[thirdparty/gcc.git] / gcc / shortest-paths.h

/* Template class for Dijkstra's algorithm on directed graphs.
   Copyright (C) 2019-2024 Free Software Foundation, Inc.
   Contributed by David Malcolm <dmalcolm@redhat.com>.

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/>.  */

#ifndef GCC_SHORTEST_PATHS_H
#define GCC_SHORTEST_PATHS_H

#include "timevar.h"

enum shortest_path_sense
{
  /* Find the shortest path from the given origin node to each
     node in the graph.  */
  SPS_FROM_GIVEN_ORIGIN,

  /* Find the shortest path from each node in the graph to the
     given target node.  */
  SPS_TO_GIVEN_TARGET
};

/* A record of the shortest path for each node relative to a special
   "given node", either:
   SPS_FROM_GIVEN_ORIGIN:
     from the given origin node to each node in a graph, or
   SPS_TO_GIVEN_TARGET:
     from each node in a graph to the given target node.

   The constructor runs Dijkstra's algorithm, and the results are
   stored in this class.  */

template <typename GraphTraits, typename Path_t>
class shortest_paths
{
public:
  typedef typename GraphTraits::graph_t graph_t;
  typedef typename GraphTraits::node_t node_t;
  typedef typename GraphTraits::edge_t edge_t;
  typedef Path_t path_t;

  shortest_paths (const graph_t &graph, const node_t *given_node,
		  enum shortest_path_sense sense);

  path_t get_shortest_path (const node_t *other_node) const;
  int get_shortest_distance (const node_t *other_node) const;

private:
  const graph_t &m_graph;

  enum shortest_path_sense m_sense;

  /* For each node (by index), the minimal distance between that node
     and the given node (with direction depending on m_sense).  */
  auto_vec<int> m_dist;

  /* For each node (by index):
     SPS_FROM_GIVEN_ORIGIN:
       the previous edge in the shortest path from the origin,
     SPS_TO_GIVEN_TARGET:
       the next edge in the shortest path to the target.  */
  auto_vec<const edge_t *> m_best_edge;
};

/* shortest_paths's constructor.

   Use Dijkstra's algorithm relative to GIVEN_NODE to populate m_dist and
   m_best_edge with enough information to be able to generate Path_t instances
   to give the shortest path...
   SPS_FROM_GIVEN_ORIGIN: to each node in a graph from the origin node, or
   SPS_TO_GIVEN_TARGET: from each node in a graph to the target node.  */

template <typename GraphTraits, typename Path_t>
inline
shortest_paths<GraphTraits, Path_t>::
shortest_paths (const graph_t &graph,
		const node_t *given_node,
		enum shortest_path_sense sense)
: m_graph (graph),
  m_sense (sense),
  m_dist (graph.m_nodes.length ()),
  m_best_edge (graph.m_nodes.length ())
{
  auto_timevar tv (TV_ANALYZER_SHORTEST_PATHS);

  auto_vec<int> queue (graph.m_nodes.length ());

  for (unsigned i = 0; i < graph.m_nodes.length (); i++)
    {
      m_dist.quick_push (INT_MAX);
      m_best_edge.quick_push (NULL);
      queue.quick_push (i);
    }
  m_dist[given_node->m_index] = 0;

  while (queue.length () > 0)
    {
      /* Get minimal distance in queue.
	 FIXME: this is O(N^2); replace with a priority queue.  */
      int idx_with_min_dist = -1;
      int idx_in_queue_with_min_dist = -1;
      int min_dist = INT_MAX;
      for (unsigned i = 0; i < queue.length (); i++)
	{
	  int idx = queue[i];
	  if (m_dist[queue[i]] < min_dist)
	    {
	      min_dist = m_dist[idx];
	      idx_with_min_dist = idx;
	      idx_in_queue_with_min_dist = i;
	    }
	}
      if (idx_with_min_dist == -1)
	break;
      gcc_assert (idx_in_queue_with_min_dist != -1);

