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

 // RTL SSA utilities relating to instruction movement               -*- 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 {

 // Restrict movement range RANGE so that the instruction is placed later
 // than INSN.  (The movement range is the range of instructions after which
 // an instruction can be placed.)
 inline insn_range_info
 move_later_than (insn_range_info range, insn_info *insn)
 {
   return { later_insn (range.first, insn), range.last };
 }

 // Restrict movement range RANGE so that the instruction is placed no earlier
 // than INSN.  (The movement range is the range of instructions after which
 // an instruction can be placed.)
 inline insn_range_info
 move_no_earlier_than (insn_range_info range, insn_info *insn)
 {
   insn_info *first = later_insn (range.first, insn->prev_nondebug_insn ());
   return { first, range.last };
 }

 // Restrict movement range RANGE so that the instruction is placed no later
 // than INSN.  (The movement range is the range of instructions after which
 // an instruction can be placed.)
 inline insn_range_info
 move_no_later_than (insn_range_info range, insn_info *insn)
 {
   return { range.first, earlier_insn (range.last, insn) };
 }

 // Restrict movement range RANGE so that the instruction is placed earlier
 // than INSN.  (The movement range is the range of instructions after which
 // an instruction can be placed.)
 inline insn_range_info
 move_earlier_than (insn_range_info range, insn_info *insn)
 {
   insn_info *last = earlier_insn (range.last, insn->prev_nondebug_insn ());
   return { range.first, last };
 }

 // Return true if it is possible to insert a new instruction after INSN.
 inline bool
 can_insert_after (insn_info *insn)
 {
   return insn->is_bb_head () || (insn->is_real () && !insn->is_jump ());
 }

 // Try to restrict move range MOVE_RANGE so that it is possible to
 // insert INSN after both of the end points.  Return true on success,
 // otherwise leave MOVE_RANGE in an invalid state.
 inline bool
 canonicalize_move_range (insn_range_info &move_range, insn_info *insn)
 {
   while (move_range.first != insn && !can_insert_after (move_range.first))
     move_range.first = move_range.first->next_nondebug_insn ();
   while (move_range.last != insn && !can_insert_after (move_range.last))
     move_range.last = move_range.last->prev_nondebug_insn ();
   return bool (move_range);
 }

 // Try to restrict movement range MOVE_RANGE of INSN so that it can set
 // or clobber REGNO.  Assume that if:
 //
 // - an instruction I2 contains another access A to REGNO; and
 // - IGNORE (I2) is true
 //
 // then either:
 //
 // - A will be removed; or
 // - something will ensure that the new definition of REGNO does not
 //   interfere with A, without this having to be enforced by I1's move range.
 //
 // Return true on success, otherwise leave MOVE_RANGE in an invalid state.
 //
 // This function only works correctly for instructions that remain within
 // the same extended basic block.
 template<typename IgnorePredicate>
 bool
 restrict_movement_for_dead_range (insn_range_info &move_range,
 				  unsigned int regno, insn_info *insn,
 				  IgnorePredicate ignore)
 {
   // Find a definition at or neighboring INSN.
   resource_info resource = full_register (regno);
   def_lookup dl = crtl->ssa->find_def (resource, insn);

   def_info *prev = dl.prev_def ();
   ebb_info *ebb = insn->ebb ();
   if (!prev || prev->ebb () != ebb)
     {
       // REGNO is not defined or used in EBB before INSN, but it
       // might be live on entry.  To keep complexity under control,
       // handle only these cases:
       //
       // - If the register is not live on entry to EBB, the register is
       //   free from the start of EBB to the first definition in EBB.
       //
       // - Otherwise, if the register is live on entry to BB, refuse
       //   to allocate the register.  We could in principle try to move
       //   the instruction to later blocks in the EBB, but it's rarely
       //   worth the effort, and could lead to linear complexity.
       //
       // - Otherwise, don't allow INSN to move earlier than its current
       //   block.  Again, we could in principle look backwards to find where
       //   REGNO dies, but it's rarely worth the effort.
       bb_info *bb = insn->bb ();
       insn_info *limit;
       if (!bitmap_bit_p (DF_LR_IN (ebb->first_bb ()->cfg_bb ()), regno))
 	limit = ebb->phi_insn ();
       else if (bitmap_bit_p (DF_LR_IN (bb->cfg_bb ()), regno))
 	return false;
       else
 	limit = bb->head_insn ();
       move_range = move_later_than (move_range, limit);
     }
   else
     {
       // Stop the instruction moving beyond the previous relevant access
       // to REGNO.
       access_info *prev_access
 	= last_access_ignoring (prev, ignore_clobbers::YES, ignore);
       if (prev_access)
 	move_range = move_later_than (move_range, access_insn (prev_access));
     }

