Files @ r2008:5e435ad4c8e4
Branch filter:

Location: cpp/openttd-patchpack/source/aystar.c

hackykid
(svn r2516) - Feature: [pbs] Implement path-based-signalling. This allows multiple trains within the same signal block, provided their paths dont intersect. For this the block must have all exit and entry signals be pbs signals. Place these by ctrl-clicking 4 times on a normal signal.
- Feature: [pbs] Implement autoplacement of pbs blocks, when a block has an entry and an exit pbs signal, covert the entire block to pbs. Can be turned off in the patch settings.
- Feature: [pbs] Allow showing of reserved status by making the tracks darker, when the pbs debug level is at least 1.
/*
 * This file has the core function for AyStar
 *  AyStar is a fast pathfinding routine and is used for things like
 *  AI_pathfinding and Train_pathfinding.
 *  For more information about AyStar (A* Algorithm), you can look at
 *    http://en.wikipedia.org/wiki/A-star_search_algorithm
 */

/*
 * Friendly reminder:
 *  Call (AyStar).free() when you are done with Aystar. It reserves a lot of memory
 *  And when not free'd, it can cause system-crashes.
 * Also remember that when you stop an algorithm before it is finished, your
 * should call clear() yourself!
 */

#include "stdafx.h"
#include "openttd.h"
#include "aystar.h"
// This looks in the Hash if a node exists in ClosedList
//  If so, it returns the PathNode, else NULL
static PathNode *AyStarMain_ClosedList_IsInList(AyStar *aystar, AyStarNode *node)
{
	return (PathNode*)Hash_Get(&aystar->ClosedListHash, node->tile, node->direction);
}

// This adds a node to the ClosedList
//  It makes a copy of the data
static void AyStarMain_ClosedList_Add(AyStar *aystar, PathNode *node)
{
	// Add a node to the ClosedList
	PathNode *new_node = malloc(sizeof(PathNode));
	*new_node = *node;
	Hash_Set(&aystar->ClosedListHash, node->node.tile, node->node.direction, new_node);
}

// Checks if a node is in the OpenList
//   If so, it returns the OpenListNode, else NULL
static OpenListNode *AyStarMain_OpenList_IsInList(AyStar *aystar, AyStarNode *node)
{
	return (OpenListNode*)Hash_Get(&aystar->OpenListHash, node->tile, node->direction);
}

// Gets the best node from OpenList
//  returns the best node, or NULL of none is found
// Also it deletes the node from the OpenList
static OpenListNode *AyStarMain_OpenList_Pop(AyStar *aystar)
{
	// Return the item the Queue returns.. the best next OpenList item.
	OpenListNode* res = (OpenListNode*)aystar->OpenListQueue.pop(&aystar->OpenListQueue);
	if (res != NULL)
		Hash_Delete(&aystar->OpenListHash, res->path.node.tile, res->path.node.direction);

	return res;
}

// Adds a node to the OpenList
//  It makes a copy of node, and puts the pointer of parent in the struct
static void AyStarMain_OpenList_Add(AyStar *aystar, PathNode *parent, AyStarNode *node, int f, int g)
{
	// Add a new Node to the OpenList
	OpenListNode* new_node = malloc(sizeof(OpenListNode));
	new_node->g = g;
	new_node->path.parent = parent;
	new_node->path.node = *node;
	Hash_Set(&aystar->OpenListHash, node->tile, node->direction, new_node);

	// Add it to the queue
	aystar->OpenListQueue.push(&aystar->OpenListQueue, new_node, f);
}

/*
 * Checks one tile and calculate his f-value
 *  return values:
 *	AYSTAR_DONE : indicates we are done
 */
int AyStarMain_CheckTile(AyStar *aystar, AyStarNode *current, OpenListNode *parent) {
	int new_f, new_g, new_h;
	PathNode *closedlist_parent;
	OpenListNode *check;

	// Check the new node against the ClosedList
	if (AyStarMain_ClosedList_IsInList(aystar, current) != NULL) return AYSTAR_DONE;

	// Calculate the G-value for this node
	new_g = aystar->CalculateG(aystar, current, parent);
	// If the value was INVALID_NODE, we don't do anything with this node
	if (new_g == AYSTAR_INVALID_NODE) return AYSTAR_DONE;

