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

 // Instruction-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 {

 // A fake cost for instructions that we haven't costed yet.
 const int UNKNOWN_COST = INT_MAX;

 // Enumerates the kinds of note that can be added to an instruction.
 // See the comment above insn_info for details.
 enum class insn_note_kind : uint8_t
 {
   ORDER_NODE,
   CALL_CLOBBERS
 };

 // The base class for notes that can be added to an instruction.
 // See the comment above insn_info for details.
 class insn_note
 {
   // Size: 2 LP64 words.
   friend class insn_info;
   friend class function_info;

 public:
   // Return what kind of note this is.
   insn_note_kind kind () const { return m_kind; }

   // Return the next note in the list, or null if none.
   insn_note *next_note () const { return m_next_note; }

   // Used with T = Derived *, where Derived is derived from insn_note.
   // Convert the note to Derived, asserting that it has the right kind.
   template<typename T>
   T as_a ();

   // Used with T = Derived *, where Derived is derived from insn_note.
   // If the note is a Derived note, return it in that form, otherwise
   // return null.
   template<typename T>
   T dyn_cast ();

 protected:
   // Construct a note with the given kind.
   insn_note (insn_note_kind);

 private:
   // The next note in the list, or null if none.
   insn_note *m_next_note;

   // The kind of note this is.
   insn_note_kind m_kind : 8;

 protected:
   // Fill in the remaining LP64 word with data that derived classes can use.
   unsigned int m_data8 : 8;
   unsigned int m_data16 : 16;
   unsigned int m_data32 : 32;
 };

 // Instructions have one of these notes if insn_info::has_call_clobbers ()
 // is true.  All such instructions in an EBB are first grouped together
 // by the predefined_function_abis of the functions that they call.
 // Then, for each such predefined ABI, the call_clobbers notes are put
 // into a splay tree whose nodes follow execution order.
 class insn_call_clobbers_note : public insn_note
 {
   friend class function_info;
   friend class default_splay_tree_accessors<insn_call_clobbers_note *>;

 public:
   static const insn_note_kind kind = insn_note_kind::CALL_CLOBBERS;

   // Return the identifier of the predefined_function_abi.
   unsigned int abi_id () const { return m_data32; }

   // Return the instruction to which the note is attached.
   insn_info *insn () const { return m_insn; }

 protected:
   insn_call_clobbers_note (unsigned int abi_id, insn_info *insn);

   // The splay tree pointers.
   insn_call_clobbers_note *m_children[2];

   // The value returned by insn ().
   insn_info *m_insn;
 };

 // A splay tree of insn_call_clobbers_notes.
 using insn_call_clobbers_tree = default_splay_tree<insn_call_clobbers_note *>;

 // SSA-related information about an instruction.  It also represents
 // artificial instructions that are added to make the dataflow correct;
 // these artificial instructions fall into three categories:
 //
 // - Instructions that hold the phi nodes for an extended basic block (is_phi).
 //
 // - Instructions that represent the head of a basic block and that hold
 //   all the associated artificial uses and definitions.
 //
 // - Instructions that represent the end of a basic block and that again
 //   hold all the associated artificial uses and definitions.
 //
 // Dataflow-wise, each instruction goes through three stages:
 //
 // (1) Use all the values in uses ().
 //
 // (2) If has_call_clobbers (), clobber the registers indicated by
 //     insn_callee_abi.
 //
 // (3) Define all the values in defs ().
 //
 // Having stage (2) is a trade-off: it makes processing the instructions
 // more complicated, but it saves having to allocate memory for every
 // individual call clobber.  Without it, clobbers for calls would often
 // make up a large proportion of the total definitions in a function.
 //
 // All the instructions in a function are chained together in a list
 // that follows a reverse postorder traversal of the CFG.  The list
 // contains both debug and nondebug instructions, but it is possible
 // to hop from one nondebug instruction to the next with constant complexity.
 //
 // Instructions can have supplemental information attached in the form
 // of "notes", a bit like REG_NOTES for the underlying RTL insns.
 class insn_info
 {
   // Size: 8 LP64 words.
   friend class ebb_info;
   friend class function_info;

 public:
   // Compare instructions by their positions in the function list described
   // above.  Thus for two instructions in the same basic block, I1 < I2 if
   // I1 comes before I2 in the block.
   bool operator< (const insn_info &) const;
   bool operator<= (const insn_info &) const;
   bool operator>= (const insn_info &) const;
   bool operator> (const insn_info &) const;