   // Stop the instruction moving beyond the next relevant definition of REGNO.
   def_info *next = first_def_ignoring (dl.matching_or_next_def (),
 				       ignore_clobbers::YES, ignore);
   if (next)
     move_range = move_earlier_than (move_range, next->insn ());

   return canonicalize_move_range (move_range, insn);
 }

 // Try to restrict movement range MOVE_RANGE so that it is possible for the
 // instruction being moved ("instruction I1") to perform all the definitions
 // in DEFS while still preserving dependencies between those definitions
 // and surrounding instructions.  Assume that if:
 //
 // - DEFS contains a definition D of resource R;
 // - an instruction I2 contains another access A to R; and
 // - IGNORE (I2) is true
 //
 // then either:
 //
 // - A will be removed; or
 // - something will ensure that D and A maintain their current order,
 //   without this having to be enforced by I1's move range.
 //
 // Return true on success, otherwise leave MOVE_RANGE in an invalid state.
 //
 // This function only works correctly for instructions that remain within
 // the same extended basic block.
 template<typename IgnorePredicate>
 bool
 restrict_movement_for_defs_ignoring (insn_range_info &move_range,
 				     def_array defs, IgnorePredicate ignore)
 {
   for (def_info *def : defs)
     {
       // If the definition is a clobber, we can move it with respect
       // to other clobbers.
       //
       // ??? We could also do this if a definition and all its uses
       // are being moved at once.
       bool is_clobber = is_a<clobber_info *> (def);

       // Search back for the first unfiltered use or definition of the
       // same resource.
       access_info *access;
       access = prev_access_ignoring (def, ignore_clobbers (is_clobber),
 				     ignore);
       if (access)
 	move_range = move_later_than (move_range, access_insn (access));

       // Search forward for the first unfiltered use of DEF,
       // or the first unfiltered definition that follows DEF.
       //
       // We don't need to consider uses of following definitions, since
       // if IGNORE (D->insn ()) is true for some definition D, the caller
       // is guarantees that either
       //
       // - D will be removed, and thus its uses will be removed; or
       // - D will occur after DEF, and thus D's uses will also occur
       //   after DEF.
       //
       // This is purely a simplification: we could also process D's uses,
       // but we don't need to.
       access = next_access_ignoring (def, ignore_clobbers (is_clobber),
 				     ignore);
       if (access)
 	move_range = move_earlier_than (move_range, access_insn (access));

       // If DEF sets a hard register, take any call clobbers
       // into account.
       unsigned int regno = def->regno ();
       if (!HARD_REGISTER_NUM_P (regno) || is_clobber)
 	continue;

       ebb_info *ebb = def->ebb ();
       for (ebb_call_clobbers_info *call_group : ebb->call_clobbers ())
 	{
 	  if (!call_group->clobbers (def->resource ()))
 	    continue;

 	  // Exit now if we've already failed, and if the splay accesses
 	  // below would be wasted work.
 	  if (!move_range)
 	    return false;

 	  insn_info *insn;
 	  insn = prev_call_clobbers_ignoring (*call_group, def->insn (),
 					      ignore);
 	  if (insn)
 	    move_range = move_later_than (move_range, insn);

 	  insn = next_call_clobbers_ignoring (*call_group, def->insn (),
 					      ignore);
 	  if (insn)
 	    move_range = move_earlier_than (move_range, insn);
 	}
     }

   // Make sure that we don't move stores between basic blocks, since we
   // don't have enough information to tell whether it's safe.
   if (def_info *def = memory_access (defs))
     {
       move_range = move_later_than (move_range, def->bb ()->head_insn ());
       move_range = move_earlier_than (move_range, def->bb ()->end_insn ());
     }

   return bool (move_range);
 }

 // Like restrict_movement_for_defs_ignoring, but for the uses in USES.
 template<typename IgnorePredicate>
 bool
 restrict_movement_for_uses_ignoring (insn_range_info &move_range,
 				     use_array uses, IgnorePredicate ignore)
 {
   for (const use_info *use : uses)
     {
       // Ignore uses of undefined values.
       set_info *set = use->def ();
       if (!set)
 	continue;