      // FIXME: this is confusing: there are two indices here

      queue.unordered_remove (idx_in_queue_with_min_dist);

      node_t *n
	= static_cast <node_t *> (m_graph.m_nodes[idx_with_min_dist]);

      if (m_sense == SPS_FROM_GIVEN_ORIGIN)
	{
	  int i;
	  edge_t *succ;
	  FOR_EACH_VEC_ELT (n->m_succs, i, succ)
	    {
	      // TODO: only for dest still in queue
	      node_t *dest = succ->m_dest;
	      int alt = m_dist[n->m_index] + 1;
	      if (alt < m_dist[dest->m_index])
		{
		  m_dist[dest->m_index] = alt;
		  m_best_edge[dest->m_index] = succ;
		}
	    }
	}
      else
	{
	  int i;
	  edge_t *pred;
	  FOR_EACH_VEC_ELT (n->m_preds, i, pred)
	    {
	      // TODO: only for dest still in queue
	      node_t *src = pred->m_src;
	      int alt = m_dist[n->m_index] + 1;
	      if (alt < m_dist[src->m_index])
		{
		  m_dist[src->m_index] = alt;
		  m_best_edge[src->m_index] = pred;
		}
	    }
	}
   }
}

/* Generate an Path_t instance giving the shortest path between OTHER_NODE
   and the given node.

   SPS_FROM_GIVEN_ORIGIN: shortest path from given origin node to OTHER_NODE
   SPS_TO_GIVEN_TARGET: shortest path from OTHER_NODE to given target node.

   If no such path exists, return an empty path.  */

template <typename GraphTraits, typename Path_t>
inline Path_t
shortest_paths<GraphTraits, Path_t>::
get_shortest_path (const node_t *other_node) const
{
  Path_t result;

  while (m_best_edge[other_node->m_index])
    {
      result.m_edges.safe_push (m_best_edge[other_node->m_index]);
      if (m_sense == SPS_FROM_GIVEN_ORIGIN)
	other_node = m_best_edge[other_node->m_index]->m_src;
      else
	other_node = m_best_edge[other_node->m_index]->m_dest;
    }

  if (m_sense == SPS_FROM_GIVEN_ORIGIN)
    result.m_edges.reverse ();

  return result;
}

/* Get the shortest distance...
   SPS_FROM_GIVEN_ORIGIN: ...from given origin node to OTHER_NODE
   SPS_TO_GIVEN_TARGET: ...from OTHER_NODE to given target node.  */

template <typename GraphTraits, typename Path_t>
inline int
shortest_paths<GraphTraits, Path_t>::
get_shortest_distance (const node_t *other_node) const
{
  return m_dist[other_node->m_index];
}