   // Return -1 if this instruction comes before INSN in the reverse
   // postorder, 0 if this instruction is INSN, or 1 if this instruction
   // comes after INSN in the reverse postorder.
   int compare_with (const insn_info *insn) const;

   // Return the previous and next instructions in the list described above,
   // or null if there are no such instructions.
   insn_info *prev_any_insn () const;
   insn_info *next_any_insn () const;

   // Only valid if !is_debug_insn ().  Return the previous and next
   // nondebug instructions in the list described above, skipping over
   // any intervening debug instructions.  These are constant-time operations.
   insn_info *prev_nondebug_insn () const;
   insn_info *next_nondebug_insn () const;

   // Return the underlying RTL insn.  This instruction is null if is_phi ()
   // or is_bb_end () are true.  The instruction is a basic block note if
   // is_bb_head () is true.
   rtx_insn *rtl () const { return m_rtl; }

   // Return true if the instruction is a real insn with an rtl pattern.
   // Return false if it is an artificial instruction that represents the
   // phi nodes in an extended basic block or the head or end of a basic block.
   bool is_real () const { return m_cost_or_uid >= 0; }

   // Return the opposite of is_real ().
   bool is_artificial () const { return m_cost_or_uid < 0; }

   // Return true if the instruction was a real instruction but has now
   // been deleted.  In this case the instruction is no longer part of
   // the SSA information.
   bool has_been_deleted () const { return m_rtl && !INSN_P (m_rtl); }

   // Return true if the instruction is a debug instruction (and thus
   // also a real instruction).
   bool is_debug_insn () const { return m_is_debug_insn; }

   // Return true if the instruction is something that we can optimize.
   // This implies that it is a real instruction that contains an asm
   // or that contains something that matches an .md define_insn pattern.
   bool can_be_optimized () const { return m_can_be_optimized; }

   // Return true if the instruction is a call instruction.
   //
   // ??? We could cache this information, but since most callers would
   // go on to access PATTERN (rtl ()), a cache might not be helpful and
   // could even be counterproductive.
   bool is_call () const { return CALL_P (m_rtl); }

   // Return true if the instruction is a jump instruction.
   //
   // ??? See is_call for the reason we don't cache this.
   bool is_jump () const { return JUMP_P (m_rtl); }

   // Return true if the instruction is real and contains an inline asm.
   bool is_asm () const { return m_is_asm; }

   // Return true if the instruction is real and includes an RTX_AUTOINC
   // operation.
   bool has_pre_post_modify () const { return m_has_pre_post_modify; }

   // Return true if the instruction is real and has volatile references,
   // in the sense of volatile_refs_p.  This includes volatile memory,
   // volatile asms and UNSPEC_VOLATILEs.
   bool has_volatile_refs () const { return m_has_volatile_refs; }

   // Return true if the instruction is aritificial and if its (sole)
   // purpose is to hold the phi nodes in an extended basic block.
   bool is_phi () const;

   // Return true if the instruction is artificial and if it represents
   // the head of a basic block.  If so, the instruction conceptually
   // executes before the real instructions in the block.  The uses
   // and definitions represent the df_get_artificial_uses and
   // df_get_artificial_defs entries for the head of the block.
   bool is_bb_head () const;

   // Return true if the instruction is artificial and if it represents
   // the end of a basic block.  The uses and definitions represent the
   // the df_get_artificial_uses and df_get_artificial_defs entries for
   // the end of the block.
   bool is_bb_end () const;

   // Return the basic block that the instruction is in.
   bb_info *bb () const { return m_bb; }

   // Return the extended basic block that the instruction is in;
   // see bb_info for details.
   ebb_info *ebb () const;

   // If the instruction is real, return the unique identifier of the
   // underlying RTL insn.  If the instruction is artificial, return
   // a unique negative identifier for the instructions.
   //
   // Note that the identifiers are not linear: it can be the case that
   // an instruction with a higher uid comes earlier in a block than an
   // instruction with a lower uid.  The identifiers are however persistent;
   // the identifier remains the same after the instruction has been moved
   // or changed.
   int uid () const;

