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/* Generic routines for manipulating PHIs

   Copyright (C) 2003, 2005, 2007, 2008 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/>.  */

#include "config.h"

#include "system.h"

#include "coretypes.h"

#include "tm.h"

#include "tree.h"

#include "rtl.h"

#include "varray.h"

#include "ggc.h"

#include "basic-block.h"

#include "tree-flow.h"

#include "toplev.h"

#include "gimple.h"

/* Rewriting a function into SSA form can create a huge number of PHIs

   many of which may be thrown away shortly after their creation if jumps

   were threaded through PHI nodes.

   While our garbage collection mechanisms will handle this situation, it

   is extremely wasteful to create nodes and throw them away, especially

   when the nodes can be reused.

   For PR 8361, we can significantly reduce the number of nodes allocated

   and thus the total amount of memory allocated by managing PHIs a

   little.  This additionally helps reduce the amount of work done by the

   garbage collector.  Similar results have been seen on a wider variety

   of tests (such as the compiler itself).

   Right now we maintain our free list on a per-function basis.  It may

   or may not make sense to maintain the free list for the duration of

   a compilation unit.

   We could also use a zone allocator for these objects since they have

   a very well defined lifetime.  If someone wants to experiment with that

   this is the place to try it.

   PHI nodes have different sizes, so we can't have a single list of all

   the PHI nodes as it would be too expensive to walk down that list to

   find a PHI of a suitable size.

   Instead we have an array of lists of free PHI nodes.  The array is

   indexed by the number of PHI alternatives that PHI node can hold.

   Except for the last array member, which holds all remaining PHI

   nodes.

   So to find a free PHI node, we compute its index into the free PHI

   node array and see if there are any elements with an exact match.

   If so, then we are done.  Otherwise, we test the next larger size

   up and continue until we are in the last array element.

   We do not actually walk members of the last array element.  While it

   might allow us to pick up a few reusable PHI nodes, it could potentially

   be very expensive if the program has released a bunch of large PHI nodes,

   but keeps asking for even larger PHI nodes.  Experiments have shown that

   walking the elements of the last array entry would result in finding less

   than .1% additional reusable PHI nodes.

   Note that we can never have less than two PHI argument slots.  Thus,

   the -2 on all the calculations below.  */

#define NUM_BUCKETS 10

static GTY ((deletable (""))) VEC(gimple,gc) *free_phinodes[NUM_BUCKETS - 2];

static unsigned long free_phinode_count;

static int ideal_phi_node_len (int);

#ifdef GATHER_STATISTICS

unsigned int phi_nodes_reused;

unsigned int phi_nodes_created;

#endif

/* Initialize management of PHIs.  */

void

init_phinodes (void)

{

  int i;

  for (i = 0; i < NUM_BUCKETS - 2; i++)

    free_phinodes[i] = NULL;

  free_phinode_count = 0;

}

/* Finalize management of PHIs.  */

void

fini_phinodes (void)

{

  int i;

  for (i = 0; i < NUM_BUCKETS - 2; i++)

    free_phinodes[i] = NULL;

  free_phinode_count = 0;

}

/* Dump some simple statistics regarding the re-use of PHI nodes.  */

#ifdef GATHER_STATISTICS

void

phinodes_print_statistics (void)

{

  fprintf (stderr, "PHI nodes allocated: %u\n", phi_nodes_created);

  fprintf (stderr, "PHI nodes reused: %u\n", phi_nodes_reused);

}

#endif

/* Allocate a PHI node with at least LEN arguments.  If the free list

   happens to contain a PHI node with LEN arguments or more, return

   that one.  */

static inline gimple

allocate_phi_node (size_t len)

{

  gimple phi;

  size_t bucket = NUM_BUCKETS - 2;

  size_t size = sizeof (struct gimple_statement_phi)

                + (len - 1) * sizeof (struct phi_arg_d);

  if (free_phinode_count)

    for (bucket = len - 2; bucket < NUM_BUCKETS - 2; bucket++)

      if (free_phinodes[bucket])

        break;