#endif /* GCC_SHORTEST_PATHS_H */
Commit	Line	Data
757bf1df	1	/* Template class for Dijkstra's algorithm on directed graphs.
a945c346	2	Copyright (C) 2019-2024 Free Software Foundation, Inc.
757bf1df DM	3	Contributed by David Malcolm <dmalcolm@redhat.com>.
	4
	5	This file is part of GCC.
	6
	7	GCC is free software; you can redistribute it and/or modify it
	8	under the terms of the GNU General Public License as published by
	9	the Free Software Foundation; either version 3, or (at your option)
	10	any later version.
	11
	12	GCC is distributed in the hope that it will be useful, but
	13	WITHOUT ANY WARRANTY; without even the implied warranty of
	14	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	15	General Public License for more details.
	16
	17	You should have received a copy of the GNU General Public License
	18	along with GCC; see the file COPYING3. If not see
	19	<http://www.gnu.org/licenses/>. */
	20
	21	#ifndef GCC_SHORTEST_PATHS_H
	22	#define GCC_SHORTEST_PATHS_H
	23
	24	#include "timevar.h"
	25
5e33e5b0 DM	26	enum shortest_path_sense
	27	{
	28	/* Find the shortest path from the given origin node to each
	29	node in the graph. */
	30	SPS_FROM_GIVEN_ORIGIN,
	31
	32	/* Find the shortest path from each node in the graph to the
	33	given target node. */
	34	SPS_TO_GIVEN_TARGET
	35	};
	36
	37	/* A record of the shortest path for each node relative to a special
	38	"given node", either:
	39	SPS_FROM_GIVEN_ORIGIN:
	40	from the given origin node to each node in a graph, or
	41	SPS_TO_GIVEN_TARGET:
	42	from each node in a graph to the given target node.
	43
757bf1df DM	44	The constructor runs Dijkstra's algorithm, and the results are
	45	stored in this class. */
	46
	47	template <typename GraphTraits, typename Path_t>
	48	class shortest_paths
	49	{
	50	public:
	51	typedef typename GraphTraits::graph_t graph_t;
	52	typedef typename GraphTraits::node_t node_t;
	53	typedef typename GraphTraits::edge_t edge_t;
	54	typedef Path_t path_t;
	55
5e33e5b0 DM	56	shortest_paths (const graph_t &graph, const node_t *given_node,
5e33e5b0 DM	57	enum shortest_path_sense sense);
757bf1df	58
5e33e5b0	59	path_t get_shortest_path (const node_t *other_node) const;
3857edb5	60	int get_shortest_distance (const node_t *other_node) const;
757bf1df DM	61
	62	private:
	63	const graph_t &m_graph;
	64
5e33e5b0 DM	65	enum shortest_path_sense m_sense;
	66
	67	/* For each node (by index), the minimal distance between that node
	68	and the given node (with direction depending on m_sense). */
757bf1df DM	69	auto_vec<int> m_dist;
757bf1df DM	70
5e33e5b0 DM	71	/* For each node (by index):
	72	SPS_FROM_GIVEN_ORIGIN:
	73	the previous edge in the shortest path from the origin,
	74	SPS_TO_GIVEN_TARGET:
	75	the next edge in the shortest path to the target. */
	76	auto_vec<const edge_t *> m_best_edge;
757bf1df DM	77	};
	78
	79	/* shortest_paths's constructor.
	80
5e33e5b0 DM	81	Use Dijkstra's algorithm relative to GIVEN_NODE to populate m_dist and
	82	m_best_edge with enough information to be able to generate Path_t instances
	83	to give the shortest path...
	84	SPS_FROM_GIVEN_ORIGIN: to each node in a graph from the origin node, or
	85	SPS_TO_GIVEN_TARGET: from each node in a graph to the target node. */
757bf1df DM	86
	87	template <typename GraphTraits, typename Path_t>
	88	inline
5e33e5b0 DM	89	shortest_paths<GraphTraits, Path_t>::
	90	shortest_paths (const graph_t &graph,
	91	const node_t *given_node,
	92	enum shortest_path_sense sense)
757bf1df	93	: m_graph (graph),
5e33e5b0	94	m_sense (sense),
757bf1df	95	m_dist (graph.m_nodes.length ()),
5e33e5b0	96	m_best_edge (graph.m_nodes.length ())
