gcc/et-forest.c - gcc - Git at Google

 /* ET-trees data structure implementation.
    Contributed by Pavel Nejedly
    Copyright (C) 2002, 2003, 2004, 2005, 2007, 2008, 2010 Free Software
    Foundation, Inc.

 This file is part of the libiberty library.
 Libiberty is free software; you can redistribute it and/or
 modify it under the terms of the GNU Library General Public
 License as published by the Free Software Foundation; either
 version 3 of the License, or (at your option) any later version.

 Libiberty 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
 Library General Public License for more details.

 You should have received a copy of the GNU Library General Public
 License along with libiberty; see the file COPYING3.  If not see
 <http://www.gnu.org/licenses/>.

   The ET-forest structure is described in:
     D. D. Sleator and R. E. Tarjan. A data structure for dynamic trees.
     J.  G'omput. System Sci., 26(3):362 381, 1983.
 */

 #include "config.h"
 #include "system.h"
 #include "coretypes.h"
 #include "et-forest.h"
 #include "alloc-pool.h"

 /* We do not enable this with ENABLE_CHECKING, since it is awfully slow.  */
 #undef DEBUG_ET

 #ifdef DEBUG_ET
 #include "basic-block.h"
 #endif

 /* The occurrence of a node in the et tree.  */
 struct et_occ
 {
   struct et_node *of;		/* The node.  */

   struct et_occ *parent;	/* Parent in the splay-tree.  */
   struct et_occ *prev;		/* Left son in the splay-tree.  */
   struct et_occ *next;		/* Right son in the splay-tree.  */

   int depth;			/* The depth of the node is the sum of depth
 				   fields on the path to the root.  */
   int min;			/* The minimum value of the depth in the subtree
 				   is obtained by adding sum of depth fields
 				   on the path to the root.  */
   struct et_occ *min_occ;	/* The occurrence in the subtree with the minimal
 				   depth.  */
 };

 static alloc_pool et_nodes;
 static alloc_pool et_occurrences;

 /* Changes depth of OCC to D.  */

 static inline void
 set_depth (struct et_occ *occ, int d)
 {
   if (!occ)
     return;

   occ->min += d - occ->depth;
   occ->depth = d;
 }

 /* Adds D to the depth of OCC.  */

 static inline void
 set_depth_add (struct et_occ *occ, int d)
 {
   if (!occ)
     return;

   occ->min += d;
   occ->depth += d;
 }

 /* Sets prev field of OCC to P.  */

 static inline void
 set_prev (struct et_occ *occ, struct et_occ *t)
 {
 #ifdef DEBUG_ET
   gcc_assert (occ != t);
 #endif

   occ->prev = t;
   if (t)
     t->parent = occ;
 }

 /* Sets next field of OCC to P.  */

 static inline void
 set_next (struct et_occ *occ, struct et_occ *t)
 {
 #ifdef DEBUG_ET
   gcc_assert (occ != t);
 #endif

   occ->next = t;
   if (t)
     t->parent = occ;
 }

 /* Recompute minimum for occurrence OCC.  */

 static inline void
 et_recomp_min (struct et_occ *occ)
 {
   struct et_occ *mson = occ->prev;

   if (!mson
       || (occ->next
 	  && mson->min > occ->next->min))
       mson = occ->next;

   if (mson && mson->min < 0)
     {
       occ->min = mson->min + occ->depth;
       occ->min_occ = mson->min_occ;
     }
   else
     {
       occ->min = occ->depth;
       occ->min_occ = occ;
     }
 }

 #ifdef DEBUG_ET
 /* Checks whether neighborhood of OCC seems sane.  */

 static void
 et_check_occ_sanity (struct et_occ *occ)
 {
   if (!occ)
     return;

   gcc_assert (occ->parent != occ);
   gcc_assert (occ->prev != occ);
   gcc_assert (occ->next != occ);
   gcc_assert (!occ->next || occ->next != occ->prev);

   if (occ->next)
     {
       gcc_assert (occ->next != occ->parent);
       gcc_assert (occ->next->parent == occ);
     }

   if (occ->prev)
     {
       gcc_assert (occ->prev != occ->parent);
       gcc_assert (occ->prev->parent == occ);
     }

   gcc_assert (!occ->parent
 	      || occ->parent->prev == occ
 	      || occ->parent->next == occ);
 }

 /* Checks whether tree rooted at OCC is sane.  */

 static void
 et_check_sanity (struct et_occ *occ)
 {
   et_check_occ_sanity (occ);
   if (occ->prev)
     et_check_sanity (occ->prev);
   if (occ->next)
     et_check_sanity (occ->next);
 }