   // Return the list of things that this instruction uses.  Registers
   // come first, in register number order, followed by memory.
   use_array uses () const;

   // Return true if the instruction is a call and if the clobbers
   // described by insn_callee_abi have been omitted from the list
   // of definitions.
   bool has_call_clobbers () const;

   // Return the list of things that this instruction sets or clobbers.
   // Registers come first, in register number order, followed by memory.
   //
   // If has_call_clobbers () is true, the list omits both the full and
   // partial register clobbers described by insn_callee_abi.
   def_array defs () const;

   // The number of entries in uses ().
   unsigned int num_uses () const { return m_num_uses; }

   // The number of entries in defs ().
   unsigned int num_defs () const { return m_num_defs; }

   // Return the cost of the instruction, as calculated by the target.
   // For performance reasons, the cost is evaluated lazily on first use.
   //
   // Artificial instructions have a cost of 0.
   unsigned int cost () const;

   // Return the first insn_note attached to the instruction, or null
   // if none.
   insn_note *first_note () const { return m_first_note; }

   // See if a note of type T is attached to the instruction.  Return it
   // if so, otherwise return null.
   template<typename T>
   const T *find_note () const;

   // Print "i" + uid () for real instructions and "a" + -uid () for
   // artificial instructions.
   void print_identifier (pretty_printer *) const;

   // Print a short(ish) description of where the instruction is.
   void print_location (pretty_printer *) const;

   // Combine print_identifier and print_location.
   void print_identifier_and_location (pretty_printer *) const;

   // Print a full description of the instruction.
   void print_full (pretty_printer *) const;

 private:
   // The first-order way of representing the order between instructions
   // is to assign "program points", with higher point numbers coming
   // later in the reverse postorder than lower point numbers.  However,
   // after a sequence of instruction movements, we may end up in a situation
   // that adjacent instructions have the same program point.
   //
   // When that happens, we put the instructions into a splay tree that
   // records their relative order.  Each node of the splay tree is an
   // order_node note that is attached to its respective instruction.
   // The root of the splay tree is not stored, since the only thing
   // we need the tree for is to compare two nodes.
   class order_node : public insn_note
   {
   public:
     static const insn_note_kind kind = insn_note_kind::ORDER_NODE;

     order_node (int uid);

     // Return the uid of the instruction that this node describes.
     int uid () const { return m_data32; }

     // The splay tree pointers.
     order_node *m_children[2];
     order_node *m_parent;
   };
   using order_splay_tree = default_rootless_splay_tree<order_node *>;

   // prev_insn_or_last_debug_insn represents a choice between two things:
   //
   // (1) A pointer to the previous instruction in the list that has the
   //     same is_debug_insn () value, or null if no such instruction exists.
   //
   // (2) A pointer to the end of a sublist of debug instructions.
   //
   // (2) is used if this instruction is a debug instruction and the
   // previous instruction is not.  (1) is used otherwise.
   //
   // next_nondebug_or_debug_insn points to the next instruction but also
   // records whether that next instruction is a debug instruction or a
   // nondebug instruction.
   //
   // Thus the list is chained as follows:
   //
   //         ---->        ---->     ---->     ---->     ---->
   // NONDEBUG     NONDEBUG     DEBUG     DEBUG     DEBUG     NONDEBUG ...
   //         <----    ^     +--     <----     <----  ^    +--
   //                  |     |                        |    |
   //                  |     +------------------------+    |
   //                  |                                   |
   //                  +-----------------------------------+
   using prev_insn_or_last_debug_insn = pointer_mux<insn_info>;
   using next_nondebug_or_debug_insn = pointer_mux<insn_info>;

   insn_info (bb_info *bb, rtx_insn *rtl, int cost_or_uid);

   static void print_uid (pretty_printer *, int);

   void calculate_cost () const;
   void set_properties (const rtx_properties &);
   void set_accesses (access_info **, unsigned int, unsigned int);
   void copy_accesses (access_array, access_array);
   void set_cost (unsigned int cost) { m_cost_or_uid = cost; }
   void set_bb (bb_info *bb) { m_bb = bb; }

   void add_note (insn_note *note);

   order_node *get_order_node () const;
   order_node *get_known_order_node () const;
   int slow_compare_with (const insn_info &) const;

   insn_info *last_debug_insn () const;

   unsigned int point () const { return m_point; }
   void copy_prev_from (insn_info *);
   void copy_next_from (insn_info *);
   void set_prev_sametype_insn (insn_info *);
   void set_last_debug_insn (insn_info *);
   void set_next_any_insn (insn_info *);
   void set_point (unsigned int point) { m_point = point; }
   void clear_insn_links ();
   bool has_insn_links ();

