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https://github.com/JGRennison/OpenTTD-patches.git
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334 lines
11 KiB
C++
334 lines
11 KiB
C++
/* $Id$ */
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#ifndef YAPF_BASE_HPP
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#define YAPF_BASE_HPP
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EXTERN_C_BEGIN
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#include "../debug.h"
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EXTERN_C_END
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#include "fixedsizearray.hpp"
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#include "blob.hpp"
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#include "nodelist.hpp"
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extern int _total_pf_time_us;
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/** CYapfBaseT - A-star type path finder base class.
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Derive your own pathfinder from it. You must provide the following template argument:
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Types - used as collection of local types used in pathfinder
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Requirements for the Types struct:
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----------------------------------
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The following types must be defined in the 'Types' argument:
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- Types::Tpf - your pathfinder derived from CYapfBaseT
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- Types::NodeList - open/closed node list (look at CNodeList_HashTableT)
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NodeList needs to have defined local type Titem - defines the pathfinder node type.
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Node needs to define local type Key - the node key in the collection ()
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For node list you can use template class CNodeList_HashTableT, for which
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you need to declare only your node type. Look at test_yapf.h for an example.
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Requrements to your pathfinder class derived from CYapfBaseT:
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-------------------------------------------------------------
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Your pathfinder derived class needs to implement following methods:
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FORCEINLINE void PfSetStartupNodes()
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FORCEINLINE void PfFollowNode(Node& org)
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FORCEINLINE bool PfCalcCost(Node& n)
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FORCEINLINE bool PfCalcEstimate(Node& n)
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FORCEINLINE bool PfDetectDestination(Node& n)
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For more details about those methods, look at the end of CYapfBaseT
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declaration. There are some examples. For another example look at
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test_yapf.h (part or unittest project).
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*/
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template <class Types>
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class CYapfBaseT {
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public:
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typedef typename Types::Tpf Tpf; ///< the pathfinder class (derived from THIS class)
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typedef typename Types::NodeList NodeList; ///< our node list
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typedef typename NodeList::Titem Node; ///< this will be our node type
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typedef typename Node::Key Key; ///< key to hash tables
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NodeList m_nodes; ///< node list multi-container
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protected:
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Node* m_pBestDestNode; ///< pointer to the destination node found at last round
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Node* m_pBestIntermediateNode; ///< here should be node closest to the destination if path not found
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const YapfSettings *m_settings; ///< current settings (_patches.yapf)
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int m_max_search_nodes; ///< maximum number of nodes we are allowed to visit before we give up
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const Vehicle* m_veh; ///< vehicle that we are trying to drive
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int m_stats_cost_calcs; ///< stats - how many node's costs were calculated
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int m_stats_cache_hits; ///< stats - how many node's costs were reused from cache
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public:
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CPerformanceTimer m_perf_cost; ///< stats - total CPU time of this run
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CPerformanceTimer m_perf_slope_cost; ///< stats - slope calculation CPU time
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CPerformanceTimer m_perf_ts_cost; ///< stats - GetTrackStatus() CPU time
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CPerformanceTimer m_perf_other_cost; ///< stats - other CPU time
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public:
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int m_num_steps; ///< this is there for debugging purposes (hope it doesn't hurt)
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public:
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/// default constructor
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FORCEINLINE CYapfBaseT()
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: m_pBestDestNode(NULL)
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, m_pBestIntermediateNode(NULL)
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#if defined(UNITTEST)
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, m_settings(NULL)
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, m_max_search_nodes(100000)
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#else
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, m_settings(&_patches.yapf)
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, m_max_search_nodes(PfGetSettings().max_search_nodes)
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#endif
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, m_veh(NULL)
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, m_stats_cost_calcs(0)
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, m_stats_cache_hits(0)
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, m_num_steps(0)
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{
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}
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/// default destructor
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~CYapfBaseT() {}
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protected:
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/// to access inherited path finder
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FORCEINLINE Tpf& Yapf() {return *static_cast<Tpf*>(this);}
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public:
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/// return current settings (can be custom - player based - but later)
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FORCEINLINE const YapfSettings& PfGetSettings() const
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{
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return *m_settings;
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}
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/** Main pathfinder routine:
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- set startup node(s)
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- main loop that stops if:
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- the destination was found
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- or the open list is empty (no route to destination).