 /* Checks whether tree containing OCC is sane.  */

 static void
 et_check_tree_sanity (struct et_occ *occ)
 {
   while (occ->parent)
     occ = occ->parent;

   et_check_sanity (occ);
 }

 /* For recording the paths.  */

 /* An ad-hoc constant; if the function has more blocks, this won't work,
    but since it is used for debugging only, it does not matter.  */
 #define MAX_NODES 100000

 static int len;
 static void *datas[MAX_NODES];
 static int depths[MAX_NODES];

 /* Records the path represented by OCC, with depth incremented by DEPTH.  */

 static int
 record_path_before_1 (struct et_occ *occ, int depth)
 {
   int mn, m;

   depth += occ->depth;
   mn = depth;

   if (occ->prev)
     {
       m = record_path_before_1 (occ->prev, depth);
       if (m < mn)
 	mn = m;
     }

   fprintf (stderr, "%d (%d); ", ((basic_block) occ->of->data)->index, depth);

   gcc_assert (len < MAX_NODES);

   depths[len] = depth;
   datas[len] = occ->of;
   len++;

   if (occ->next)
     {
       m = record_path_before_1 (occ->next, depth);
       if (m < mn)
 	mn = m;
     }

   gcc_assert (mn == occ->min + depth - occ->depth);

   return mn;
 }

 /* Records the path represented by a tree containing OCC.  */

 static void
 record_path_before (struct et_occ *occ)
 {
   while (occ->parent)
     occ = occ->parent;

   len = 0;
   record_path_before_1 (occ, 0);
   fprintf (stderr, "\n");
 }

 /* Checks whether the path represented by OCC, with depth incremented by DEPTH,
    was not changed since the last recording.  */

 static int
 check_path_after_1 (struct et_occ *occ, int depth)
 {
   int mn, m;

   depth += occ->depth;
   mn = depth;

   if (occ->next)
     {
       m = check_path_after_1 (occ->next, depth);
       if (m < mn)
 	mn =  m;
     }

   len--;
   gcc_assert (depths[len] == depth && datas[len] == occ->of);

   if (occ->prev)
     {
       m = check_path_after_1 (occ->prev, depth);
       if (m < mn)
 	mn =  m;
     }

   gcc_assert (mn == occ->min + depth - occ->depth);

   return mn;
 }

 /* Checks whether the path represented by a tree containing OCC was
    not changed since the last recording.  */

 static void
 check_path_after (struct et_occ *occ)
 {
   while (occ->parent)
     occ = occ->parent;

   check_path_after_1 (occ, 0);
   gcc_assert (!len);
 }

 #endif

 /* Splay the occurrence OCC to the root of the tree.  */

 static void
 et_splay (struct et_occ *occ)
 {
   struct et_occ *f, *gf, *ggf;
   int occ_depth, f_depth, gf_depth;

 #ifdef DEBUG_ET
   record_path_before (occ);
   et_check_tree_sanity (occ);
 #endif

   while (occ->parent)
     {
       occ_depth = occ->depth;

       f = occ->parent;
       f_depth = f->depth;

       gf = f->parent;

       if (!gf)
 	{
 	  set_depth_add (occ, f_depth);
 	  occ->min_occ = f->min_occ;
 	  occ->min = f->min;

 	  if (f->prev == occ)
 	    {
 	      /* zig */
 	      set_prev (f, occ->next);
 	      set_next (occ, f);
 	      set_depth_add (f->prev, occ_depth);
 	    }
 	  else
 	    {
 	      /* zag */
 	      set_next (f, occ->prev);
 	      set_prev (occ, f);
 	      set_depth_add (f->next, occ_depth);
 	    }
 	  set_depth (f, -occ_depth);
 	  occ->parent = NULL;

 	  et_recomp_min (f);
 #ifdef DEBUG_ET
 	  et_check_tree_sanity (occ);
 	  check_path_after (occ);
 #endif
 	  return;
 	}

       gf_depth = gf->depth;

       set_depth_add (occ, f_depth + gf_depth);
       occ->min_occ = gf->min_occ;
       occ->min = gf->min;

       ggf = gf->parent;

       if (gf->prev == f)
 	{
 	  if (f->prev == occ)
 	    {
 	      /* zig zig */
 	      set_prev (gf, f->next);
 	      set_prev (f, occ->next);
 	      set_next (occ, f);
 	      set_next (f, gf);