   // The values returned by the accessors above.
   prev_insn_or_last_debug_insn m_prev_insn_or_last_debug_insn;
   next_nondebug_or_debug_insn m_next_nondebug_or_debug_insn;
   bb_info *m_bb;
   rtx_insn *m_rtl;

   // The list of definitions followed by the list of uses.
   access_info **m_accesses;

   // The number of definitions and the number uses.  FIRST_PSEUDO_REGISTER + 1
   // is the maximum number of accesses to hard registers and memory, and
   // MAX_RECOG_OPERANDS is the maximum number of pseudos that can be
   // defined by an instruction, so the number of definitions should fit
   // easily in 16 bits.
   unsigned int m_num_uses;
   unsigned int m_num_defs : 16;

   // Flags returned by the accessors above.
   unsigned int m_is_debug_insn : 1;
   unsigned int m_can_be_optimized : 1;
   unsigned int m_is_asm : 1;
   unsigned int m_has_pre_post_modify : 1;
   unsigned int m_has_volatile_refs : 1;

   // For future expansion.
   unsigned int m_spare : 11;

   // The program point at which the instruction occurs.
   //
   // Note that the values of the program points are influenced by -g
   // and so should not used to make codegen decisions.
   unsigned int m_point;

   // Negative if the instruction is artificial, nonnegative if it is real.
   //
   // For real instructions: the cost of the instruction, or UNKNOWN_COST
   // if we haven't measured it yet.
   //
   // For artificial instructions: the (negative) unique identifier of the
   // instruction.
   mutable int m_cost_or_uid;

   // The list of notes that have been attached to the instruction.
   insn_note *m_first_note;
 };

 // Iterators for unfiltered lists of instructions.
 using any_insn_iterator = list_iterator<insn_info, &insn_info::next_any_insn>;
 using reverse_any_insn_iterator
   = list_iterator<insn_info, &insn_info::prev_any_insn>;

 // Iterators for nondebug instructions only.
 using nondebug_insn_iterator
   = list_iterator<insn_info, &insn_info::next_nondebug_insn>;
 using reverse_nondebug_insn_iterator
   = list_iterator<insn_info, &insn_info::prev_nondebug_insn>;

 // A class that describes an inclusive range of instructions.
 class insn_range_info
 {
 public:
   insn_range_info () = default;

   // Create a range that contains a singleton instruction.
   insn_range_info (insn_info *insn) : first (insn), last (insn) {}

   // Create a range [FIRST, LAST], given that *FIRST <= *LAST.
   insn_range_info (insn_info *first, insn_info *last);

   // Return true if the range contains at least one instruction.
   explicit operator bool () const { return *first <= *last; }

   bool operator== (const insn_range_info &) const;
   bool operator!= (const insn_range_info &) const;

   // If the range contains a single instruction, return that instruction,
   // otherwise return null.
   insn_info *singleton () const;

   // Return true if the range includes INSN.
   bool includes (insn_info *insn) const;

   // If INSN is inside the range, return INSN, otherwise return the
   // nearest in-range instruction.
   insn_info *clamp_insn_to_range (insn_info *insn) const;

   // Return true if this range is a subrange of OTHER, i.e. if OTHER
   // includes every instruction that this range does.
   bool is_subrange_of (const insn_range_info &other) const;

   // The lower and upper bounds of the range.
   insn_info *first;
   insn_info *last;
 };

 // A class that represents a closure of operator== for instructions.
 // This is used by insn_is; see there for details.
 class insn_is_closure
 {
 public:
   insn_is_closure (const insn_info *insn) : m_insn (insn) {}
   bool operator() (const insn_info *other) const { return m_insn == other; }

 private:
   const insn_info *m_insn;
 };

 void pp_insn (pretty_printer *, const insn_info *);

