486 lines
14 KiB
C
486 lines
14 KiB
C
/* Generic routines for manipulating PHIs
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Copyright (C) 2003, 2005 Free Software Foundation, Inc.
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This file is part of GCC.
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GCC is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 2, or (at your option)
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any later version.
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GCC is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with GCC; see the file COPYING. If not, write to
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the Free Software Foundation, 51 Franklin Street, Fifth Floor,
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Boston, MA 02110-1301, USA. */
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#include "config.h"
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#include "system.h"
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#include "coretypes.h"
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#include "tm.h"
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#include "tree.h"
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#include "rtl.h"
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#include "varray.h"
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#include "ggc.h"
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#include "basic-block.h"
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#include "tree-flow.h"
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#include "toplev.h"
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/* Rewriting a function into SSA form can create a huge number of PHIs
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many of which may be thrown away shortly after their creation if jumps
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were threaded through PHI nodes.
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While our garbage collection mechanisms will handle this situation, it
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is extremely wasteful to create nodes and throw them away, especially
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when the nodes can be reused.
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For PR 8361, we can significantly reduce the number of nodes allocated
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and thus the total amount of memory allocated by managing PHIs a
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little. This additionally helps reduce the amount of work done by the
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garbage collector. Similar results have been seen on a wider variety
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of tests (such as the compiler itself).
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Right now we maintain our free list on a per-function basis. It may
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or may not make sense to maintain the free list for the duration of
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a compilation unit.
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We could also use a zone allocator for these objects since they have
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a very well defined lifetime. If someone wants to experiment with that
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this is the place to try it.
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PHI nodes have different sizes, so we can't have a single list of all
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the PHI nodes as it would be too expensive to walk down that list to
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find a PHI of a suitable size.
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Instead we have an array of lists of free PHI nodes. The array is
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indexed by the number of PHI alternatives that PHI node can hold.
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Except for the last array member, which holds all remaining PHI
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nodes.
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So to find a free PHI node, we compute its index into the free PHI
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node array and see if there are any elements with an exact match.
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If so, then we are done. Otherwise, we test the next larger size
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up and continue until we are in the last array element.
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We do not actually walk members of the last array element. While it
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might allow us to pick up a few reusable PHI nodes, it could potentially
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be very expensive if the program has released a bunch of large PHI nodes,
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but keeps asking for even larger PHI nodes. Experiments have shown that
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walking the elements of the last array entry would result in finding less
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than .1% additional reusable PHI nodes.
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Note that we can never have less than two PHI argument slots. Thus,
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the -2 on all the calculations below. */
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#define NUM_BUCKETS 10
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static GTY ((deletable (""))) tree free_phinodes[NUM_BUCKETS - 2];
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static unsigned long free_phinode_count;
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static int ideal_phi_node_len (int);
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static void resize_phi_node (tree *, int);
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#ifdef GATHER_STATISTICS
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unsigned int phi_nodes_reused;
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unsigned int phi_nodes_created;
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#endif
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/* Initialize management of PHIs. */
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void
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init_phinodes (void)
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{
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int i;
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for (i = 0; i < NUM_BUCKETS - 2; i++)
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free_phinodes[i] = NULL;
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free_phinode_count = 0;
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}
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/* Finalize management of PHIs. */
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void
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fini_phinodes (void)
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{
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int i;
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for (i = 0; i < NUM_BUCKETS - 2; i++)
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free_phinodes[i] = NULL;
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free_phinode_count = 0;
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}
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/* Dump some simple statistics regarding the re-use of PHI nodes. */
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#ifdef GATHER_STATISTICS
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void
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phinodes_print_statistics (void)
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{
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fprintf (stderr, "PHI nodes allocated: %u\n", phi_nodes_created);
