forked from mirror/DotRecast
342 lines
14 KiB
C#
342 lines
14 KiB
C#
/*
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recast4j Copyright (c) 2015-2019 Piotr Piastucki piotr@jtilia.org
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This software is provided 'as-is', without any express or implied
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warranty. In no event will the authors be held liable for any damages
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arising from the use of this software.
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Permission is granted to anyone to use this software for any purpose,
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including commercial applications, and to alter it and redistribute it
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freely, subject to the following restrictions:
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1. The origin of this software must not be misrepresented; you must not
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claim that you wrote the original software. If you use this software
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in a product, an acknowledgment in the product documentation would be
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appreciated but is not required.
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2. Altered source versions must be plainly marked as such, and must not be
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misrepresented as being the original software.
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3. This notice may not be removed or altered from any source distribution.
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*/
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using System;
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using System.Diagnostics;
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using System.IO;
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using DotRecast.Core;
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using DotRecast.Recast.Geom;
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using NUnit.Framework;
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namespace DotRecast.Recast.Test;
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using static RcConstants;
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[Parallelizable]
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public class RecastSoloMeshTest
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{
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private const float m_cellSize = 0.3f;
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private const float m_cellHeight = 0.2f;
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private const float m_agentHeight = 2.0f;
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private const float m_agentRadius = 0.6f;
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private const float m_agentMaxClimb = 0.9f;
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private const float m_agentMaxSlope = 45.0f;
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private const int m_regionMinSize = 8;
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private const int m_regionMergeSize = 20;
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private const float m_edgeMaxLen = 12.0f;
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private const float m_edgeMaxError = 1.3f;
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private const int m_vertsPerPoly = 6;
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private const float m_detailSampleDist = 6.0f;
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private const float m_detailSampleMaxError = 1.0f;
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private PartitionType m_partitionType = PartitionType.WATERSHED;
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[Test]
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public void TestPerformance()
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{
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for (int i = 0; i < 10; i++)
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{
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TestBuild("dungeon.obj", PartitionType.WATERSHED, 52, 16, 15, 223, 118, 118, 513, 291);
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TestBuild("dungeon.obj", PartitionType.MONOTONE, 0, 17, 16, 210, 100, 100, 453, 264);
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TestBuild("dungeon.obj", PartitionType.LAYERS, 0, 5, 5, 203, 97, 97, 446, 266);
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}
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}
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[Test]
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public void TestDungeonWatershed()
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{
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TestBuild("dungeon.obj", PartitionType.WATERSHED, 52, 16, 15, 223, 118, 118, 513, 291);
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}
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[Test]
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public void TestDungeonMonotone()
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{
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TestBuild("dungeon.obj", PartitionType.MONOTONE, 0, 17, 16, 210, 100, 100, 453, 264);
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}
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[Test]
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public void TestDungeonLayers()
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{
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TestBuild("dungeon.obj", PartitionType.LAYERS, 0, 5, 5, 203, 97, 97, 446, 266);
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}
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[Test]
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public void TestWatershed()
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{
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TestBuild("nav_test.obj", PartitionType.WATERSHED, 60, 48, 47, 349, 155, 155, 812, 561);
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}
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[Test]
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public void TestMonotone()
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{
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TestBuild("nav_test.obj", PartitionType.MONOTONE, 0, 50, 49, 341, 186, 186, 878, 567);
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}
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[Test]
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public void TestLayers()
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{
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TestBuild("nav_test.obj", PartitionType.LAYERS, 0, 19, 32, 310, 150, 150, 773, 526);
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}
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public void TestBuild(string filename, PartitionType partitionType, int expDistance, int expRegions,
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int expContours, int expVerts, int expPolys, int expDetMeshes, int expDetVerts, int expDetTris)
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{
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m_partitionType = partitionType;
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IInputGeomProvider geomProvider = ObjImporter.Load(Loader.ToBytes(filename));
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long time = RcFrequency.Ticks;
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RcVec3f bmin = geomProvider.GetMeshBoundsMin();
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RcVec3f bmax = geomProvider.GetMeshBoundsMax();
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RcTelemetry m_ctx = new RcTelemetry();
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//
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// Step 1. Initialize build config.
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//
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// Init build configuration from GUI
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RcConfig cfg = new RcConfig(partitionType, m_cellSize, m_cellHeight, m_agentHeight, m_agentRadius,
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m_agentMaxClimb, m_agentMaxSlope, m_regionMinSize, m_regionMergeSize, m_edgeMaxLen, m_edgeMaxError,
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m_vertsPerPoly, m_detailSampleDist, m_detailSampleMaxError, SampleAreaModifications.SAMPLE_AREAMOD_GROUND);
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RecastBuilderConfig bcfg = new RecastBuilderConfig(cfg, bmin, bmax);
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//
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// Step 2. Rasterize input polygon soup.
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//
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// Allocate voxel heightfield where we rasterize our input data to.