 	      set_depth (f, -occ_depth);
 	      set_depth_add (f->prev, occ_depth);
 	      set_depth (gf, -f_depth);
 	      set_depth_add (gf->prev, f_depth);
 	    }
 	  else
 	    {
 	      /* zag zig */
 	      set_prev (gf, occ->next);
 	      set_next (f, occ->prev);
 	      set_prev (occ, f);
 	      set_next (occ, gf);

 	      set_depth (f, -occ_depth);
 	      set_depth_add (f->next, occ_depth);
 	      set_depth (gf, -occ_depth - f_depth);
 	      set_depth_add (gf->prev, occ_depth + f_depth);
 	    }
 	}
       else
 	{
 	  if (f->prev == occ)
 	    {
 	      /* zig zag */
 	      set_next (gf, occ->prev);
 	      set_prev (f, occ->next);
 	      set_prev (occ, gf);
 	      set_next (occ, f);

 	      set_depth (f, -occ_depth);
 	      set_depth_add (f->prev, occ_depth);
 	      set_depth (gf, -occ_depth - f_depth);
 	      set_depth_add (gf->next, occ_depth + f_depth);
 	    }
 	  else
 	    {
 	      /* zag zag */
 	      set_next (gf, f->prev);
 	      set_next (f, occ->prev);
 	      set_prev (occ, f);
 	      set_prev (f, gf);

 	      set_depth (f, -occ_depth);
 	      set_depth_add (f->next, occ_depth);
 	      set_depth (gf, -f_depth);
 	      set_depth_add (gf->next, f_depth);
 	    }
 	}

       occ->parent = ggf;
       if (ggf)
 	{
 	  if (ggf->prev == gf)
 	    ggf->prev = occ;
 	  else
 	    ggf->next = occ;
 	}

       et_recomp_min (gf);
       et_recomp_min (f);
 #ifdef DEBUG_ET
       et_check_tree_sanity (occ);
 #endif
     }

 #ifdef DEBUG_ET
   et_check_sanity (occ);
   check_path_after (occ);
 #endif
 }

 /* Create a new et tree occurrence of NODE.  */

 static struct et_occ *
 et_new_occ (struct et_node *node)
 {
   struct et_occ *nw;

   if (!et_occurrences)
     et_occurrences = create_alloc_pool ("et_occ pool", sizeof (struct et_occ), 300);
   nw = (struct et_occ *) pool_alloc (et_occurrences);

   nw->of = node;
   nw->parent = NULL;
   nw->prev = NULL;
   nw->next = NULL;

   nw->depth = 0;
   nw->min_occ = nw;
   nw->min = 0;

   return nw;
 }

 /* Create a new et tree containing DATA.  */

 struct et_node *
 et_new_tree (void *data)
 {
   struct et_node *nw;

   if (!et_nodes)
     et_nodes = create_alloc_pool ("et_node pool", sizeof (struct et_node), 300);
   nw = (struct et_node *) pool_alloc (et_nodes);

   nw->data = data;
   nw->father = NULL;
   nw->left = NULL;
   nw->right = NULL;
   nw->son = NULL;

   nw->rightmost_occ = et_new_occ (nw);
   nw->parent_occ = NULL;

   return nw;
 }

 /* Releases et tree T.  */

 void
 et_free_tree (struct et_node *t)
 {
   while (t->son)
     et_split (t->son);

   if (t->father)
     et_split (t);

   pool_free (et_occurrences, t->rightmost_occ);
   pool_free (et_nodes, t);
 }

 /* Releases et tree T without maintaining other nodes.  */

 void
 et_free_tree_force (struct et_node *t)
 {
   pool_free (et_occurrences, t->rightmost_occ);
   if (t->parent_occ)
     pool_free (et_occurrences, t->parent_occ);
   pool_free (et_nodes, t);
 }

 /* Release the alloc pools, if they are empty.  */

 void
 et_free_pools (void)
 {
   free_alloc_pool_if_empty (&et_occurrences);
   free_alloc_pool_if_empty (&et_nodes);
 }

 /* Sets father of et tree T to FATHER.  */

 void
 et_set_father (struct et_node *t, struct et_node *father)
 {
   struct et_node *left, *right;
   struct et_occ *rmost, *left_part, *new_f_occ, *p;

   /* Update the path represented in the splay tree.  */
   new_f_occ = et_new_occ (father);

   rmost = father->rightmost_occ;
   et_splay (rmost);

   left_part = rmost->prev;

   p = t->rightmost_occ;
   et_splay (p);

   set_prev (new_f_occ, left_part);
   set_next (new_f_occ, p);

   p->depth++;
   p->min++;
   et_recomp_min (new_f_occ);

   set_prev (rmost, new_f_occ);

   if (new_f_occ->min + rmost->depth < rmost->min)
     {
       rmost->min = new_f_occ->min + rmost->depth;
       rmost->min_occ = new_f_occ->min_occ;
     }

   t->parent_occ = new_f_occ;