  /* If our free list has an element, then use it.  */

  if (bucket < NUM_BUCKETS - 2

      && gimple_phi_capacity (VEC_index (gimple, free_phinodes[bucket], 0))

         >= len)

    {

      free_phinode_count--;

      phi = VEC_pop (gimple, free_phinodes[bucket]);

      if (VEC_empty (gimple, free_phinodes[bucket]))

        VEC_free (gimple, gc, free_phinodes[bucket]);

#ifdef GATHER_STATISTICS

      phi_nodes_reused++;

#endif

    }

  else

    {

      phi = (gimple) ggc_alloc (size);

#ifdef GATHER_STATISTICS

      phi_nodes_created++;

        {

          enum gimple_alloc_kind kind = gimple_alloc_kind (GIMPLE_PHI);

          gimple_alloc_counts[(int) kind]++;

          gimple_alloc_sizes[(int) kind] += size;

        }

#endif

    }

  return phi;

}

/* Given LEN, the original number of requested PHI arguments, return

   a new, "ideal" length for the PHI node.  The "ideal" length rounds

   the total size of the PHI node up to the next power of two bytes.

   Rounding up will not result in wasting any memory since the size request

   will be rounded up by the GC system anyway.  [ Note this is not entirely

   true since the original length might have fit on one of the special

   GC pages. ]  By rounding up, we may avoid the need to reallocate the

   PHI node later if we increase the number of arguments for the PHI.  */

static int

ideal_phi_node_len (int len)

{

  size_t size, new_size;

  int log2, new_len;

  /* We do not support allocations of less than two PHI argument slots.  */

  if (len < 2)

    len = 2;

  /* Compute the number of bytes of the original request.  */

  size = sizeof (struct gimple_statement_phi)

         + (len - 1) * sizeof (struct phi_arg_d);

  /* Round it up to the next power of two.  */

  log2 = ceil_log2 (size);

  new_size = 1 << log2;

  /* Now compute and return the number of PHI argument slots given an

     ideal size allocation.  */

  new_len = len + (new_size - size) / sizeof (struct phi_arg_d);

  return new_len;

}

/* Return a PHI node with LEN argument slots for variable VAR.  */

gimple

make_phi_node (tree var, int len)

{

  gimple phi;

  int capacity, i;

  capacity = ideal_phi_node_len (len);

  phi = allocate_phi_node (capacity);

  /* We need to clear the entire PHI node, including the argument

     portion, because we represent a "missing PHI argument" by placing

     NULL_TREE in PHI_ARG_DEF.  */

  memset (phi, 0, (sizeof (struct gimple_statement_phi)

                   - sizeof (struct phi_arg_d)

                   + sizeof (struct phi_arg_d) * len));

  phi->gsbase.code = GIMPLE_PHI;

  phi->gimple_phi.nargs = len;

  phi->gimple_phi.capacity = capacity;

  if (TREE_CODE (var) == SSA_NAME)

    gimple_phi_set_result (phi, var);

  else

    gimple_phi_set_result (phi, make_ssa_name (var, phi));

  for (i = 0; i < capacity; i++)

    {

      use_operand_p  imm;

      gimple_phi_arg_set_location (phi, i, UNKNOWN_LOCATION);

      imm = gimple_phi_arg_imm_use_ptr (phi, i);

      imm->use = gimple_phi_arg_def_ptr (phi, i);

      imm->prev = NULL;

      imm->next = NULL;

      imm->loc.stmt = phi;

    }

  return phi;

}

/* We no longer need PHI, release it so that it may be reused.  */

void

release_phi_node (gimple phi)

{

  size_t bucket;

  size_t len = gimple_phi_capacity (phi);

  size_t x;

  for (x = 0; x < gimple_phi_num_args (phi); x++)

    {

      use_operand_p  imm;

      imm = gimple_phi_arg_imm_use_ptr (phi, x);

      delink_imm_use (imm);

    }

  bucket = len > NUM_BUCKETS - 1 ? NUM_BUCKETS - 1 : len;

  bucket -= 2;

  VEC_safe_push (gimple, gc, free_phinodes[bucket], phi);

  free_phinode_count++;