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- or the maximum amount of loops reached - m_max_search_nodes (default = 10000)
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@return true if the path was found */
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inline bool FindPath(const Vehicle* v)
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{
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m_veh = v;
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CPerformanceTimer perf;
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perf.Start();
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Yapf().PfSetStartupNodes();
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while (true) {
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m_num_steps++;
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Node& n = m_nodes.GetBestOpenNode();
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if (&n == NULL)
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break;
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// if the best open node was worse than the best path found, we can finish
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if (m_pBestDestNode != NULL && m_pBestDestNode->GetCost() < n.GetCostEstimate())
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break;
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Yapf().PfFollowNode(n);
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if (m_max_search_nodes == 0 || m_nodes.ClosedCount() < m_max_search_nodes) {
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m_nodes.PopOpenNode(n.GetKey());
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m_nodes.InsertClosedNode(n);
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} else {
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m_pBestDestNode = m_pBestIntermediateNode;
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break;
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}
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}
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bool bDestFound = (m_pBestDestNode != NULL);
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int16 veh_idx = (m_veh != NULL) ? m_veh->unitnumber : 0;
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// if (veh_idx != 433) return bDestFound;
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perf.Stop();
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int t = perf.Get(1000000);
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_total_pf_time_us += t;
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char ttc = Yapf().TransportTypeChar();
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float cache_hit_ratio = (float)m_stats_cache_hits / (float)(m_stats_cache_hits + m_stats_cost_calcs) * 100.0f;
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int cost = bDestFound ? m_pBestDestNode->m_cost : -1;
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int dist = bDestFound ? m_pBestDestNode->m_estimate - m_pBestDestNode->m_cost : -1;
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#ifdef UNITTEST
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printf("%c%c%4d-%6d us -%5d rounds -%4d open -%5d closed - CHR %4.1f%% - c/d(%d, %d) - c%d(sc%d, ts%d, o%d) -- \n", bDestFound ? '-' : '!', ttc, veh_idx, t, m_num_steps, m_nodes.OpenCount(), m_nodes.ClosedCount(), cache_hit_ratio, cost, dist, m_perf_cost.Get(1000000), m_perf_slope_cost.Get(1000000), m_perf_ts_cost.Get(1000000), m_perf_other_cost.Get(1000000));
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#else
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DEBUG(yapf, 3)("[YAPF][YAPF%c]%c%4d- %d us - %d rounds - %d open - %d closed - CHR %4.1f%% - c%d(sc%d, ts%d, o%d) -- ", ttc, bDestFound ? '-' : '!', veh_idx, t, m_num_steps, m_nodes.OpenCount(), m_nodes.ClosedCount(), cache_hit_ratio, cost, dist, m_perf_cost.Get(1000000), m_perf_slope_cost.Get(1000000), m_perf_ts_cost.Get(1000000), m_perf_other_cost.Get(1000000));
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#endif
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return bDestFound;
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}
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/** If path was found return the best node that has reached the destination. Otherwise
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return the best visited node (which was nearest to the destination).
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*/
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FORCEINLINE Node& GetBestNode()
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{
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return (m_pBestDestNode != NULL) ? *m_pBestDestNode : *m_pBestIntermediateNode;
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}
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/** Calls NodeList::CreateNewNode() - allocates new node that can be filled and used
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as argument for AddStartupNode() or AddNewNode()
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*/
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FORCEINLINE Node& CreateNewNode()
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{
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Node& node = *m_nodes.CreateNewNode();
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return node;
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}
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/** Add new node (created by CreateNewNode and filled with data) into open list */
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FORCEINLINE void AddStartupNode(Node& n)
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{
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Yapf().PfNodeCacheFetch(n);
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m_nodes.InsertOpenNode(n);
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}
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/** add multiple nodes - direct children of the given node */
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FORCEINLINE void AddMultipleNodes(Node* parent, TileIndex tile, TrackdirBits td_bits)
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{
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bool is_choice = (KillFirstBit2x64(td_bits) != 0);
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for (TrackdirBits rtds = td_bits; rtds != TRACKDIR_BIT_NONE; rtds = (TrackdirBits)KillFirstBit2x64(rtds)) {
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Trackdir td = (Trackdir)FindFirstBit2x64(rtds);
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Node& n = Yapf().CreateNewNode();
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n.Set(parent, tile, td, is_choice);
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Yapf().AddNewNode(n);
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}
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}
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/** AddNewNode() - called by Tderived::PfFollowNode() for each child node.