       // Ignore uses by debug instructions.  Debug instructions are
       // never supposed to move, and uses by debug instructions are
       // never supposed to be transferred elsewhere, so we know that
       // the caller must be changing the uses on the debug instruction
       // and checking whether all new uses are available at the debug
       // instruction's original location.
       if (use->is_in_debug_insn ())
 	continue;

       // If the used value is defined by an instruction I2 for which
       // IGNORE (I2) is true, the caller guarantees that I2 will occur
       // before change.insn ().  Otherwise, make sure that the use occurs
       // after the definition.
       insn_info *insn = set->insn ();
       if (!ignore (insn))
 	move_range = move_later_than (move_range, insn);

       // Search forward for the first unfiltered definition that follows SET.
       //
       // We don't need to consider the uses of these definitions, since
       // if IGNORE (D->insn ()) is true for some definition D, the caller
       // is guarantees that either
       //
       // - D will be removed, and thus its uses will be removed; or
       // - D will occur after USE, and thus D's uses will also occur
       //   after USE.
       //
       // This is purely a simplification: we could also process D's uses,
       // but we don't need to.
       def_info *def;
       def = first_def_ignoring (set->next_def (), ignore_clobbers::NO,
 				ignore);
       if (def)
 	move_range = move_earlier_than (move_range, def->insn ());

       // If USE uses a hard register, take any call clobbers into account too.
       // SET will necessarily occur after any previous call clobber, so we
       // only need to check for later clobbers.
       unsigned int regno = use->regno ();
       if (!HARD_REGISTER_NUM_P (regno))
 	continue;

       ebb_info *ebb = use->ebb ();
       for (ebb_call_clobbers_info *call_group : ebb->call_clobbers ())
 	{
 	  if (!call_group->clobbers (use->resource ()))
 	    continue;

 	  if (!move_range)
 	    return false;

 	  insn_info *insn = next_call_clobbers_ignoring (*call_group,
 							 use->insn (), ignore);
 	  if (insn)
 	    move_range = move_earlier_than (move_range, insn);
 	}
     }

   // Make sure that we don't move loads into an earlier basic block.
   //
   // ??? It would be good to relax this for loads that can be safely
   // speculated.
   if (use_info *use = memory_access (uses))
     move_range = move_later_than (move_range, use->bb ()->head_insn ());

   return bool (move_range);
 }

 }
	// RTL SSA utilities relating to instruction movement -- 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 {

	// Restrict movement range RANGE so that the instruction is placed later
	// than INSN. (The movement range is the range of instructions after which
	// an instruction can be placed.)
	inline insn_range_info
	move_later_than (insn_range_info range, insn_info *insn)
	{
	return { later_insn (range.first, insn), range.last };
	}

	// Restrict movement range RANGE so that the instruction is placed no earlier
	// than INSN. (The movement range is the range of instructions after which
	// an instruction can be placed.)
	inline insn_range_info
	move_no_earlier_than (insn_range_info range, insn_info *insn)
	{
	insn_info *first = later_insn (range.first, insn->prev_nondebug_insn ());
	return { first, range.last };
	}

	// Restrict movement range RANGE so that the instruction is placed no later
	// than INSN. (The movement range is the range of instructions after which
	// an instruction can be placed.)
	inline insn_range_info
	move_no_later_than (insn_range_info range, insn_info *insn)
	{
	return { range.first, earlier_insn (range.last, insn) };
	}

	// Restrict movement range RANGE so that the instruction is placed earlier
	// than INSN. (The movement range is the range of instructions after which
	// an instruction can be placed.)
	inline insn_range_info
	move_earlier_than (insn_range_info range, insn_info *insn)
	{
	insn_info *last = earlier_insn (range.last, insn->prev_nondebug_insn ());
	return { range.first, last };
	}

	// Return true if it is possible to insert a new instruction after INSN.
	inline bool
	can_insert_after (insn_info *insn)
	{
	return insn->is_bb_head () \|\| (insn->is_real () && !insn->is_jump ());
	}

	// Try to restrict move range MOVE_RANGE so that it is possible to
	// insert INSN after both of the end points. Return true on success,
	// otherwise leave MOVE_RANGE in an invalid state.
	inline bool
	canonicalize_move_range (insn_range_info &move_range, insn_info *insn)
	{
	while (move_range.first != insn && !can_insert_after (move_range.first))
	move_range.first = move_range.first->next_nondebug_insn ();
	while (move_range.last != insn && !can_insert_after (move_range.last))
	move_range.last = move_range.last->prev_nondebug_insn ();
	return bool (move_range);
	}