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RcHeightfield m_solid = new RcHeightfield(bcfg.width, bcfg.height, bcfg.bmin, bcfg.bmax, cfg.cs, cfg.ch, cfg.borderSize);
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foreach (RcTriMesh geom in geomProvider.Meshes())
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{
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float[] verts = geom.GetVerts();
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int[] tris = geom.GetTris();
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int ntris = tris.Length / 3;
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// Allocate array that can hold triangle area types.
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// If you have multiple meshes you need to process, allocate
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// and array which can hold the max number of triangles you need to process.
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// Find triangles which are walkable based on their slope and rasterize them.
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// If your input data is multiple meshes, you can transform them here, calculate
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// the are type for each of the meshes and rasterize them.
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int[] m_triareas = Recast.MarkWalkableTriangles(m_ctx, cfg.walkableSlopeAngle, verts, tris, ntris, cfg.walkableAreaMod);
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RecastRasterization.RasterizeTriangles(m_solid, verts, tris, m_triareas, ntris, cfg.walkableClimb, m_ctx);
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}
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//
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// Step 3. Filter walkable surfaces.
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//
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// Once all geometry is rasterized, we do initial pass of filtering to
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// remove unwanted overhangs caused by the conservative rasterization
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// as well as filter spans where the character cannot possibly stand.
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RecastFilter.FilterLowHangingWalkableObstacles(m_ctx, cfg.walkableClimb, m_solid);
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RecastFilter.FilterLedgeSpans(m_ctx, cfg.walkableHeight, cfg.walkableClimb, m_solid);
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RecastFilter.FilterWalkableLowHeightSpans(m_ctx, cfg.walkableHeight, m_solid);
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//
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// Step 4. Partition walkable surface to simple regions.
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//
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// Compact the heightfield so that it is faster to handle from now on.
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// This will result more cache coherent data as well as the neighbours
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// between walkable cells will be calculated.
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RcCompactHeightfield m_chf = RecastCompact.BuildCompactHeightfield(m_ctx, cfg.walkableHeight, cfg.walkableClimb,
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m_solid);
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// Erode the walkable area by agent radius.
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RecastArea.ErodeWalkableArea(m_ctx, cfg.walkableRadius, m_chf);
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// (Optional) Mark areas.
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/*
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* ConvexVolume vols = m_geom->GetConvexVolumes(); for (int i = 0; i < m_geom->GetConvexVolumeCount(); ++i)
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* RcMarkConvexPolyArea(m_ctx, vols[i].verts, vols[i].nverts, vols[i].hmin, vols[i].hmax, (unsigned
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* char)vols[i].area, *m_chf);
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*/
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// Partition the heightfield so that we can use simple algorithm later
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// to triangulate the walkable areas.
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// There are 3 martitioning methods, each with some pros and cons:
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// 1) Watershed partitioning
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// - the classic Recast partitioning
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// - creates the nicest tessellation
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// - usually slowest
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// - partitions the heightfield into nice regions without holes or
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// overlaps
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// - the are some corner cases where this method creates produces holes
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// and overlaps
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// - holes may appear when a small obstacles is close to large open area
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// (triangulation can handle this)
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// - overlaps may occur if you have narrow spiral corridors (i.e
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// stairs), this make triangulation to fail
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// * generally the best choice if you precompute the nacmesh, use this
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// if you have large open areas
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// 2) Monotone partioning
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// - fastest
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// - partitions the heightfield into regions without holes and overlaps
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// (guaranteed)
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// - creates long thin polygons, which sometimes causes paths with
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// detours
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// * use this if you want fast navmesh generation
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// 3) Layer partitoining
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// - quite fast
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// - partitions the heighfield into non-overlapping regions
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// - relies on the triangulation code to cope with holes (thus slower
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// than monotone partitioning)
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// - produces better triangles than monotone partitioning
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// - does not have the corner cases of watershed partitioning
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// - can be slow and create a bit ugly tessellation (still better than
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// monotone)
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// if you have large open areas with small obstacles (not a problem if
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// you use tiles)
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// * good choice to use for tiled navmesh with medium and small sized
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// tiles
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long time3 = RcFrequency.Ticks;
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if (m_partitionType == PartitionType.WATERSHED)
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{
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// Prepare for region partitioning, by calculating distance field
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// along the walkable surface.
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RecastRegion.BuildDistanceField(m_ctx, m_chf);
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// Partition the walkable surface into simple regions without holes.
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RecastRegion.BuildRegions(m_ctx, m_chf, cfg.minRegionArea, cfg.mergeRegionArea);
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}
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else if (m_partitionType == PartitionType.MONOTONE)
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{
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// Partition the walkable surface into simple regions without holes.
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// Monotone partitioning does not need distancefield.
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RecastRegion.BuildRegionsMonotone(m_ctx, m_chf, cfg.minRegionArea, cfg.mergeRegionArea);
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}
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else
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{
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// Partition the walkable surface into simple regions without holes.
