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210 lines
8.1 KiB
C
210 lines
8.1 KiB
C
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// Copyright (C) 2002-2012 Nikolaus Gebhardt
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// This file is part of the "Irrlicht Engine".
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// For conditions of distribution and use, see copyright notice in irrlicht.h
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#ifndef __I_GEOMETRY_CREATOR_H_INCLUDED__
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#define __I_GEOMETRY_CREATOR_H_INCLUDED__
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#include "IReferenceCounted.h"
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#include "IMesh.h"
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#include "IImage.h"
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namespace irr
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{
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namespace video
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{
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class IVideoDriver;
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class SMaterial;
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}
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namespace scene
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{
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enum ECUBE_MESH_TYPE
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{
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//! Single buffer with 12 different vertices, normals are average of adjacent planes
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//! Order for outgoing (front-face) normals of planes would be: NEG_Z, POS_X, POS_Z, NEG_X, POS_Y, NEG_Y
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ECMT_1BUF_12VTX_NA,
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//! One buffer per side, each with 4 vertices, normals are perpendicular to sides
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//! Note: You probably will have to scale down your texture uv's to avoid white lines at borders
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// as this mesh sets them to 0,1 values. We can't do that when creating the mesh as it
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// depends on texture resolution which we don't know at that point.
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ECMT_6BUF_4VTX_NP
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};
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//! Helper class for creating geometry on the fly.
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/** You can get an instance of this class through ISceneManager::getGeometryCreator() */
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class IGeometryCreator : public IReferenceCounted
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{
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public:
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//! Creates a simple cube mesh.
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/**
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\param size Dimensions of the cube.
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\param type One of ECUBE_MESH_TYPE. So you can chose between cubes with single material or independent materials per side.
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\return Generated mesh.
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*/
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virtual IMesh* createCubeMesh(const core::vector3df& size=core::vector3df(5.f,5.f,5.f), ECUBE_MESH_TYPE type = ECMT_1BUF_12VTX_NA) const =0;
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//! Create a pseudo-random mesh representing a hilly terrain.
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/**
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\param tileSize The size of each tile.
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\param tileCount The number of tiles in each dimension.
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\param material The material to apply to the mesh.
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\param hillHeight The maximum height of the hills.
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\param countHills The number of hills along each dimension.
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\param textureRepeatCount The number of times to repeat the material texture along each dimension.
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\return Generated mesh.
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*/
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virtual IMesh* createHillPlaneMesh(
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const core::dimension2d<f32>& tileSize,
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const core::dimension2d<u32>& tileCount,
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video::SMaterial* material, f32 hillHeight,
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const core::dimension2d<f32>& countHills,
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const core::dimension2d<f32>& textureRepeatCount) const =0;
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//! Create a simple rectangular textured plane mesh.
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/**
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\param tileSize The size of each tile.
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\param tileCount The number of tiles in each dimension.
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\param material The material to apply to the mesh.
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\param textureRepeatCount The number of times to repeat the material texture along each dimension.
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\return Generated mesh.
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*/
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IMesh* createPlaneMesh(
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const core::dimension2d<f32>& tileSize,
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const core::dimension2d<u32>& tileCount=core::dimension2du(1,1),
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video::SMaterial* material=0,
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const core::dimension2df& textureRepeatCount=core::dimension2df(1.f,1.f)) const
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{
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return createHillPlaneMesh(tileSize, tileCount, material, 0.f, core::dimension2df(), textureRepeatCount);
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}
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//! Create a geoplane.
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/**
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\param radius Radius of the plane
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\param rows How many rows to place
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\param columns How many columns to place
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\return Generated mesh.
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*/
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virtual IMesh* createGeoplaneMesh(f32 radius = 5.f,
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u32 rows = 16, u32 columns = 16) const =0;
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//! Create a terrain mesh from an image representing a heightfield.
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/**
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\param texture The texture to apply to the terrain.
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\param heightmap An image that will be interpreted as a heightmap. The
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brightness (average color) of each pixel is interpreted as a height,
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with a 255 brightness pixel producing the maximum height.
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\param stretchSize The size that each pixel will produce, i.e. a
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512x512 heightmap
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and a stretchSize of (10.f, 20.f) will produce a mesh of size
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5120.f x 10240.f
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\param maxHeight The maximum height of the terrain.
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\param driver The current video driver.
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\param defaultVertexBlockSize (to be documented)
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\param debugBorders (to be documented)
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\return Generated mesh.