	// Try to restrict movement range MOVE_RANGE of INSN so that it can set
	// or clobber REGNO. Assume that if:
	//
	// - an instruction I2 contains another access A to REGNO; and
	// - IGNORE (I2) is true
	//
	// then either:
	//
	// - A will be removed; or
	// - something will ensure that the new definition of REGNO does not
	// interfere with A, without this having to be enforced by I1's move range.
	//
	// Return true on success, otherwise leave MOVE_RANGE in an invalid state.
	//
	// This function only works correctly for instructions that remain within
	// the same extended basic block.
	template<typename IgnorePredicate>
	bool
	restrict_movement_for_dead_range (insn_range_info &move_range,
	unsigned int regno, insn_info *insn,
	IgnorePredicate ignore)
	{
	// Find a definition at or neighboring INSN.
	resource_info resource = full_register (regno);
	def_lookup dl = crtl->ssa->find_def (resource, insn);

	def_info *prev = dl.prev_def ();
	ebb_info *ebb = insn->ebb ();
	if (!prev \|\| prev->ebb () != ebb)
	{
	// REGNO is not defined or used in EBB before INSN, but it
	// might be live on entry. To keep complexity under control,
	// handle only these cases:
	//
	// - If the register is not live on entry to EBB, the register is
	// free from the start of EBB to the first definition in EBB.
	//
	// - Otherwise, if the register is live on entry to BB, refuse
	// to allocate the register. We could in principle try to move
	// the instruction to later blocks in the EBB, but it's rarely
	// worth the effort, and could lead to linear complexity.
	//
	// - Otherwise, don't allow INSN to move earlier than its current
	// block. Again, we could in principle look backwards to find where
	// REGNO dies, but it's rarely worth the effort.
	bb_info *bb = insn->bb ();
	insn_info *limit;
	if (!bitmap_bit_p (DF_LR_IN (ebb->first_bb ()->cfg_bb ()), regno))
	limit = ebb->phi_insn ();
	else if (bitmap_bit_p (DF_LR_IN (bb->cfg_bb ()), regno))
	return false;
	else
	limit = bb->head_insn ();
	move_range = move_later_than (move_range, limit);
	}
	else
	{
	// Stop the instruction moving beyond the previous relevant access
	// to REGNO.
	access_info *prev_access
	= last_access_ignoring (prev, ignore_clobbers::YES, ignore);
	if (prev_access)
	move_range = move_later_than (move_range, access_insn (prev_access));
	}

	// Stop the instruction moving beyond the next relevant definition of REGNO.
	def_info *next = first_def_ignoring (dl.matching_or_next_def (),
	ignore_clobbers::YES, ignore);
	if (next)
	move_range = move_earlier_than (move_range, next->insn ());

	return canonicalize_move_range (move_range, insn);
	}

	// Try to restrict movement range MOVE_RANGE so that it is possible for the
	// instruction being moved ("instruction I1") to perform all the definitions
	// in DEFS while still preserving dependencies between those definitions
	// and surrounding instructions. Assume that if:
	//
	// - DEFS contains a definition D of resource R;
	// - an instruction I2 contains another access A to R; and
	// - IGNORE (I2) is true
	//
	// then either:
	//
	// - A will be removed; or
	// - something will ensure that D and A maintain their current order,
	// without this having to be enforced by I1's move range.
	//
	// Return true on success, otherwise leave MOVE_RANGE in an invalid state.
	//
	// This function only works correctly for instructions that remain within
	// the same extended basic block.
	template<typename IgnorePredicate>
	bool
	restrict_movement_for_defs_ignoring (insn_range_info &move_range,
	def_array defs, IgnorePredicate ignore)
	{
	for (def_info *def : defs)
	{
	// If the definition is a clobber, we can move it with respect
	// to other clobbers.
	//
	// ??? We could also do this if a definition and all its uses
	// are being moved at once.
	bool is_clobber = is_a<clobber_info *> (def);

	// Search back for the first unfiltered use or definition of the
	// same resource.
	access_info *access;
	access = prev_access_ignoring (def, ignore_clobbers (is_clobber),
	ignore);
	if (access)
	move_range = move_later_than (move_range, access_insn (access));