 }

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

 void DEBUG_FUNCTION debug (const rtl_ssa::insn_info *);
	// Instruction-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 {

	// A fake cost for instructions that we haven't costed yet.
	const int UNKNOWN_COST = INT_MAX;

	// Enumerates the kinds of note that can be added to an instruction.
	// See the comment above insn_info for details.
	enum class insn_note_kind : uint8_t
	{
	ORDER_NODE,
	CALL_CLOBBERS
	};

	// The base class for notes that can be added to an instruction.
	// See the comment above insn_info for details.
	class insn_note
	{
	// Size: 2 LP64 words.
	friend class insn_info;
	friend class function_info;

	public:
	// Return what kind of note this is.
	insn_note_kind kind () const { return m_kind; }

	// Return the next note in the list, or null if none.
	insn_note *next_note () const { return m_next_note; }

	// Used with T = Derived *, where Derived is derived from insn_note.
	// Convert the note to Derived, asserting that it has the right kind.
	template<typename T>
	T as_a ();

	// Used with T = Derived *, where Derived is derived from insn_note.
	// If the note is a Derived note, return it in that form, otherwise
	// return null.
	template<typename T>
	T dyn_cast ();

	protected:
	// Construct a note with the given kind.
	insn_note (insn_note_kind);

	private:
	// The next note in the list, or null if none.
	insn_note *m_next_note;

	// The kind of note this is.
	insn_note_kind m_kind : 8;

	protected:
	// Fill in the remaining LP64 word with data that derived classes can use.
	unsigned int m_data8 : 8;
	unsigned int m_data16 : 16;
	unsigned int m_data32 : 32;
	};

	// Instructions have one of these notes if insn_info::has_call_clobbers ()
	// is true. All such instructions in an EBB are first grouped together
	// by the predefined_function_abis of the functions that they call.
	// Then, for each such predefined ABI, the call_clobbers notes are put
	// into a splay tree whose nodes follow execution order.
	class insn_call_clobbers_note : public insn_note
	{
	friend class function_info;
	friend class default_splay_tree_accessors<insn_call_clobbers_note *>;

	public:
	static const insn_note_kind kind = insn_note_kind::CALL_CLOBBERS;

	// Return the identifier of the predefined_function_abi.
	unsigned int abi_id () const { return m_data32; }

	// Return the instruction to which the note is attached.
	insn_info *insn () const { return m_insn; }

	protected:
	insn_call_clobbers_note (unsigned int abi_id, insn_info *insn);

	// The splay tree pointers.
	insn_call_clobbers_note *m_children[2];

	// The value returned by insn ().
	insn_info *m_insn;
	};

	// A splay tree of insn_call_clobbers_notes.
	using insn_call_clobbers_tree = default_splay_tree<insn_call_clobbers_note *>;

	// SSA-related information about an instruction. It also represents
	// artificial instructions that are added to make the dataflow correct;
	// these artificial instructions fall into three categories:
	//
	// - Instructions that hold the phi nodes for an extended basic block (is_phi).
	//
	// - Instructions that represent the head of a basic block and that hold
	// all the associated artificial uses and definitions.
	//
	// - Instructions that represent the end of a basic block and that again
	// hold all the associated artificial uses and definitions.
	//
	// Dataflow-wise, each instruction goes through three stages:
	//
	// (1) Use all the values in uses ().
	//
	// (2) If has_call_clobbers (), clobber the registers indicated by
	// insn_callee_abi.
	//
	// (3) Define all the values in defs ().
	//
	// Having stage (2) is a trade-off: it makes processing the instructions
	// more complicated, but it saves having to allocate memory for every
	// individual call clobber. Without it, clobbers for calls would often
	// make up a large proportion of the total definitions in a function.
	//
	// All the instructions in a function are chained together in a list
	// that follows a reverse postorder traversal of the CFG. The list
	// contains both debug and nondebug instructions, but it is possible
	// to hop from one nondebug instruction to the next with constant complexity.
	//
	// Instructions can have supplemental information attached in the form
	// of "notes", a bit like REG_NOTES for the underlying RTL insns.
	class insn_info
	{
	// Size: 8 LP64 words.
	friend class ebb_info;
	friend class function_info;

	public:
	// Compare instructions by their positions in the function list described
	// above. Thus for two instructions in the same basic block, I1 < I2 if
	// I1 comes before I2 in the block.
	bool operator< (const insn_info &) const;
	bool operator<= (const insn_info &) const;
	bool operator>= (const insn_info &) const;
	bool operator> (const insn_info &) const;