   /* Update the tree.  */
   t->father = father;
   right = father->son;
   if (right)
     left = right->left;
   else
     left = right = t;

   left->right = t;
   right->left = t;
   t->left = left;
   t->right = right;

   father->son = t;

 #ifdef DEBUG_ET
   et_check_tree_sanity (rmost);
   record_path_before (rmost);
 #endif
 }

 /* Splits the edge from T to its father.  */

 void
 et_split (struct et_node *t)
 {
   struct et_node *father = t->father;
   struct et_occ *r, *l, *rmost, *p_occ;

   /* Update the path represented by the splay tree.  */
   rmost = t->rightmost_occ;
   et_splay (rmost);

   for (r = rmost->next; r->prev; r = r->prev)
     continue;
   et_splay (r);

   r->prev->parent = NULL;
   p_occ = t->parent_occ;
   et_splay (p_occ);
   t->parent_occ = NULL;

   l = p_occ->prev;
   p_occ->next->parent = NULL;

   set_prev (r, l);

   et_recomp_min (r);

   et_splay (rmost);
   rmost->depth = 0;
   rmost->min = 0;

   pool_free (et_occurrences, p_occ);

   /* Update the tree.  */
   if (father->son == t)
     father->son = t->right;
   if (father->son == t)
     father->son = NULL;
   else
     {
       t->left->right = t->right;
       t->right->left = t->left;
     }
   t->left = t->right = NULL;
   t->father = NULL;

 #ifdef DEBUG_ET
   et_check_tree_sanity (rmost);
   record_path_before (rmost);

   et_check_tree_sanity (r);
   record_path_before (r);
 #endif
 }

 /* Finds the nearest common ancestor of the nodes N1 and N2.  */

 struct et_node *
 et_nca (struct et_node *n1, struct et_node *n2)
 {
   struct et_occ *o1 = n1->rightmost_occ, *o2 = n2->rightmost_occ, *om;
   struct et_occ *l, *r, *ret;
   int mn;

   if (n1 == n2)
     return n1;

   et_splay (o1);
   l = o1->prev;
   r = o1->next;
   if (l)
     l->parent = NULL;
   if (r)
     r->parent = NULL;
   et_splay (o2);

   if (l == o2 || (l && l->parent != NULL))
     {
       ret = o2->next;

       set_prev (o1, o2);
       if (r)
 	r->parent = o1;
     }
   else if (r == o2 || (r && r->parent != NULL))
     {
       ret = o2->prev;

       set_next (o1, o2);
       if (l)
 	l->parent = o1;
     }
   else
     {
       /* O1 and O2 are in different components of the forest.  */
       if (l)
 	l->parent = o1;
       if (r)
 	r->parent = o1;
       return NULL;
     }

   if (0 < o2->depth)
     {
       om = o1;
       mn = o1->depth;
     }
   else
     {
       om = o2;
       mn = o2->depth + o1->depth;
     }

 #ifdef DEBUG_ET
   et_check_tree_sanity (o2);
 #endif

   if (ret && ret->min + o1->depth + o2->depth < mn)
     return ret->min_occ->of;
   else
     return om->of;
 }

 /* Checks whether the node UP is an ancestor of the node DOWN.  */

 bool
 et_below (struct et_node *down, struct et_node *up)
 {
   struct et_occ *u = up->rightmost_occ, *d = down->rightmost_occ;
   struct et_occ *l, *r;

   if (up == down)
     return true;

   et_splay (u);
   l = u->prev;
   r = u->next;

   if (!l)
     return false;

   l->parent = NULL;

   if (r)
     r->parent = NULL;

   et_splay (d);

   if (l == d || l->parent != NULL)
     {
       if (r)
 	r->parent = u;
       set_prev (u, d);
 #ifdef DEBUG_ET
       et_check_tree_sanity (u);
 #endif
     }
   else
     {
       l->parent = u;

       /* In case O1 and O2 are in two different trees, we must just restore the
 	 original state.  */
       if (r && r->parent != NULL)
 	set_next (u, d);
       else
 	set_next (u, r);

 #ifdef DEBUG_ET
       et_check_tree_sanity (u);
 #endif
       return false;
     }

   if (0 >= d->depth)
     return false;

   return !d->next || d->next->min + d->depth >= 0;
 }

 /* Returns the root of the tree that contains NODE.  */

 struct et_node *
 et_root (struct et_node *node)
 {
   struct et_occ *occ = node->rightmost_occ, *r;

   /* The root of the tree corresponds to the rightmost occurrence in the
      represented path.  */
   et_splay (occ);
   for (r = occ; r->next; r = r->next)
     continue;
   et_splay (r);

   return r->of;
 }
	/* ET-trees data structure implementation.
	Contributed by Pavel Nejedly
	Copyright (C) 2002, 2003, 2004, 2005, 2007, 2008, 2010 Free Software
	Foundation, Inc.