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fprintf (stderr, "PHI nodes reused: %u\n", phi_nodes_reused);
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}
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#endif
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/* Allocate a PHI node with at least LEN arguments. If the free list
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happens to contain a PHI node with LEN arguments or more, return
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that one. */
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static inline tree
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allocate_phi_node (int len)
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{
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tree phi;
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int bucket = NUM_BUCKETS - 2;
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int size = (sizeof (struct tree_phi_node)
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+ (len - 1) * sizeof (struct phi_arg_d));
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if (free_phinode_count)
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for (bucket = len - 2; bucket < NUM_BUCKETS - 2; bucket++)
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if (free_phinodes[bucket])
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break;
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/* If our free list has an element, then use it. */
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if (bucket < NUM_BUCKETS - 2
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&& PHI_ARG_CAPACITY (free_phinodes[bucket]) >= len)
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{
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free_phinode_count--;
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phi = free_phinodes[bucket];
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free_phinodes[bucket] = PHI_CHAIN (free_phinodes[bucket]);
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#ifdef GATHER_STATISTICS
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phi_nodes_reused++;
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#endif
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}
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else
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{
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phi = ggc_alloc (size);
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#ifdef GATHER_STATISTICS
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phi_nodes_created++;
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tree_node_counts[(int) phi_kind]++;
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tree_node_sizes[(int) phi_kind] += size;
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#endif
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}
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return phi;
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}
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/* Given LEN, the original number of requested PHI arguments, return
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a new, "ideal" length for the PHI node. The "ideal" length rounds
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the total size of the PHI node up to the next power of two bytes.
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Rounding up will not result in wasting any memory since the size request
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will be rounded up by the GC system anyway. [ Note this is not entirely
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true since the original length might have fit on one of the special
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GC pages. ] By rounding up, we may avoid the need to reallocate the
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PHI node later if we increase the number of arguments for the PHI. */
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static int
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ideal_phi_node_len (int len)
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{
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size_t size, new_size;
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int log2, new_len;
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/* We do not support allocations of less than two PHI argument slots. */
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if (len < 2)
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len = 2;
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/* Compute the number of bytes of the original request. */
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size = sizeof (struct tree_phi_node) + (len - 1) * sizeof (struct phi_arg_d);
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/* Round it up to the next power of two. */
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log2 = ceil_log2 (size);
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new_size = 1 << log2;
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/* Now compute and return the number of PHI argument slots given an
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ideal size allocation. */
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new_len = len + (new_size - size) / sizeof (struct phi_arg_d);
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return new_len;
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}
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/* Return a PHI node with LEN argument slots for variable VAR. */
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static tree
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make_phi_node (tree var, int len)
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{
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tree phi;
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int capacity, i;
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capacity = ideal_phi_node_len (len);
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phi = allocate_phi_node (capacity);
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/* We need to clear the entire PHI node, including the argument
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portion, because we represent a "missing PHI argument" by placing
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NULL_TREE in PHI_ARG_DEF. */
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memset (phi, 0, (sizeof (struct tree_phi_node) - sizeof (struct phi_arg_d)
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+ sizeof (struct phi_arg_d) * len));
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TREE_SET_CODE (phi, PHI_NODE);
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PHI_NUM_ARGS (phi) = len;
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PHI_ARG_CAPACITY (phi) = capacity;
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TREE_TYPE (phi) = TREE_TYPE (var);
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if (TREE_CODE (var) == SSA_NAME)
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SET_PHI_RESULT (phi, var);
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else
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SET_PHI_RESULT (phi, make_ssa_name (var, phi));
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for (i = 0; i < capacity; i++)
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{
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use_operand_p imm;
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imm = &(PHI_ARG_IMM_USE_NODE (phi, i));
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imm->use = &(PHI_ARG_DEF_TREE (phi, i));
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imm->prev = NULL;
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imm->next = NULL;
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imm->stmt = phi;
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}
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return phi;
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}
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/* We no longer need PHI, release it so that it may be reused. */