	// There should not be given any other error-code..
	assert(new_g >= 0);
	// Add the parent g-value to the new g-value
	new_g += parent->g;
	if (aystar->max_path_cost != 0 && (uint)new_g > aystar->max_path_cost) return AYSTAR_DONE;

	// Calculate the h-value
	new_h = aystar->CalculateH(aystar, current, parent);
	// There should not be given any error-code..
	assert(new_h >= 0);

	// The f-value if g + h
	new_f = new_g + new_h;

	// Get the pointer to the parent in the ClosedList (the currentone is to a copy of the one in the OpenList)
	closedlist_parent = AyStarMain_ClosedList_IsInList(aystar, &parent->path.node);

	// Check if this item is already in the OpenList
	if ((check = AyStarMain_OpenList_IsInList(aystar, current)) != NULL) {
		uint i;
		// Yes, check if this g value is lower..
		if (new_g > check->g) return AYSTAR_DONE;
		aystar->OpenListQueue.del(&aystar->OpenListQueue, check, 0);
		// It is lower, so change it to this item
		check->g = new_g;
		check->path.parent = closedlist_parent;
		/* Copy user data, will probably have changed */
		for (i=0;i<lengthof(current->user_data);i++)
			check->path.node.user_data[i] = current->user_data[i];
		// Readd him in the OpenListQueue
		aystar->OpenListQueue.push(&aystar->OpenListQueue, check, new_f);
	} else {
		// A new node, add him to the OpenList
		AyStarMain_OpenList_Add(aystar, closedlist_parent, current, new_f, new_g);
	}

	return AYSTAR_DONE;
}

/*
 * This function is the core of AyStar. It handles one item and checks
 *  his neighbour items. If they are valid, they are added to be checked too.
 *  return values:
 *	AYSTAR_EMPTY_OPENLIST : indicates all items are tested, and no path
 *	has been found.
 *	AYSTAR_LIMIT_REACHED : Indicates that the max_nodes limit has been
 *	reached.
 *	AYSTAR_FOUND_END_NODE : indicates we found the end. Path_found now is true, and in path is the path found.
 *	AYSTAR_STILL_BUSY : indicates we have done this tile, did not found the path yet, and have items left to try.
 */
int AyStarMain_Loop(AyStar *aystar) {
	int i, r;

	// Get the best node from OpenList
	OpenListNode *current = AyStarMain_OpenList_Pop(aystar);
	// If empty, drop an error
	if (current == NULL) return AYSTAR_EMPTY_OPENLIST;

	// Check for end node and if found, return that code
	if (aystar->EndNodeCheck(aystar, current) == AYSTAR_FOUND_END_NODE) {
		if (aystar->FoundEndNode != NULL)
			aystar->FoundEndNode(aystar, current);
		free(current);
		return AYSTAR_FOUND_END_NODE;
	}

	// Add the node to the ClosedList
	AyStarMain_ClosedList_Add(aystar, &current->path);

	// Load the neighbours
	aystar->GetNeighbours(aystar, current);

	// Go through all neighbours
	for (i=0;i<aystar->num_neighbours;i++) {
		// Check and add them to the OpenList if needed
		r = aystar->checktile(aystar, &aystar->neighbours[i], current);
	}

	// Free the node
	free(current);

	if (aystar->max_search_nodes != 0 && Hash_Size(&aystar->ClosedListHash) >= aystar->max_search_nodes)
		/* We've expanded enough nodes */
		return AYSTAR_LIMIT_REACHED;
	else
		// Return that we are still busy
		return AYSTAR_STILL_BUSY;
}

/*
 * This function frees the memory it allocated
 */
void AyStarMain_Free(AyStar *aystar) {
	aystar->OpenListQueue.free(&aystar->OpenListQueue, false);
	/* 2nd argument above is false, below is true, to free the values only
	 * once */
	delete_Hash(&aystar->OpenListHash, true);
	delete_Hash(&aystar->ClosedListHash, true);
#ifdef AYSTAR_DEBUG
	printf("[AyStar] Memory free'd\n");
#endif
}