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Nodes are evaluated here and added into open list */
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void AddNewNode(Node& n)
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{
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// evaluate the node
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bool bCached = Yapf().PfNodeCacheFetch(n);
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if (!bCached) {
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m_stats_cost_calcs++;
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} else {
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m_stats_cache_hits++;
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}
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bool bValid = Yapf().PfCalcCost(n);
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if (bCached) {
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Yapf().PfNodeCacheFlush(n);
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}
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if (bValid) bValid = Yapf().PfCalcEstimate(n);
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// have the cost or estimate callbacks marked this node as invalid?
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if (!bValid) return;
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// detect the destination
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bool bDestination = Yapf().PfDetectDestination(n);
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if (bDestination) {
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if (m_pBestDestNode == NULL || n < *m_pBestDestNode) {
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m_pBestDestNode = &n;
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}
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m_nodes.FoundBestNode(n);
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return;
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}
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if (m_max_search_nodes > 0 && (m_pBestIntermediateNode == NULL || (m_pBestIntermediateNode->GetCostEstimate() - m_pBestIntermediateNode->GetCost()) > (n.GetCostEstimate() - n.GetCost()))) {
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m_pBestIntermediateNode = &n;
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}
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// check new node against open list
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Node& openNode = m_nodes.FindOpenNode(n.GetKey());
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if (&openNode != NULL) {
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// another node exists with the same key in the open list
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// is it better than new one?
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if (n.GetCostEstimate() < openNode.GetCostEstimate()) {
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// update the old node by value from new one
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m_nodes.PopOpenNode(n.GetKey());
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openNode = n;
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// add the updated old node back to open list
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m_nodes.InsertOpenNode(openNode);
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}
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return;
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}
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// check new node against closed list
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Node& closedNode = m_nodes.FindClosedNode(n.GetKey());
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if (&closedNode != NULL) {
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// another node exists with the same key in the closed list
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// is it better than new one?
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int node_est = n.GetCostEstimate();
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int closed_est = closedNode.GetCostEstimate();
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if (node_est < closed_est) {
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// If this assert occurs, you have probably problem in
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// your Tderived::PfCalcCost() or Tderived::PfCalcEstimate().
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// The problem could be:
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// - PfCalcEstimate() gives too large numbers
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// - PfCalcCost() gives too small numbers
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// - You have used negative cost penalty in some cases (cost bonus)
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assert(0);
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return;
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}
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return;
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}
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// the new node is really new
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// add it to the open list
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m_nodes.InsertOpenNode(n);
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}
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const Vehicle* GetVehicle() const {return m_veh;}
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// methods that should be implemented at derived class Types::Tpf (derived from CYapfBaseT)
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#if 0
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/** Example: PfSetStartupNodes() - set source (origin) nodes */
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FORCEINLINE void PfSetStartupNodes()
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{
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// example:
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Node& n1 = *base::m_nodes.CreateNewNode();
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.
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. // setup node members here
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.
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base::m_nodes.InsertOpenNode(n1);
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}
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/** Example: PfFollowNode() - set following (child) nodes of the given node */
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FORCEINLINE void PfFollowNode(Node& org)
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{
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for (each follower of node org) {
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Node& n = *base::m_nodes.CreateNewNode();
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.
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. // setup node members here
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.
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n.m_parent = &org; // set node's parent to allow back tracking
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AddNewNode(n);
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}
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}
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/** Example: PfCalcCost() - set path cost from origin to the given node */
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FORCEINLINE bool PfCalcCost(Node& n)
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{
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// evaluate last step cost
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int cost = ...;
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// set the node cost as sum of parent's cost and last step cost
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n.m_cost = n.m_parent->m_cost + cost;
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return true; // true if node is valid follower (i.e. no obstacle was found)
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}
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/** Example: PfCalcEstimate() - set path cost estimate from origin to the target through given node */
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FORCEINLINE bool PfCalcEstimate(Node& n)
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{
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// evaluate the distance to our destination
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int distance = ...;
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// set estimate as sum of cost from origin + distance to the target
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n.m_estimate = n.m_cost + distance;
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return true; // true if node is valid (i.e. not too far away :)
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}
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/** Example: PfDetectDestination() - return true if the given node is our destination */
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FORCEINLINE bool PfDetectDestination(Node& n)
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{
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bool bDest = (n.m_key.m_x == m_x2) && (n.m_key.m_y == m_y2);
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return bDest;
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}
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#endif
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};
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#endif /* YAPF_BASE_HPP */
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