	// Return -1 if this instruction comes before INSN in the reverse
	// postorder, 0 if this instruction is INSN, or 1 if this instruction
	// comes after INSN in the reverse postorder.
	int compare_with (const insn_info *insn) const;

	// Return the previous and next instructions in the list described above,
	// or null if there are no such instructions.
	insn_info *prev_any_insn () const;
	insn_info *next_any_insn () const;

	// Only valid if !is_debug_insn (). Return the previous and next
	// nondebug instructions in the list described above, skipping over
	// any intervening debug instructions. These are constant-time operations.
	insn_info *prev_nondebug_insn () const;
	insn_info *next_nondebug_insn () const;

	// Return the underlying RTL insn. This instruction is null if is_phi ()
	// or is_bb_end () are true. The instruction is a basic block note if
	// is_bb_head () is true.
	rtx_insn *rtl () const { return m_rtl; }

	// Return true if the instruction is a real insn with an rtl pattern.
	// Return false if it is an artificial instruction that represents the
	// phi nodes in an extended basic block or the head or end of a basic block.
	bool is_real () const { return m_cost_or_uid >= 0; }

	// Return the opposite of is_real ().
	bool is_artificial () const { return m_cost_or_uid < 0; }

	// Return true if the instruction was a real instruction but has now
	// been deleted. In this case the instruction is no longer part of
	// the SSA information.
	bool has_been_deleted () const { return m_rtl && !INSN_P (m_rtl); }

	// Return true if the instruction is a debug instruction (and thus
	// also a real instruction).
	bool is_debug_insn () const { return m_is_debug_insn; }

	// Return true if the instruction is something that we can optimize.
	// This implies that it is a real instruction that contains an asm
	// or that contains something that matches an .md define_insn pattern.
	bool can_be_optimized () const { return m_can_be_optimized; }

	// Return true if the instruction is a call instruction.
	//
	// ??? We could cache this information, but since most callers would
	// go on to access PATTERN (rtl ()), a cache might not be helpful and
	// could even be counterproductive.
	bool is_call () const { return CALL_P (m_rtl); }

	// Return true if the instruction is a jump instruction.
	//
	// ??? See is_call for the reason we don't cache this.
	bool is_jump () const { return JUMP_P (m_rtl); }

	// Return true if the instruction is real and contains an inline asm.
	bool is_asm () const { return m_is_asm; }

	// Return true if the instruction is real and includes an RTX_AUTOINC
	// operation.
	bool has_pre_post_modify () const { return m_has_pre_post_modify; }

	// Return true if the instruction is real and has volatile references,
	// in the sense of volatile_refs_p. This includes volatile memory,
	// volatile asms and UNSPEC_VOLATILEs.
	bool has_volatile_refs () const { return m_has_volatile_refs; }

	// Return true if the instruction is aritificial and if its (sole)
	// purpose is to hold the phi nodes in an extended basic block.
	bool is_phi () const;

	// Return true if the instruction is artificial and if it represents
	// the head of a basic block. If so, the instruction conceptually
	// executes before the real instructions in the block. The uses
	// and definitions represent the df_get_artificial_uses and
	// df_get_artificial_defs entries for the head of the block.
	bool is_bb_head () const;

	// Return true if the instruction is artificial and if it represents
	// the end of a basic block. The uses and definitions represent the
	// the df_get_artificial_uses and df_get_artificial_defs entries for
	// the end of the block.
	bool is_bb_end () const;

	// Return the basic block that the instruction is in.
	bb_info *bb () const { return m_bb; }

	// Return the extended basic block that the instruction is in;
	// see bb_info for details.
	ebb_info *ebb () const;

	// If the instruction is real, return the unique identifier of the
	// underlying RTL insn. If the instruction is artificial, return
	// a unique negative identifier for the instructions.
	//
	// Note that the identifiers are not linear: it can be the case that
	// an instruction with a higher uid comes earlier in a block than an
	// instruction with a lower uid. The identifiers are however persistent;
	// the identifier remains the same after the instruction has been moved
	// or changed.
	int uid () const;