757bf1df DM	97	{
	98	auto_timevar tv (TV_ANALYZER_SHORTEST_PATHS);
	99
	100	auto_vec<int> queue (graph.m_nodes.length ());
	101
	102	for (unsigned i = 0; i < graph.m_nodes.length (); i++)
	103	{
	104	m_dist.quick_push (INT_MAX);
5e33e5b0	105	m_best_edge.quick_push (NULL);
757bf1df DM	106	queue.quick_push (i);
757bf1df DM	107	}
5e33e5b0	108	m_dist[given_node->m_index] = 0;
757bf1df DM	109
	110	while (queue.length () > 0)
	111	{
	112	/* Get minimal distance in queue.
	113	FIXME: this is O(N^2); replace with a priority queue. */
	114	int idx_with_min_dist = -1;
	115	int idx_in_queue_with_min_dist = -1;
	116	int min_dist = INT_MAX;
	117	for (unsigned i = 0; i < queue.length (); i++)
	118	{
	119	int idx = queue[i];
	120	if (m_dist[queue[i]] < min_dist)
	121	{
	122	min_dist = m_dist[idx];
	123	idx_with_min_dist = idx;
	124	idx_in_queue_with_min_dist = i;
	125	}
	126	}
3f958348 DM	127	if (idx_with_min_dist == -1)
3f958348 DM	128	break;
757bf1df DM	129	gcc_assert (idx_in_queue_with_min_dist != -1);
	130
	131	// FIXME: this is confusing: there are two indices here
	132
	133	queue.unordered_remove (idx_in_queue_with_min_dist);
	134
	135	node_t *n
	136	= static_cast <node_t *> (m_graph.m_nodes[idx_with_min_dist]);
	137
5e33e5b0	138	if (m_sense == SPS_FROM_GIVEN_ORIGIN)
757bf1df	139	{
5e33e5b0 DM	140	int i;
	141	edge_t *succ;
	142	FOR_EACH_VEC_ELT (n->m_succs, i, succ)
757bf1df	143	{
5e33e5b0 DM	144	// TODO: only for dest still in queue
	145	node_t *dest = succ->m_dest;
	146	int alt = m_dist[n->m_index] + 1;
	147	if (alt < m_dist[dest->m_index])
	148	{
	149	m_dist[dest->m_index] = alt;
	150	m_best_edge[dest->m_index] = succ;
	151	}
	152	}
	153	}
	154	else
	155	{
	156	int i;
	157	edge_t *pred;
	158	FOR_EACH_VEC_ELT (n->m_preds, i, pred)
	159	{
	160	// TODO: only for dest still in queue
	161	node_t *src = pred->m_src;
	162	int alt = m_dist[n->m_index] + 1;
	163	if (alt < m_dist[src->m_index])
	164	{
	165	m_dist[src->m_index] = alt;
	166	m_best_edge[src->m_index] = pred;
	167	}
757bf1df DM	168	}
	169	}
	170	}
	171	}
	172
5e33e5b0 DM	173	/* Generate an Path_t instance giving the shortest path between OTHER_NODE
	174	and the given node.
	175
	176	SPS_FROM_GIVEN_ORIGIN: shortest path from given origin node to OTHER_NODE
	177	SPS_TO_GIVEN_TARGET: shortest path from OTHER_NODE to given target node.
	178
3f958348	179	If no such path exists, return an empty path. */
757bf1df DM	180
	181	template <typename GraphTraits, typename Path_t>
	182	inline Path_t
5e33e5b0 DM	183	shortest_paths<GraphTraits, Path_t>::
5e33e5b0 DM	184	get_shortest_path (const node_t *other_node) const
757bf1df DM	185	{
	186	Path_t result;
	187
5e33e5b0	188	while (m_best_edge[other_node->m_index])
757bf1df	189	{
5e33e5b0 DM	190	result.m_edges.safe_push (m_best_edge[other_node->m_index]);
	191	if (m_sense == SPS_FROM_GIVEN_ORIGIN)
	192	other_node = m_best_edge[other_node->m_index]->m_src;
	193	else
	194	other_node = m_best_edge[other_node->m_index]->m_dest;
757bf1df DM	195	}
757bf1df DM	196
5e33e5b0 DM	197	if (m_sense == SPS_FROM_GIVEN_ORIGIN)
5e33e5b0 DM	198	result.m_edges.reverse ();
757bf1df DM	199
	200	return result;
	201	}
	202
3857edb5 DM	203	/* Get the shortest distance...
	204	SPS_FROM_GIVEN_ORIGIN: ...from given origin node to OTHER_NODE
	205	SPS_TO_GIVEN_TARGET: ...from OTHER_NODE to given target node. */
	206
	207	template <typename GraphTraits, typename Path_t>
	208	inline int
	209	shortest_paths<GraphTraits, Path_t>::
	210	get_shortest_distance (const node_t *other_node) const
	211	{
	212	return m_dist[other_node->m_index];
	213	}
	214
757bf1df	215	#endif /* GCC_SHORTEST_PATHS_H */