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*/
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virtual IMesh* createTerrainMesh(video::IImage* texture,
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video::IImage* heightmap,
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const core::dimension2d<f32>& stretchSize,
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f32 maxHeight, video::IVideoDriver* driver,
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const core::dimension2d<u32>& defaultVertexBlockSize,
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bool debugBorders=false) const =0;
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//! Create an arrow mesh, composed of a cylinder and a cone.
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/**
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\param tesselationCylinder Number of quads composing the cylinder.
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\param tesselationCone Number of triangles composing the cone's roof.
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\param height Total height of the arrow
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\param cylinderHeight Total height of the cylinder, should be lesser
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than total height
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\param widthCylinder Diameter of the cylinder
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\param widthCone Diameter of the cone's base, should be not smaller
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than the cylinder's diameter
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\param colorCylinder color of the cylinder
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\param colorCone color of the cone
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\return Generated mesh.
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*/
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virtual IMesh* createArrowMesh(const u32 tesselationCylinder = 4,
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const u32 tesselationCone = 8, const f32 height = 1.f,
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const f32 cylinderHeight = 0.6f, const f32 widthCylinder = 0.05f,
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const f32 widthCone = 0.3f, const video::SColor colorCylinder = 0xFFFFFFFF,
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const video::SColor colorCone = 0xFFFFFFFF) const =0;
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//! Create a sphere mesh.
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/**
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\param radius Radius of the sphere
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\param polyCountX Number of quads used for the horizontal tiling
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\param polyCountY Number of quads used for the vertical tiling
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\return Generated mesh.
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*/
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virtual IMesh* createSphereMesh(f32 radius = 5.f,
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u32 polyCountX = 16, u32 polyCountY = 16) const =0;
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//! Create a cylinder mesh.
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/**
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\param radius Radius of the cylinder.
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\param length Length of the cylinder.
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\param tesselation Number of quads around the circumference of the cylinder.
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\param color The color of the cylinder.
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\param closeTop If true, close the ends of the cylinder, otherwise leave them open.
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\param oblique X-offset (shear) of top compared to bottom.
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\param normalType When 0 side normals are radial from origin. Note that origin is at the bottom.
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When 1 side normals are flat along top/bottom polygons.
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NOTE: To get normals which are perpendicular to the side of an oblique
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cylinder, don't use the oblique parameter. Instead set normalType to 1
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and create a cylinder with oblique set to 0. Then use
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IMeshManipulator::transform with a shear matrix on the returned mesh.
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You get a shear matrix for an identical effect of this oblique parameter when you
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set the 4th element of an identity matrix to (oblique/length).
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\return Generated mesh.
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*/
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virtual IMesh* createCylinderMesh(f32 radius, f32 length,
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u32 tesselation,
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const video::SColor& color=video::SColor(0xffffffff),
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bool closeTop=true, f32 oblique=0.f, u32 normalType=0) const =0;
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//! Create a cone mesh.
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/**
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\param radius Radius of the cone.
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\param length Length of the cone.
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\param tesselation Number of quads around the circumference of the cone.
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\param colorTop The color of the top of the cone.
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\param colorBottom The color of the bottom of the cone.
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\param oblique (to be documented)
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\return Generated mesh.
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*/
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virtual IMesh* createConeMesh(f32 radius, f32 length, u32 tesselation,
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const video::SColor& colorTop=video::SColor(0xffffffff),
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const video::SColor& colorBottom=video::SColor(0xffffffff),
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f32 oblique=0.f) const =0;
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//! Create a volume light mesh.
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/**
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\param subdivideU Horizontal patch count.
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\param subdivideV Vertical patch count.
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\param footColor Color at the bottom of the light.
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\param tailColor Color at the mid of the light.
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\param lpDistance Virtual distance of the light point for normals.
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\param lightDim Dimensions of the light.
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\return Generated mesh.
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*/
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virtual IMesh* createVolumeLightMesh(
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const u32 subdivideU=32, const u32 subdivideV=32,
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const video::SColor footColor = 0xffffffff,
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const video::SColor tailColor = 0xffffffff,
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const f32 lpDistance = 8.f,
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const core::vector3df& lightDim = core::vector3df(1.f,1.2f,1.f)) const =0;
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};
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} // end namespace scene
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} // end namespace irr
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#endif // __I_GEOMETRY_CREATOR_H_INCLUDED__
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