	// Search forward for the first unfiltered use of DEF,
	// or the first unfiltered definition that follows DEF.
	//
	// We don't need to consider uses of following definitions, since
	// if IGNORE (D->insn ()) is true for some definition D, the caller
	// is guarantees that either
	//
	// - D will be removed, and thus its uses will be removed; or
	// - D will occur after DEF, and thus D's uses will also occur
	// after DEF.
	//
	// This is purely a simplification: we could also process D's uses,
	// but we don't need to.
	access = next_access_ignoring (def, ignore_clobbers (is_clobber),
	ignore);
	if (access)
	move_range = move_earlier_than (move_range, access_insn (access));

	// If DEF sets a hard register, take any call clobbers
	// into account.
	unsigned int regno = def->regno ();
	if (!HARD_REGISTER_NUM_P (regno) \|\| is_clobber)
	continue;

	ebb_info *ebb = def->ebb ();
	for (ebb_call_clobbers_info *call_group : ebb->call_clobbers ())
	{
	if (!call_group->clobbers (def->resource ()))
	continue;

	// Exit now if we've already failed, and if the splay accesses
	// below would be wasted work.
	if (!move_range)
	return false;

	insn_info *insn;
	insn = prev_call_clobbers_ignoring (*call_group, def->insn (),
	ignore);
	if (insn)
	move_range = move_later_than (move_range, insn);

	insn = next_call_clobbers_ignoring (*call_group, def->insn (),
	ignore);
	if (insn)
	move_range = move_earlier_than (move_range, insn);
	}
	}

	// Make sure that we don't move stores between basic blocks, since we
	// don't have enough information to tell whether it's safe.
	if (def_info *def = memory_access (defs))
	{
	move_range = move_later_than (move_range, def->bb ()->head_insn ());
	move_range = move_earlier_than (move_range, def->bb ()->end_insn ());
	}

	return bool (move_range);
	}

	// Like restrict_movement_for_defs_ignoring, but for the uses in USES.
	template<typename IgnorePredicate>
	bool
	restrict_movement_for_uses_ignoring (insn_range_info &move_range,
	use_array uses, IgnorePredicate ignore)
	{
	for (const use_info *use : uses)
	{
	// Ignore uses of undefined values.
	set_info *set = use->def ();
	if (!set)
	continue;

	// Ignore uses by debug instructions. Debug instructions are
	// never supposed to move, and uses by debug instructions are
	// never supposed to be transferred elsewhere, so we know that
	// the caller must be changing the uses on the debug instruction
	// and checking whether all new uses are available at the debug
	// instruction's original location.
	if (use->is_in_debug_insn ())
	continue;

	// If the used value is defined by an instruction I2 for which
	// IGNORE (I2) is true, the caller guarantees that I2 will occur
	// before change.insn (). Otherwise, make sure that the use occurs
	// after the definition.
	insn_info *insn = set->insn ();
	if (!ignore (insn))
	move_range = move_later_than (move_range, insn);

	// Search forward for the first unfiltered definition that follows SET.
	//
	// We don't need to consider the uses of these definitions, since
	// if IGNORE (D->insn ()) is true for some definition D, the caller
	// is guarantees that either
	//
	// - D will be removed, and thus its uses will be removed; or
	// - D will occur after USE, and thus D's uses will also occur
	// after USE.
	//
	// This is purely a simplification: we could also process D's uses,
	// but we don't need to.
	def_info *def;
	def = first_def_ignoring (set->next_def (), ignore_clobbers::NO,
	ignore);
	if (def)
	move_range = move_earlier_than (move_range, def->insn ());

	// If USE uses a hard register, take any call clobbers into account too.
	// SET will necessarily occur after any previous call clobber, so we
	// only need to check for later clobbers.
	unsigned int regno = use->regno ();
	if (!HARD_REGISTER_NUM_P (regno))
	continue;

	ebb_info *ebb = use->ebb ();
	for (ebb_call_clobbers_info *call_group : ebb->call_clobbers ())
	{
	if (!call_group->clobbers (use->resource ()))
	continue;

	if (!move_range)
	return false;

	insn_info insn = next_call_clobbers_ignoring (call_group,
	use->insn (), ignore);
	if (insn)
	move_range = move_earlier_than (move_range, insn);
	}
	}

	// Make sure that we don't move loads into an earlier basic block.
	//
	// ??? It would be good to relax this for loads that can be safely
	// speculated.
	if (use_info *use = memory_access (uses))
	move_range = move_later_than (move_range, use->bb ()->head_insn ());

	return bool (move_range);
	}

	}