	// Return the list of things that this instruction uses. Registers
	// come first, in register number order, followed by memory.
	use_array uses () const;

	// Return true if the instruction is a call and if the clobbers
	// described by insn_callee_abi have been omitted from the list
	// of definitions.
	bool has_call_clobbers () const;

	// Return the list of things that this instruction sets or clobbers.
	// Registers come first, in register number order, followed by memory.
	//
	// If has_call_clobbers () is true, the list omits both the full and
	// partial register clobbers described by insn_callee_abi.
	def_array defs () const;

	// The number of entries in uses ().
	unsigned int num_uses () const { return m_num_uses; }

	// The number of entries in defs ().
	unsigned int num_defs () const { return m_num_defs; }

	// Return the cost of the instruction, as calculated by the target.
	// For performance reasons, the cost is evaluated lazily on first use.
	//
	// Artificial instructions have a cost of 0.
	unsigned int cost () const;

	// Return the first insn_note attached to the instruction, or null
	// if none.
	insn_note *first_note () const { return m_first_note; }

	// See if a note of type T is attached to the instruction. Return it
	// if so, otherwise return null.
	template<typename T>
	const T *find_note () const;

	// Print "i" + uid () for real instructions and "a" + -uid () for
	// artificial instructions.
	void print_identifier (pretty_printer *) const;

	// Print a short(ish) description of where the instruction is.
	void print_location (pretty_printer *) const;

	// Combine print_identifier and print_location.
	void print_identifier_and_location (pretty_printer *) const;

	// Print a full description of the instruction.
	void print_full (pretty_printer *) const;

	private:
	// The first-order way of representing the order between instructions
	// is to assign "program points", with higher point numbers coming
	// later in the reverse postorder than lower point numbers. However,
	// after a sequence of instruction movements, we may end up in a situation
	// that adjacent instructions have the same program point.
	//
	// When that happens, we put the instructions into a splay tree that
	// records their relative order. Each node of the splay tree is an
	// order_node note that is attached to its respective instruction.
	// The root of the splay tree is not stored, since the only thing
	// we need the tree for is to compare two nodes.
	class order_node : public insn_note
	{
	public:
	static const insn_note_kind kind = insn_note_kind::ORDER_NODE;

	order_node (int uid);

	// Return the uid of the instruction that this node describes.
	int uid () const { return m_data32; }

	// The splay tree pointers.
	order_node *m_children[2];
	order_node *m_parent;
	};
	using order_splay_tree = default_rootless_splay_tree<order_node *>;

	// prev_insn_or_last_debug_insn represents a choice between two things:
	//
	// (1) A pointer to the previous instruction in the list that has the
	// same is_debug_insn () value, or null if no such instruction exists.
	//
	// (2) A pointer to the end of a sublist of debug instructions.
	//
	// (2) is used if this instruction is a debug instruction and the
	// previous instruction is not. (1) is used otherwise.
	//
	// next_nondebug_or_debug_insn points to the next instruction but also
	// records whether that next instruction is a debug instruction or a
	// nondebug instruction.
	//
	// Thus the list is chained as follows:
	//
	// ----> ----> ----> ----> ---->
	// NONDEBUG NONDEBUG DEBUG DEBUG DEBUG NONDEBUG ...
	// <---- ^ +-- <---- <---- ^ +--
	// \| \| \| \|
	// \| +------------------------+ \|
	// \| \|
	// +-----------------------------------+
	using prev_insn_or_last_debug_insn = pointer_mux<insn_info>;
	using next_nondebug_or_debug_insn = pointer_mux<insn_info>;

	insn_info (bb_info bb, rtx_insn rtl, int cost_or_uid);

	static void print_uid (pretty_printer *, int);

	void calculate_cost () const;
	void set_properties (const rtx_properties &);
	void set_accesses (access_info **, unsigned int, unsigned int);
	void copy_accesses (access_array, access_array);
	void set_cost (unsigned int cost) { m_cost_or_uid = cost; }
	void set_bb (bb_info *bb) { m_bb = bb; }

	void add_note (insn_note *note);

	order_node *get_order_node () const;
	order_node *get_known_order_node () const;
	int slow_compare_with (const insn_info &) const;

	insn_info *last_debug_insn () const;

	unsigned int point () const { return m_point; }
	void copy_prev_from (insn_info *);
	void copy_next_from (insn_info *);
	void set_prev_sametype_insn (insn_info *);
	void set_last_debug_insn (insn_info *);
	void set_next_any_insn (insn_info *);
	void set_point (unsigned int point) { m_point = point; }
	void clear_insn_links ();
	bool has_insn_links ();