	This file is part of the libiberty library.
	Libiberty is free software; you can redistribute it and/or
	modify it under the terms of the GNU Library General Public
	License as published by the Free Software Foundation; either
	version 3 of the License, or (at your option) any later version.

	Libiberty 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
	Library General Public License for more details.

	You should have received a copy of the GNU Library General Public
	License along with libiberty; see the file COPYING3. If not see
	<http://www.gnu.org/licenses/>.

	The ET-forest structure is described in:
	D. D. Sleator and R. E. Tarjan. A data structure for dynamic trees.
	J. G'omput. System Sci., 26(3):362 381, 1983.
	*/

	#include "config.h"
	#include "system.h"
	#include "coretypes.h"
	#include "et-forest.h"
	#include "alloc-pool.h"

	/* We do not enable this with ENABLE_CHECKING, since it is awfully slow. */
	#undef DEBUG_ET

	#ifdef DEBUG_ET
	#include "basic-block.h"
	#endif

	/* The occurrence of a node in the et tree. */
	struct et_occ
	{
	struct et_node of; / The node. */

	struct et_occ parent; / Parent in the splay-tree. */
	struct et_occ prev; / Left son in the splay-tree. */
	struct et_occ next; / Right son in the splay-tree. */

	int depth; /* The depth of the node is the sum of depth
	fields on the path to the root. */
	int min; /* The minimum value of the depth in the subtree
	is obtained by adding sum of depth fields
	on the path to the root. */
	struct et_occ min_occ; / The occurrence in the subtree with the minimal
	depth. */
	};

	static alloc_pool et_nodes;
	static alloc_pool et_occurrences;

	/* Changes depth of OCC to D. */

	static inline void
	set_depth (struct et_occ *occ, int d)
	{
	if (!occ)
	return;

	occ->min += d - occ->depth;
	occ->depth = d;
	}

	/* Adds D to the depth of OCC. */

	static inline void
	set_depth_add (struct et_occ *occ, int d)
	{
	if (!occ)
	return;

	occ->min += d;
	occ->depth += d;
	}

	/* Sets prev field of OCC to P. */

	static inline void
	set_prev (struct et_occ occ, struct et_occ t)
	{
	#ifdef DEBUG_ET
	gcc_assert (occ != t);
	#endif

	occ->prev = t;
	if (t)
	t->parent = occ;
	}

	/* Sets next field of OCC to P. */

	static inline void
	set_next (struct et_occ occ, struct et_occ t)
	{
	#ifdef DEBUG_ET
	gcc_assert (occ != t);
	#endif

	occ->next = t;
	if (t)
	t->parent = occ;
	}

	/* Recompute minimum for occurrence OCC. */

	static inline void
	et_recomp_min (struct et_occ *occ)
	{
	struct et_occ *mson = occ->prev;

	if (!mson
	\|\| (occ->next
	&& mson->min > occ->next->min))
	mson = occ->next;

	if (mson && mson->min < 0)
	{
	occ->min = mson->min + occ->depth;
	occ->min_occ = mson->min_occ;
	}
	else
	{
	occ->min = occ->depth;
	occ->min_occ = occ;
	}
	}

	#ifdef DEBUG_ET
	/* Checks whether neighborhood of OCC seems sane. */

	static void
	et_check_occ_sanity (struct et_occ *occ)
	{
	if (!occ)
	return;

	gcc_assert (occ->parent != occ);
	gcc_assert (occ->prev != occ);
	gcc_assert (occ->next != occ);
	gcc_assert (!occ->next \|\| occ->next != occ->prev);

	if (occ->next)
	{
	gcc_assert (occ->next != occ->parent);
	gcc_assert (occ->next->parent == occ);
	}

	if (occ->prev)
	{
	gcc_assert (occ->prev != occ->parent);
	gcc_assert (occ->prev->parent == occ);
	}

	gcc_assert (!occ->parent
	\|\| occ->parent->prev == occ
	\|\| occ->parent->next == occ);
	}