/*
 * This function make the memory go back to zero
 *  This function should be called when you are using the same instance again.
 */
void AyStarMain_Clear(AyStar *aystar) {
	// Clean the Queue, but not the elements within. That will be done by
	// the hash.
	aystar->OpenListQueue.clear(&aystar->OpenListQueue, false);
	// Clean the hashes
	clear_Hash(&aystar->OpenListHash, true);
	clear_Hash(&aystar->ClosedListHash, true);

#ifdef AYSTAR_DEBUG
	printf("[AyStar] Cleared AyStar\n");
#endif
}

/*
 * This is the function you call to run AyStar.
 *  return values:
 *	AYSTAR_FOUND_END_NODE : indicates we found an end node.
 *	AYSTAR_NO_PATH : indicates that there was no path found.
 *	AYSTAR_STILL_BUSY : indicates we have done some checked, that we did not found the path yet, and that we still have items left to try.
 * When the algorithm is done (when the return value is not AYSTAR_STILL_BUSY)
 * aystar->clear() is called. Note that when you stop the algorithm halfway,
 * you should still call clear() yourself!
 */
int AyStarMain_Main(AyStar *aystar) {
	int r, i = 0;
	// Loop through the OpenList
	//  Quit if result is no AYSTAR_STILL_BUSY or is more than loops_per_tick
	while ((r = aystar->loop(aystar)) == AYSTAR_STILL_BUSY && (aystar->loops_per_tick == 0 || ++i < aystar->loops_per_tick)) { }
#ifdef AYSTAR_DEBUG
	if (r == AYSTAR_FOUND_END_NODE)
		printf("[AyStar] Found path!\n");
	else if (r == AYSTAR_EMPTY_OPENLIST)
		printf("[AyStar] OpenList run dry, no path found\n");
	else if (r == AYSTAR_LIMIT_REACHED)
		printf("[AyStar] Exceeded search_nodes, no path found\n");
#endif

	if (aystar->BeforeExit != NULL)
		aystar->BeforeExit(aystar);

	if (r != AYSTAR_STILL_BUSY)
		/* We're done, clean up */
		aystar->clear(aystar);

	// Check result-value
	if (r == AYSTAR_FOUND_END_NODE) return AYSTAR_FOUND_END_NODE;
	// Check if we have some left in the OpenList
	if (r == AYSTAR_EMPTY_OPENLIST || r == AYSTAR_LIMIT_REACHED) return AYSTAR_NO_PATH;

	// Return we are still busy
	return AYSTAR_STILL_BUSY;
}

/*
 * Adds a node from where to start an algorithm. Multiple nodes can be added
 * if wanted. You should make sure that clear() is called before adding nodes
 * if the AyStar has been used before (though the normal main loop calls
 * clear() automatically when the algorithm finishes
 * g is the cost for starting with this node.
 */
void AyStarMain_AddStartNode(AyStar *aystar, AyStarNode *start_node, uint g) {
#ifdef AYSTAR_DEBUG
	printf("[AyStar] Starting A* Algorithm from node (%d, %d, %d)\n",
		TileX(start_node->tile), TileY(start_node->tile), start_node->direction);
#endif
	AyStarMain_OpenList_Add(aystar, NULL, start_node, 0, g);
}

void init_AyStar(AyStar* aystar, Hash_HashProc hash, uint num_buckets) {
	// Allocated the Hash for the OpenList and ClosedList
	init_Hash(&aystar->OpenListHash, hash, num_buckets);
	init_Hash(&aystar->ClosedListHash, hash, num_buckets);

	// Set up our sorting queue
	//  BinaryHeap allocates a block of 1024 nodes
	//  When thatone gets full it reserves an otherone, till this number
	//  That is why it can stay this high
	init_BinaryHeap(&aystar->OpenListQueue, 102400);

	aystar->addstart	= AyStarMain_AddStartNode;
	aystar->main		= AyStarMain_Main;
	aystar->loop		= AyStarMain_Loop;
	aystar->free		= AyStarMain_Free;
	aystar->clear		= AyStarMain_Clear;
	aystar->checktile	= AyStarMain_CheckTile;
}