	// The values returned by the accessors above.
	prev_insn_or_last_debug_insn m_prev_insn_or_last_debug_insn;
	next_nondebug_or_debug_insn m_next_nondebug_or_debug_insn;
	bb_info *m_bb;
	rtx_insn *m_rtl;

	// The list of definitions followed by the list of uses.
	access_info **m_accesses;

	// The number of definitions and the number uses. FIRST_PSEUDO_REGISTER + 1
	// is the maximum number of accesses to hard registers and memory, and
	// MAX_RECOG_OPERANDS is the maximum number of pseudos that can be
	// defined by an instruction, so the number of definitions should fit
	// easily in 16 bits.
	unsigned int m_num_uses;
	unsigned int m_num_defs : 16;

	// Flags returned by the accessors above.
	unsigned int m_is_debug_insn : 1;
	unsigned int m_can_be_optimized : 1;
	unsigned int m_is_asm : 1;
	unsigned int m_has_pre_post_modify : 1;
	unsigned int m_has_volatile_refs : 1;

	// For future expansion.
	unsigned int m_spare : 11;

	// The program point at which the instruction occurs.
	//
	// Note that the values of the program points are influenced by -g
	// and so should not used to make codegen decisions.
	unsigned int m_point;

	// Negative if the instruction is artificial, nonnegative if it is real.
	//
	// For real instructions: the cost of the instruction, or UNKNOWN_COST
	// if we haven't measured it yet.
	//
	// For artificial instructions: the (negative) unique identifier of the
	// instruction.
	mutable int m_cost_or_uid;

	// The list of notes that have been attached to the instruction.
	insn_note *m_first_note;
	};

	// Iterators for unfiltered lists of instructions.
	using any_insn_iterator = list_iterator<insn_info, &insn_info::next_any_insn>;
	using reverse_any_insn_iterator
	= list_iterator<insn_info, &insn_info::prev_any_insn>;

	// Iterators for nondebug instructions only.
	using nondebug_insn_iterator
	= list_iterator<insn_info, &insn_info::next_nondebug_insn>;
	using reverse_nondebug_insn_iterator
	= list_iterator<insn_info, &insn_info::prev_nondebug_insn>;

	// A class that describes an inclusive range of instructions.
	class insn_range_info
	{
	public:
	insn_range_info () = default;

	// Create a range that contains a singleton instruction.
	insn_range_info (insn_info *insn) : first (insn), last (insn) {}

	// Create a range [FIRST, LAST], given that FIRST <= LAST.
	insn_range_info (insn_info first, insn_info last);

	// Return true if the range contains at least one instruction.
	explicit operator bool () const { return first <= last; }

	bool operator== (const insn_range_info &) const;
	bool operator!= (const insn_range_info &) const;

	// If the range contains a single instruction, return that instruction,
	// otherwise return null.
	insn_info *singleton () const;

	// Return true if the range includes INSN.
	bool includes (insn_info *insn) const;

	// If INSN is inside the range, return INSN, otherwise return the
	// nearest in-range instruction.
	insn_info clamp_insn_to_range (insn_info insn) const;

	// Return true if this range is a subrange of OTHER, i.e. if OTHER
	// includes every instruction that this range does.
	bool is_subrange_of (const insn_range_info &other) const;

	// The lower and upper bounds of the range.
	insn_info *first;
	insn_info *last;
	};

	// A class that represents a closure of operator== for instructions.
	// This is used by insn_is; see there for details.
	class insn_is_closure
	{
	public:
	insn_is_closure (const insn_info *insn) : m_insn (insn) {}
	bool operator() (const insn_info *other) const { return m_insn == other; }

	private:
	const insn_info *m_insn;
	};

	void pp_insn (pretty_printer , const insn_info );

	}

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

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