	/* Checks whether tree rooted at OCC is sane. */

	static void
	et_check_sanity (struct et_occ *occ)
	{
	et_check_occ_sanity (occ);
	if (occ->prev)
	et_check_sanity (occ->prev);
	if (occ->next)
	et_check_sanity (occ->next);
	}

	/* Checks whether tree containing OCC is sane. */

	static void
	et_check_tree_sanity (struct et_occ *occ)
	{
	while (occ->parent)
	occ = occ->parent;

	et_check_sanity (occ);
	}

	/* For recording the paths. */

	/* An ad-hoc constant; if the function has more blocks, this won't work,
	but since it is used for debugging only, it does not matter. */
	#define MAX_NODES 100000

	static int len;
	static void *datas[MAX_NODES];
	static int depths[MAX_NODES];

	/* Records the path represented by OCC, with depth incremented by DEPTH. */

	static int
	record_path_before_1 (struct et_occ *occ, int depth)
	{
	int mn, m;

	depth += occ->depth;
	mn = depth;

	if (occ->prev)
	{
	m = record_path_before_1 (occ->prev, depth);
	if (m < mn)
	mn = m;
	}

	fprintf (stderr, "%d (%d); ", ((basic_block) occ->of->data)->index, depth);

	gcc_assert (len < MAX_NODES);

	depths[len] = depth;
	datas[len] = occ->of;
	len++;

	if (occ->next)
	{
	m = record_path_before_1 (occ->next, depth);
	if (m < mn)
	mn = m;
	}

	gcc_assert (mn == occ->min + depth - occ->depth);

	return mn;
	}

	/* Records the path represented by a tree containing OCC. */

	static void
	record_path_before (struct et_occ *occ)
	{
	while (occ->parent)
	occ = occ->parent;

	len = 0;
	record_path_before_1 (occ, 0);
	fprintf (stderr, "\n");
	}

	/* Checks whether the path represented by OCC, with depth incremented by DEPTH,
	was not changed since the last recording. */

	static int
	check_path_after_1 (struct et_occ *occ, int depth)
	{
	int mn, m;

	depth += occ->depth;
	mn = depth;

	if (occ->next)
	{
	m = check_path_after_1 (occ->next, depth);
	if (m < mn)
	mn = m;
	}

	len--;
	gcc_assert (depths[len] == depth && datas[len] == occ->of);

	if (occ->prev)
	{
	m = check_path_after_1 (occ->prev, depth);
	if (m < mn)
	mn = m;
	}

	gcc_assert (mn == occ->min + depth - occ->depth);

	return mn;
	}

	/* Checks whether the path represented by a tree containing OCC was
	not changed since the last recording. */

	static void
	check_path_after (struct et_occ *occ)
	{
	while (occ->parent)
	occ = occ->parent;

	check_path_after_1 (occ, 0);
	gcc_assert (!len);
	}

	#endif

	/* Splay the occurrence OCC to the root of the tree. */

	static void
	et_splay (struct et_occ *occ)
	{
	struct et_occ f, gf, *ggf;
	int occ_depth, f_depth, gf_depth;

	#ifdef DEBUG_ET
	record_path_before (occ);
	et_check_tree_sanity (occ);
	#endif

	while (occ->parent)
	{
	occ_depth = occ->depth;

	f = occ->parent;
	f_depth = f->depth;

	gf = f->parent;

	if (!gf)
	{
	set_depth_add (occ, f_depth);
	occ->min_occ = f->min_occ;
	occ->min = f->min;

	if (f->prev == occ)
	{
	/* zig */
	set_prev (f, occ->next);
	set_next (occ, f);
	set_depth_add (f->prev, occ_depth);
	}
	else
	{
	/* zag */
	set_next (f, occ->prev);
	set_prev (occ, f);
	set_depth_add (f->next, occ_depth);
	}
	set_depth (f, -occ_depth);
	occ->parent = NULL;

	et_recomp_min (f);
	#ifdef DEBUG_ET
	et_check_tree_sanity (occ);
	check_path_after (occ);
	#endif
	return;
	}

	gf_depth = gf->depth;

	set_depth_add (occ, f_depth + gf_depth);
	occ->min_occ = gf->min_occ;
	occ->min = gf->min;

	ggf = gf->parent;

	if (gf->prev == f)
	{
	if (f->prev == occ)
	{
	/* zig zig */
	set_prev (gf, f->next);
	set_prev (f, occ->next);
	set_next (occ, f);
	set_next (f, gf);