}

/* Resize an existing PHI node.  The only way is up.  Return the

   possibly relocated phi.  */

static void

resize_phi_node (gimple *phi, size_t len)

{

  size_t old_size, i;

  gimple new_phi;

  gcc_assert (len > gimple_phi_capacity (*phi));

  /* The garbage collector will not look at the PHI node beyond the

     first PHI_NUM_ARGS elements.  Therefore, all we have to copy is a

     portion of the PHI node currently in use.  */

  old_size = sizeof (struct gimple_statement_phi)

             + (gimple_phi_num_args (*phi) - 1) * sizeof (struct phi_arg_d);

  new_phi = allocate_phi_node (len);

  memcpy (new_phi, *phi, old_size);

  for (i = 0; i < gimple_phi_num_args (new_phi); i++)

    {

      use_operand_p imm, old_imm;

      imm = gimple_phi_arg_imm_use_ptr (new_phi, i);

      old_imm = gimple_phi_arg_imm_use_ptr (*phi, i);

      imm->use = gimple_phi_arg_def_ptr (new_phi, i);

      relink_imm_use_stmt (imm, old_imm, new_phi);

    }

  new_phi->gimple_phi.capacity = len;

  for (i = gimple_phi_num_args (new_phi); i < len; i++)

    {

      use_operand_p imm;

      gimple_phi_arg_set_location (new_phi, i, UNKNOWN_LOCATION);

      imm = gimple_phi_arg_imm_use_ptr (new_phi, i);

      imm->use = gimple_phi_arg_def_ptr (new_phi, i);

      imm->prev = NULL;

      imm->next = NULL;

      imm->loc.stmt = new_phi;

    }

  *phi = new_phi;

}

/* Reserve PHI arguments for a new edge to basic block BB.  */

void

reserve_phi_args_for_new_edge (basic_block bb)

{

  size_t len = EDGE_COUNT (bb->preds);

  size_t cap = ideal_phi_node_len (len + 4);

  gimple_stmt_iterator gsi;

  for (gsi = gsi_start_phis (bb); !gsi_end_p (gsi); gsi_next (&gsi))

    {

      gimple *loc = gsi_stmt_ptr (&gsi);

      if (len > gimple_phi_capacity (*loc))

        {

          gimple old_phi = *loc;

          resize_phi_node (loc, cap);

          /* The result of the PHI is defined by this PHI node.  */

          SSA_NAME_DEF_STMT (gimple_phi_result (*loc)) = *loc;

          release_phi_node (old_phi);

        }

      /* We represent a "missing PHI argument" by placing NULL_TREE in

         the corresponding slot.  If PHI arguments were added

         immediately after an edge is created, this zeroing would not

         be necessary, but unfortunately this is not the case.  For

         example, the loop optimizer duplicates several basic blocks,

         redirects edges, and then fixes up PHI arguments later in

         batch.  */

      SET_PHI_ARG_DEF (*loc, len - 1, NULL_TREE);

      (*loc)->gimple_phi.nargs++;

    }

}

/* Adds PHI to BB.  */

void

add_phi_node_to_bb (gimple phi, basic_block bb)

{

  gimple_stmt_iterator gsi;

  /* Add the new PHI node to the list of PHI nodes for block BB.  */

  if (phi_nodes (bb) == NULL)

    set_phi_nodes (bb, gimple_seq_alloc ());

  gsi = gsi_last (phi_nodes (bb));

  gsi_insert_after (&gsi, phi, GSI_NEW_STMT);

  /* Associate BB to the PHI node.  */

  gimple_set_bb (phi, bb);

}

/* Create a new PHI node for variable VAR at basic block BB.  */

gimple

create_phi_node (tree var, basic_block bb)

{

  gimple phi = make_phi_node (var, EDGE_COUNT (bb->preds));

  add_phi_node_to_bb (phi, bb);

  return phi;

}

/* Add a new argument to PHI node PHI.  DEF is the incoming reaching

   definition and E is the edge through which DEF reaches PHI.  The new

   argument is added at the end of the argument list.