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void
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release_phi_node (tree phi)
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{
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int bucket;
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int len = PHI_ARG_CAPACITY (phi);
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int x;
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for (x = 0; x < PHI_NUM_ARGS (phi); x++)
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{
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use_operand_p imm;
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imm = &(PHI_ARG_IMM_USE_NODE (phi, x));
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delink_imm_use (imm);
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}
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bucket = len > NUM_BUCKETS - 1 ? NUM_BUCKETS - 1 : len;
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bucket -= 2;
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PHI_CHAIN (phi) = free_phinodes[bucket];
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free_phinodes[bucket] = phi;
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free_phinode_count++;
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}
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/* Resize an existing PHI node. The only way is up. Return the
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possibly relocated phi. */
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static void
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resize_phi_node (tree *phi, int len)
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{
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int old_size, i;
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tree new_phi;
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gcc_assert (len > PHI_ARG_CAPACITY (*phi));
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/* The garbage collector will not look at the PHI node beyond the
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first PHI_NUM_ARGS elements. Therefore, all we have to copy is a
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portion of the PHI node currently in use. */
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old_size = (sizeof (struct tree_phi_node)
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+ (PHI_NUM_ARGS (*phi) - 1) * sizeof (struct phi_arg_d));
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new_phi = allocate_phi_node (len);
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memcpy (new_phi, *phi, old_size);
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for (i = 0; i < PHI_NUM_ARGS (new_phi); i++)
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{
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use_operand_p imm, old_imm;
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imm = &(PHI_ARG_IMM_USE_NODE (new_phi, i));
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old_imm = &(PHI_ARG_IMM_USE_NODE (*phi, i));
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imm->use = &(PHI_ARG_DEF_TREE (new_phi, i));
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relink_imm_use_stmt (imm, old_imm, new_phi);
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}
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PHI_ARG_CAPACITY (new_phi) = len;
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for (i = PHI_NUM_ARGS (new_phi); i < len; i++)
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{
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use_operand_p imm;
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imm = &(PHI_ARG_IMM_USE_NODE (new_phi, i));
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imm->use = &(PHI_ARG_DEF_TREE (new_phi, i));
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imm->prev = NULL;
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imm->next = NULL;
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imm->stmt = new_phi;
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}
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*phi = new_phi;
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}
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/* Reserve PHI arguments for a new edge to basic block BB. */
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void
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reserve_phi_args_for_new_edge (basic_block bb)
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{
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tree *loc;
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int len = EDGE_COUNT (bb->preds);
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int cap = ideal_phi_node_len (len + 4);
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for (loc = &(bb->phi_nodes);
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*loc;
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loc = &PHI_CHAIN (*loc))
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{
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if (len > PHI_ARG_CAPACITY (*loc))
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{
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tree old_phi = *loc;
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resize_phi_node (loc, cap);
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/* The result of the phi is defined by this phi node. */
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SSA_NAME_DEF_STMT (PHI_RESULT (*loc)) = *loc;
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release_phi_node (old_phi);
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}
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/* We represent a "missing PHI argument" by placing NULL_TREE in
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the corresponding slot. If PHI arguments were added
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immediately after an edge is created, this zeroing would not
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be necessary, but unfortunately this is not the case. For
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example, the loop optimizer duplicates several basic blocks,
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redirects edges, and then fixes up PHI arguments later in
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batch. */
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SET_PHI_ARG_DEF (*loc, len - 1, NULL_TREE);
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PHI_NUM_ARGS (*loc)++;
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}
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}
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/* Create a new PHI node for variable VAR at basic block BB. */
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tree
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create_phi_node (tree var, basic_block bb)
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{
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tree phi;
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phi = make_phi_node (var, EDGE_COUNT (bb->preds));
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/* Add the new PHI node to the list of PHI nodes for block BB. */
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PHI_CHAIN (phi) = phi_nodes (bb);
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bb->phi_nodes = phi;
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/* Associate BB to the PHI node. */
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set_bb_for_stmt (phi, bb);
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return phi;
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}
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/* Add a new argument to PHI node PHI. DEF is the incoming reaching
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definition and E is the edge through which DEF reaches PHI. The new
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argument is added at the end of the argument list.