	set_depth (f, -occ_depth);
	set_depth_add (f->prev, occ_depth);
	set_depth (gf, -f_depth);
	set_depth_add (gf->prev, f_depth);
	}
	else
	{
	/* zag zig */
	set_prev (gf, occ->next);
	set_next (f, occ->prev);
	set_prev (occ, f);
	set_next (occ, gf);

	set_depth (f, -occ_depth);
	set_depth_add (f->next, occ_depth);
	set_depth (gf, -occ_depth - f_depth);
	set_depth_add (gf->prev, occ_depth + f_depth);
	}
	}
	else
	{
	if (f->prev == occ)
	{
	/* zig zag */
	set_next (gf, occ->prev);
	set_prev (f, occ->next);
	set_prev (occ, gf);
	set_next (occ, f);

	set_depth (f, -occ_depth);
	set_depth_add (f->prev, occ_depth);
	set_depth (gf, -occ_depth - f_depth);
	set_depth_add (gf->next, occ_depth + f_depth);
	}
	else
	{
	/* zag zag */
	set_next (gf, f->prev);
	set_next (f, occ->prev);
	set_prev (occ, f);
	set_prev (f, gf);

	set_depth (f, -occ_depth);
	set_depth_add (f->next, occ_depth);
	set_depth (gf, -f_depth);
	set_depth_add (gf->next, f_depth);
	}
	}

	occ->parent = ggf;
	if (ggf)
	{
	if (ggf->prev == gf)
	ggf->prev = occ;
	else
	ggf->next = occ;
	}

	et_recomp_min (gf);
	et_recomp_min (f);
	#ifdef DEBUG_ET
	et_check_tree_sanity (occ);
	#endif
	}

	#ifdef DEBUG_ET
	et_check_sanity (occ);
	check_path_after (occ);
	#endif
	}

	/* Create a new et tree occurrence of NODE. */

	static struct et_occ *
	et_new_occ (struct et_node *node)
	{
	struct et_occ *nw;

	if (!et_occurrences)
	et_occurrences = create_alloc_pool ("et_occ pool", sizeof (struct et_occ), 300);
	nw = (struct et_occ *) pool_alloc (et_occurrences);

	nw->of = node;
	nw->parent = NULL;
	nw->prev = NULL;
	nw->next = NULL;

	nw->depth = 0;
	nw->min_occ = nw;
	nw->min = 0;

	return nw;
	}

	/* Create a new et tree containing DATA. */

	struct et_node *
	et_new_tree (void *data)
	{
	struct et_node *nw;

	if (!et_nodes)
	et_nodes = create_alloc_pool ("et_node pool", sizeof (struct et_node), 300);
	nw = (struct et_node *) pool_alloc (et_nodes);

	nw->data = data;
	nw->father = NULL;
	nw->left = NULL;
	nw->right = NULL;
	nw->son = NULL;

	nw->rightmost_occ = et_new_occ (nw);
	nw->parent_occ = NULL;

	return nw;
	}

	/* Releases et tree T. */

	void
	et_free_tree (struct et_node *t)
	{
	while (t->son)
	et_split (t->son);

	if (t->father)
	et_split (t);

	pool_free (et_occurrences, t->rightmost_occ);
	pool_free (et_nodes, t);
	}

	/* Releases et tree T without maintaining other nodes. */

	void
	et_free_tree_force (struct et_node *t)
	{
	pool_free (et_occurrences, t->rightmost_occ);
	if (t->parent_occ)
	pool_free (et_occurrences, t->parent_occ);
	pool_free (et_nodes, t);
	}

	/* Release the alloc pools, if they are empty. */

	void
	et_free_pools (void)
	{
	free_alloc_pool_if_empty (&et_occurrences);
	free_alloc_pool_if_empty (&et_nodes);
	}

	/* Sets father of et tree T to FATHER. */

	void
	et_set_father (struct et_node t, struct et_node father)
	{
	struct et_node left, right;
	struct et_occ rmost, left_part, new_f_occ, p;

	/* Update the path represented in the splay tree. */
	new_f_occ = et_new_occ (father);

	rmost = father->rightmost_occ;
	et_splay (rmost);

	left_part = rmost->prev;

	p = t->rightmost_occ;
	et_splay (p);

	set_prev (new_f_occ, left_part);
	set_next (new_f_occ, p);

	p->depth++;
	p->min++;
	et_recomp_min (new_f_occ);

	set_prev (rmost, new_f_occ);

	if (new_f_occ->min + rmost->depth < rmost->min)
	{
	rmost->min = new_f_occ->min + rmost->depth;
	rmost->min_occ = new_f_occ->min_occ;
	}

	t->parent_occ = new_f_occ;