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RecastRegion.BuildLayerRegions(m_ctx, m_chf, cfg.minRegionArea);
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}
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Assert.That(m_chf.maxDistance, Is.EqualTo(expDistance), "maxDistance");
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Assert.That(m_chf.maxRegions, Is.EqualTo(expRegions), "Regions");
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//
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// Step 5. Trace and simplify region contours.
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//
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// Create contours.
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RcContourSet m_cset = RecastContour.BuildContours(m_ctx, m_chf, cfg.maxSimplificationError, cfg.maxEdgeLen,
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RcConstants.RC_CONTOUR_TESS_WALL_EDGES);
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Assert.That(m_cset.conts.Count, Is.EqualTo(expContours), "Contours");
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//
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// Step 6. Build polygons mesh from contours.
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//
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// Build polygon navmesh from the contours.
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RcPolyMesh m_pmesh = RecastMesh.BuildPolyMesh(m_ctx, m_cset, cfg.maxVertsPerPoly);
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Assert.That(m_pmesh.nverts, Is.EqualTo(expVerts), "Mesh Verts");
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Assert.That(m_pmesh.npolys, Is.EqualTo(expPolys), "Mesh Polys");
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//
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// Step 7. Create detail mesh which allows to access approximate height
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// on each polygon.
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//
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RcPolyMeshDetail m_dmesh = RecastMeshDetail.BuildPolyMeshDetail(m_ctx, m_pmesh, m_chf, cfg.detailSampleDist,
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cfg.detailSampleMaxError);
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Assert.That(m_dmesh.nmeshes, Is.EqualTo(expDetMeshes), "Mesh Detail Meshes");
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Assert.That(m_dmesh.nverts, Is.EqualTo(expDetVerts), "Mesh Detail Verts");
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Assert.That(m_dmesh.ntris, Is.EqualTo(expDetTris), "Mesh Detail Tris");
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long time2 = RcFrequency.Ticks;
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Console.WriteLine(filename + " : " + partitionType + " " + (time2 - time) / TimeSpan.TicksPerMillisecond + " ms");
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Console.WriteLine(" " + (time3 - time) / TimeSpan.TicksPerMillisecond + " ms");
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SaveObj(filename.Substring(0, filename.LastIndexOf('.')) + "_" + partitionType + "_detail.obj", m_dmesh);
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SaveObj(filename.Substring(0, filename.LastIndexOf('.')) + "_" + partitionType + ".obj", m_pmesh);
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foreach (var rtt in m_ctx.ToList())
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{
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Console.WriteLine($"{rtt.Key} : {rtt.Millis} ms");
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}
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}
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private void SaveObj(string filename, RcPolyMesh mesh)
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{
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try
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{
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string path = Path.Combine("test-output", filename);
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Directory.CreateDirectory(Path.GetDirectoryName(path));
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using StreamWriter fw = new StreamWriter(path);
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for (int v = 0; v < mesh.nverts; v++)
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{
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fw.Write("v " + (mesh.bmin.x + mesh.verts[v * 3] * mesh.cs) + " "
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+ (mesh.bmin.y + mesh.verts[v * 3 + 1] * mesh.ch) + " "
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+ (mesh.bmin.z + mesh.verts[v * 3 + 2] * mesh.cs) + "\n");
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}
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for (int i = 0; i < mesh.npolys; i++)
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{
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int p = i * mesh.nvp * 2;
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fw.Write("f ");
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for (int j = 0; j < mesh.nvp; ++j)
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{
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int v = mesh.polys[p + j];
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if (v == RC_MESH_NULL_IDX)
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{
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break;
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}
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fw.Write((v + 1) + " ");
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}
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fw.Write("\n");
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}
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fw.Close();
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}
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catch (Exception e)
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{
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Console.WriteLine(e);
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}
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}
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private void SaveObj(string filename, RcPolyMeshDetail dmesh)
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{
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try
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{
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string filePath = Path.Combine("test-output", filename);
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Directory.CreateDirectory(Path.GetDirectoryName(filePath));
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using StreamWriter fw = new StreamWriter(filePath);
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for (int v = 0; v < dmesh.nverts; v++)
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{
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fw.Write(
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"v " + dmesh.verts[v * 3] + " " + dmesh.verts[v * 3 + 1] + " " + dmesh.verts[v * 3 + 2] + "\n");
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}
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for (int m = 0; m < dmesh.nmeshes; m++)
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{
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int vfirst = dmesh.meshes[m * 4];
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int tfirst = dmesh.meshes[m * 4 + 2];
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for (int f = 0; f < dmesh.meshes[m * 4 + 3]; f++)
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{
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fw.Write("f " + (vfirst + dmesh.tris[(tfirst + f) * 4] + 1) + " "
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+ (vfirst + dmesh.tris[(tfirst + f) * 4 + 1] + 1) + " "
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+ (vfirst + dmesh.tris[(tfirst + f) * 4 + 2] + 1) + "\n");
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}
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}
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fw.Close();
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}
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catch (Exception e)
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{
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Console.WriteLine(e);
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}
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}
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} |