   If PHI has reached its maximum capacity, add a few slots.  In this case,

   PHI points to the reallocated phi node when we return.  */

void

add_phi_arg (gimple phi, tree def, edge e, source_location locus)

{

  basic_block bb = e->dest;

  gcc_assert (bb == gimple_bb (phi));

  /* We resize PHI nodes upon edge creation.  We should always have

     enough room at this point.  */

  gcc_assert (gimple_phi_num_args (phi) <= gimple_phi_capacity (phi));

  /* We resize PHI nodes upon edge creation.  We should always have

     enough room at this point.  */

  gcc_assert (e->dest_idx < gimple_phi_num_args (phi));

  /* Copy propagation needs to know what object occur in abnormal

     PHI nodes.  This is a convenient place to record such information.  */

  if (e->flags & EDGE_ABNORMAL)

    {

      SSA_NAME_OCCURS_IN_ABNORMAL_PHI (def) = 1;

      SSA_NAME_OCCURS_IN_ABNORMAL_PHI (PHI_RESULT (phi)) = 1;

    }

  SET_PHI_ARG_DEF (phi, e->dest_idx, def);

  gimple_phi_arg_set_location (phi, e->dest_idx, locus);

}

/* Remove the Ith argument from PHI's argument list.  This routine

   implements removal by swapping the last alternative with the

   alternative we want to delete and then shrinking the vector, which

   is consistent with how we remove an edge from the edge vector.  */

static void

remove_phi_arg_num (gimple phi, int i)

{

  int num_elem = gimple_phi_num_args (phi);

  gcc_assert (i < num_elem);

  /* Delink the item which is being removed.  */

  delink_imm_use (gimple_phi_arg_imm_use_ptr (phi, i));

  /* If it is not the last element, move the last element

     to the element we want to delete, resetting all the links. */

  if (i != num_elem - 1)

    {

      use_operand_p old_p, new_p;

      old_p = gimple_phi_arg_imm_use_ptr (phi, num_elem - 1);

      new_p = gimple_phi_arg_imm_use_ptr (phi, i);

      /* Set use on new node, and link into last element's place.  */

      *(new_p->use) = *(old_p->use);

      relink_imm_use (new_p, old_p);

      /* Move the location as well.  */

      gimple_phi_arg_set_location (phi, i,

                                   gimple_phi_arg_location (phi, num_elem - 1));

    }

  /* Shrink the vector and return.  Note that we do not have to clear

     PHI_ARG_DEF because the garbage collector will not look at those

     elements beyond the first PHI_NUM_ARGS elements of the array.  */

  phi->gimple_phi.nargs--;

}

/* Remove all PHI arguments associated with edge E.  */

void

remove_phi_args (edge e)

{

  gimple_stmt_iterator gsi;

  for (gsi = gsi_start_phis (e->dest); !gsi_end_p (gsi); gsi_next (&gsi))

    remove_phi_arg_num (gsi_stmt (gsi), e->dest_idx);

}

/* Remove the PHI node pointed-to by iterator GSI from basic block BB.  After

   removal, iterator GSI is updated to point to the next PHI node in the

   sequence. If RELEASE_LHS_P is true, the LHS of this PHI node is released

   into the free pool of SSA names.  */

void

remove_phi_node (gimple_stmt_iterator *gsi, bool release_lhs_p)

{

  gimple phi = gsi_stmt (*gsi);

  if (release_lhs_p)

    insert_debug_temps_for_defs (gsi);

  gsi_remove (gsi, false);

  /* If we are deleting the PHI node, then we should release the

     SSA_NAME node so that it can be reused.  */

  release_phi_node (phi);

  if (release_lhs_p)

    release_ssa_name (gimple_phi_result (phi));

}

/* Remove all the phi nodes from BB.  */

void

remove_phi_nodes (basic_block bb)

{

  gimple_stmt_iterator gsi;

  for (gsi = gsi_start_phis (bb); !gsi_end_p (gsi); )

    remove_phi_node (&gsi, true);

  set_phi_nodes (bb, NULL);

}

#include "gt-tree-phinodes.h"