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If PHI has reached its maximum capacity, add a few slots. In this case,
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PHI points to the reallocated phi node when we return. */
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void
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add_phi_arg (tree phi, tree def, edge e)
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{
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basic_block bb = e->dest;
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gcc_assert (bb == bb_for_stmt (phi));
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/* We resize PHI nodes upon edge creation. We should always have
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enough room at this point. */
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gcc_assert (PHI_NUM_ARGS (phi) <= PHI_ARG_CAPACITY (phi));
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/* We resize PHI nodes upon edge creation. We should always have
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enough room at this point. */
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gcc_assert (e->dest_idx < (unsigned int) PHI_NUM_ARGS (phi));
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/* Copy propagation needs to know what object occur in abnormal
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PHI nodes. This is a convenient place to record such information. */
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if (e->flags & EDGE_ABNORMAL)
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{
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SSA_NAME_OCCURS_IN_ABNORMAL_PHI (def) = 1;
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SSA_NAME_OCCURS_IN_ABNORMAL_PHI (PHI_RESULT (phi)) = 1;
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}
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SET_PHI_ARG_DEF (phi, e->dest_idx, def);
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PHI_ARG_NONZERO (phi, e->dest_idx) = false;
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}
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/* Remove the Ith argument from PHI's argument list. This routine
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implements removal by swapping the last alternative with the
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alternative we want to delete and then shrinking the vector, which
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is consistent with how we remove an edge from the edge vector. */
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static void
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remove_phi_arg_num (tree phi, int i)
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{
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int num_elem = PHI_NUM_ARGS (phi);
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gcc_assert (i < num_elem);
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/* Delink the last item, which is being removed. */
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delink_imm_use (&(PHI_ARG_IMM_USE_NODE (phi, num_elem - 1)));
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/* If we are not at the last element, switch the last element
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with the element we want to delete. */
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if (i != num_elem - 1)
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{
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SET_PHI_ARG_DEF (phi, i, PHI_ARG_DEF (phi, num_elem - 1));
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PHI_ARG_NONZERO (phi, i) = PHI_ARG_NONZERO (phi, num_elem - 1);
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}
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/* Shrink the vector and return. Note that we do not have to clear
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PHI_ARG_DEF or PHI_ARG_NONZERO because the garbage collector will
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not look at those elements beyond the first PHI_NUM_ARGS elements
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of the array. */
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PHI_NUM_ARGS (phi)--;
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}
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/* Remove all PHI arguments associated with edge E. */
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void
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remove_phi_args (edge e)
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{
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tree phi;
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for (phi = phi_nodes (e->dest); phi; phi = PHI_CHAIN (phi))
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remove_phi_arg_num (phi, e->dest_idx);
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}
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/* Remove PHI node PHI from basic block BB. If PREV is non-NULL, it is
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used as the node immediately before PHI in the linked list. */
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void
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remove_phi_node (tree phi, tree prev)
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{
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tree *loc;
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if (prev)
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{
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loc = &PHI_CHAIN (prev);
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}
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else
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{
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for (loc = &(bb_for_stmt (phi)->phi_nodes);
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*loc != phi;
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loc = &PHI_CHAIN (*loc))
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;
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}
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/* Remove PHI from the chain. */
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*loc = PHI_CHAIN (phi);
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/* If we are deleting the PHI node, then we should release the
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SSA_NAME node so that it can be reused. */
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release_phi_node (phi);
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release_ssa_name (PHI_RESULT (phi));
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}
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/* Reverse the order of PHI nodes in the chain PHI.
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Return the new head of the chain (old last PHI node). */
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tree
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phi_reverse (tree phi)
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{
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tree prev = NULL_TREE, next;
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for (; phi; phi = next)
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{
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next = PHI_CHAIN (phi);
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PHI_CHAIN (phi) = prev;
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prev = phi;
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}
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return prev;
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}
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#include "gt-tree-phinodes.h"
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