/* Copyright (C) 2015 Wildfire Games. * This file is part of 0 A.D. * * 0 A.D. 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 2 of the License, or * (at your option) any later version. * * 0 A.D. 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 0 A.D. If not, see . */ #ifndef INCLUDED_ICMPPATHFINDER #define INCLUDED_ICMPPATHFINDER #include "simulation2/system/Interface.h" #include "simulation2/components/ICmpObstruction.h" #include "simulation2/helpers/PathGoal.h" #include "simulation2/helpers/Pathfinding.h" #include "maths/FixedVector2D.h" #include #include class IObstructionTestFilter; template class Grid; /** * Pathfinder algorithms. * * There are two different modes: a tile-based pathfinder that works over long distances and * accounts for terrain costs but ignore units, and a 'short' vertex-based pathfinder that * provides precise paths and avoids other units. * * Both use the same concept of a PathGoal: either a point, circle or square. * (If the starting point is inside the goal shape then the path will move outwards * to reach the shape's outline.) * * The output is a list of waypoints. */ class ICmpPathfinder : public IComponent { public: /** * Get the list of all known passability classes. */ virtual void GetPassabilityClasses(std::map& passClasses) const = 0; /** * Get the list of passability classes, separating pathfinding classes and others. */ virtual void GetPassabilityClasses( std::map& nonPathfindingPassClasses, std::map& pathfindingPassClasses) const = 0; /** * Get the tag for a given passability class name. * Logs an error and returns something acceptable if the name is unrecognised. */ virtual pass_class_t GetPassabilityClass(const std::string& name) = 0; virtual entity_pos_t GetClearance(pass_class_t passClass) const = 0; /** * Get the larger clearance in all passability classes. */ virtual entity_pos_t GetMaximumClearance() const = 0; virtual const Grid& GetPassabilityGrid() = 0; /** * Passes the lazily-stored dirtiness data collected from * the obstruction manager during the previous grid update. */ virtual const GridUpdateInformation& GetDirtinessData() const = 0; /** * Get a grid representing the distance to the shore of the terrain tile. */ virtual Grid ComputeShoreGrid(bool expandOnWater = false) = 0; /** * Compute a tile-based path from the given point to the goal, and return the set of waypoints. * The waypoints correspond to the centers of horizontally/vertically adjacent tiles * along the path. */ virtual void ComputePath(entity_pos_t x0, entity_pos_t z0, const PathGoal& goal, pass_class_t passClass, WaypointPath& ret) = 0; /** * Asynchronous version of ComputePath. * The result will be sent as CMessagePathResult to 'notify'. * Returns a unique non-zero number, which will match the 'ticket' in the result, * so callers can recognise each individual request they make. */ virtual u32 ComputePathAsync(entity_pos_t x0, entity_pos_t z0, const PathGoal& goal, pass_class_t passClass, entity_id_t notify) = 0; /** * If the debug overlay is enabled, render the path that will computed by ComputePath. */ virtual void SetDebugPath(entity_pos_t x0, entity_pos_t z0, const PathGoal& goal, pass_class_t passClass) = 0; /** * Compute a precise path from the given point to the goal, and return the set of waypoints. * The path is based on the full set of obstructions that pass the filter, such that * a unit of clearance 'clearance' will be able to follow the path with no collisions. * The path is restricted to a box of radius 'range' from the starting point. */ virtual void ComputeShortPath(const IObstructionTestFilter& filter, entity_pos_t x0, entity_pos_t z0, entity_pos_t clearance, entity_pos_t range, const PathGoal& goal, pass_class_t passClass, WaypointPath& ret) = 0; /** * Asynchronous version of ComputeShortPath (using ControlGroupObstructionFilter). * The result will be sent as CMessagePathResult to 'notify'. * Returns a unique non-zero number, which will match the 'ticket' in the result, * so callers can recognise each individual request they make. */ virtual u32 ComputeShortPathAsync(entity_pos_t x0, entity_pos_t z0, entity_pos_t clearance, entity_pos_t range, const PathGoal& goal, pass_class_t passClass, bool avoidMovingUnits, entity_id_t group, entity_id_t notify) = 0; /** * Check whether the given movement line is valid and doesn't hit any obstructions * or impassable terrain. * Returns true if the movement is okay. */ virtual bool CheckMovement(const IObstructionTestFilter& filter, entity_pos_t x0, entity_pos_t z0, entity_pos_t x1, entity_pos_t z1, entity_pos_t r, pass_class_t passClass) = 0; /** * Check whether a unit placed here is valid and doesn't hit any obstructions * or impassable terrain. * When onlyCenterPoint = true, only check the center tile of the unit * @return ICmpObstruction::FOUNDATION_CHECK_SUCCESS if the placement is okay, else * a value describing the type of failure. */ virtual ICmpObstruction::EFoundationCheck CheckUnitPlacement(const IObstructionTestFilter& filter, entity_pos_t x, entity_pos_t z, entity_pos_t r, pass_class_t passClass, bool onlyCenterPoint = false) = 0; /** * Check whether a building placed here is valid and doesn't hit any obstructions * or impassable terrain. * @return ICmpObstruction::FOUNDATION_CHECK_SUCCESS if the placement is okay, else * a value describing the type of failure. */ virtual ICmpObstruction::EFoundationCheck CheckBuildingPlacement(const IObstructionTestFilter& filter, entity_pos_t x, entity_pos_t z, entity_pos_t a, entity_pos_t w, entity_pos_t h, entity_id_t id, pass_class_t passClass) = 0; /** * Check whether a building placed here is valid and doesn't hit any obstructions * or impassable terrain. * when onlyCenterPoint = true, only check the center tile of the building * @return ICmpObstruction::FOUNDATION_CHECK_SUCCESS if the placement is okay, else * a value describing the type of failure. */ virtual ICmpObstruction::EFoundationCheck CheckBuildingPlacement(const IObstructionTestFilter& filter, entity_pos_t x, entity_pos_t z, entity_pos_t a, entity_pos_t w, entity_pos_t h, entity_id_t id, pass_class_t passClass, bool onlyCenterPoint) = 0; /** * Toggle the storage and rendering of debug info. */ virtual void SetDebugOverlay(bool enabled) = 0; /** * Toggle the storage and rendering of debug info for the hierarchical pathfinder. */ virtual void SetHierDebugOverlay(bool enabled) = 0; /** * Finish computing asynchronous path requests and send the CMessagePathResult messages. */ virtual void FinishAsyncRequests() = 0; /** * Process moves during the same turn they were created in to improve responsiveness. */ virtual void ProcessSameTurnMoves() = 0; /** * Regenerates the grid based on the current obstruction list, if necessary */ virtual void UpdateGrid() = 0; /** * Returns some stats about the last ComputePath. */ virtual void GetDebugData(u32& steps, double& time, Grid& grid) = 0; /** * Sets up the pathfinder passability overlay in Atlas. */ virtual void SetAtlasOverlay(bool enable, pass_class_t passClass = 0) = 0; DECLARE_INTERFACE_TYPE(Pathfinder) }; #endif // INCLUDED_ICMPPATHFINDER