	/* Update the tree. */
	t->father = father;
	right = father->son;
	if (right)
	left = right->left;
	else
	left = right = t;

	left->right = t;
	right->left = t;
	t->left = left;
	t->right = right;

	father->son = t;

	#ifdef DEBUG_ET
	et_check_tree_sanity (rmost);
	record_path_before (rmost);
	#endif
	}

	/* Splits the edge from T to its father. */

	void
	et_split (struct et_node *t)
	{
	struct et_node *father = t->father;
	struct et_occ r, l, rmost, p_occ;

	/* Update the path represented by the splay tree. */
	rmost = t->rightmost_occ;
	et_splay (rmost);

	for (r = rmost->next; r->prev; r = r->prev)
	continue;
	et_splay (r);

	r->prev->parent = NULL;
	p_occ = t->parent_occ;
	et_splay (p_occ);
	t->parent_occ = NULL;

	l = p_occ->prev;
	p_occ->next->parent = NULL;

	set_prev (r, l);

	et_recomp_min (r);

	et_splay (rmost);
	rmost->depth = 0;
	rmost->min = 0;

	pool_free (et_occurrences, p_occ);

	/* Update the tree. */
	if (father->son == t)
	father->son = t->right;
	if (father->son == t)
	father->son = NULL;
	else
	{
	t->left->right = t->right;
	t->right->left = t->left;
	}
	t->left = t->right = NULL;
	t->father = NULL;

	#ifdef DEBUG_ET
	et_check_tree_sanity (rmost);
	record_path_before (rmost);

	et_check_tree_sanity (r);
	record_path_before (r);
	#endif
	}

	/* Finds the nearest common ancestor of the nodes N1 and N2. */

	struct et_node *
	et_nca (struct et_node n1, struct et_node n2)
	{
	struct et_occ o1 = n1->rightmost_occ, o2 = n2->rightmost_occ, *om;
	struct et_occ l, r, *ret;
	int mn;

	if (n1 == n2)
	return n1;

	et_splay (o1);
	l = o1->prev;
	r = o1->next;
	if (l)
	l->parent = NULL;
	if (r)
	r->parent = NULL;
	et_splay (o2);

	if (l == o2 \|\| (l && l->parent != NULL))
	{
	ret = o2->next;

	set_prev (o1, o2);
	if (r)
	r->parent = o1;
	}
	else if (r == o2 \|\| (r && r->parent != NULL))
	{
	ret = o2->prev;

	set_next (o1, o2);
	if (l)
	l->parent = o1;
	}
	else
	{
	/* O1 and O2 are in different components of the forest. */
	if (l)
	l->parent = o1;
	if (r)
	r->parent = o1;
	return NULL;
	}

	if (0 < o2->depth)
	{
	om = o1;
	mn = o1->depth;
	}
	else
	{
	om = o2;
	mn = o2->depth + o1->depth;
	}

	#ifdef DEBUG_ET
	et_check_tree_sanity (o2);
	#endif

	if (ret && ret->min + o1->depth + o2->depth < mn)
	return ret->min_occ->of;
	else
	return om->of;
	}

	/* Checks whether the node UP is an ancestor of the node DOWN. */

	bool
	et_below (struct et_node down, struct et_node up)
	{
	struct et_occ u = up->rightmost_occ, d = down->rightmost_occ;
	struct et_occ l, r;

	if (up == down)
	return true;

	et_splay (u);
	l = u->prev;
	r = u->next;

	if (!l)
	return false;

	l->parent = NULL;

	if (r)
	r->parent = NULL;

	et_splay (d);

	if (l == d \|\| l->parent != NULL)
	{
	if (r)
	r->parent = u;
	set_prev (u, d);
	#ifdef DEBUG_ET
	et_check_tree_sanity (u);
	#endif
	}
	else
	{
	l->parent = u;

	/* In case O1 and O2 are in two different trees, we must just restore the
	original state. */
	if (r && r->parent != NULL)
	set_next (u, d);
	else
	set_next (u, r);

	#ifdef DEBUG_ET
	et_check_tree_sanity (u);
	#endif
	return false;
	}

	if (0 >= d->depth)
	return false;

	return !d->next \|\| d->next->min + d->depth >= 0;
	}

	/* Returns the root of the tree that contains NODE. */

	struct et_node *
	et_root (struct et_node *node)
	{
	struct et_occ occ = node->rightmost_occ, r;

	/* The root of the tree corresponds to the rightmost occurrence in the
	represented path. */
	et_splay (occ);
	for (r = occ; r->next; r = r->next)
	continue;
	et_splay (r);

	return r->of;
	}