Unigine::ObjectMeshClutter Class
Header: | #include <UnigineObjects.h> |
Inherits: | Object |
MeshClutter is used to scatter identical meshes (with the same material applied to their surfaces), as well as randomly scale and orient them. Scattered meshes are baked into one object, which allows for less cluttered spatial tree, reduces the number of texture fetches and speeds up rendering.
Meshes are rendered within a specified
distance from the camera. Further than this distance, nodes fade out and then disappear completely.
The following samples demonstrate the ObjectMeshClutter class usage:
ObjectMeshClutter Class
Members
static ObjectMeshClutterPtr create(const char * arg1, int unique = 0)
ObjectMeshClutter constructor.Arguments
- const char * arg1 - Name of the mesh file.
- int unique - When you create several objects out of a single .mesh file, the instance of the mesh geometry is created. If you then change the source geometry, its instances will be changed as well. To avoid this, set the unique flag to 1, so a copy of the mesh geometry will be created and changes won't be applied.
Ptr<ObjectMeshClutter> cast(const Ptr<Object> & base)
Casts an ObjectMeshClutter out of the Object instance.Arguments
- const Ptr<Object> & base - Pointer to Object.
Return value
Pointer to ObjectMeshClutter.Ptr<ObjectMeshClutter> cast(const Ptr<Node> & node)
Casts an ObjectMeshClutter out of the Node instance.Arguments
- const Ptr<Node> & node - Pointer to Node.
Return value
Pointer to ObjectMeshClutter.void setAngle(float angle)
Sets the angle cosine that defines the slope steepness appropriate for positioning meshes.Arguments
- float angle - Slope angle cosine. The provided value will be clipped in range [0;1].
float getAngle()
Returns the current angle cosine that defines the slope steepness appropriate for positioning meshes.Return value
Slope angle cosine.void setCollision(int collision)
Sets a value indicating if collisions with the object should be taken into account.If the collision parameter is set to 0, the new geometry will never be generated by collision detection request.
Arguments
- int collision - 1 to take collisions into account and make the object important for physics; 0 to allow collisions only with already generated geometry.
int getCollision()
Returns a value indicating if collisions with the object should be taken into account.If the return value is 0 the new geometry will never be generated by collision detection request.
Return value
1 if collisions are taken into account; 0 if collisions are allowed only with already generated geometry.void setDensity(float density)
Sets the density factor that defines the number of meshes per square unit.Arguments
- float density - Density factor. If a negative value is provided, 0 will be used instead.
float getDensity()
Returns the current density factor that defines the number of meshes per square unit.Return value
Density factor.void setFadeDistance(float distance)
Sets the distance up to which meshes scattered by the mesh clutter will be fading out (that is, fewer meshes will be rendered instead of all). The distance is measured starting from the visible distance.In order for a fade distance to be applied, visibility distance should not be infinite.
Arguments
- float distance - Distance of fading for meshes in units. If a negative value is provided, 0 will be used instead.
float getFadeDistance()
Returns the current distance up to which meshes scattered by the mesh clutter are fading out (that is, fewer meshes will be rendered instead of all). The distance is measured starting from the visible distance.In order for a fade distance to be applied, visibility distance should not be infinite.
Return value
Distance of nodes fading in units.void setIntersection(int intersection)
Sets a value indicating whether meshes should be scattered upon the ground (along its relief): either the terrain or a mesh set as a parent node.Arguments
- int intersection - Positive number to enable intersection; 0 to disable.
int getIntersection()
Returns a value indicating whether meshes are scattered upon the ground (along its relief): either the terrain or a mesh set as a parent node.Return value
1 if intersection is enabled; otherwise, 0.void setMaskFlipX(int value)
Flip the mask by X axis.Arguments
- int value - Positive value to flip the mask; otherwise, 0.
int getMaskFlipX()
Returns a flag indicating if a mask is flipped by X axis.Return value
Positive value if the mask is flipped; otherwise, 0.void setMaskFlipY(int value)
Flip the mask by Y axis.Arguments
- int value - Positive value to flip the mask; otherwise, 0.
int getMaskFlipY()
Returns a flag indicating if a mask is flipped by Y axis.Return value
Positive value if the mask is flipped; otherwise, 0.int setMaskImage(const Ptr<Image> & image)
Sets an image (in R8 format) that defines placement of meshes.Arguments
- const Ptr<Image> & image - Image smart pointer.
Return value
1 if the mask image is successfully set; otherwise, 0.int getMaskImage(const Ptr<Image> & image)
Writes the image that is currently used as a mask for placement of meshes into the given buffer.Arguments
- const Ptr<Image> & image - Image smart pointer.
Return value
1 if the mask image is successfully written into the buffer; otherwise, 0.void setMaskImageName(const char * name)
Sets the name of a mask texture (in R8 format) that defines the placement of meshes.Arguments
- const char * name - Name (path) of the mask texture.
const char * getMaskImageName()
Returns the name of a mask texture (in R8 format) that defines the placement of meshes.Return value
Name (path) of the mask texture.void setMaskInverse(int inverse)
Specifies if clutter meshes should be rendered inside or outside the mask mesh contour.Arguments
- int inverse - 0 to render clutter meshes inside the mask mesh contour; 1 to render them outside.
int getMaskInverse()
Returns a flag indicating if clutter meshes are rendered inside or outside the mask mesh contour.Return value
0 if clutter meshes are rendered inside the mask mesh contour; 1 if outside.void setMaskMaxValue(int value)
Sets the maximum value of the mask application range.Arguments
- int value - Maximum mask value, [0;255].
int getMaskMaxValue()
Returns the maximum value of the mask application range.Return value
Maximum mask value.int setMaskMesh(const Ptr<Mesh> & mesh)
Sets a mesh to be used as a mask on-the-fly. Limitations:- Before the method is called, another mesh must be set via setMaskMeshName() first.
- If the world is reloaded, the mesh set via setMaskMeshName() will be loaded.
- If the memory limit is exceeded, the new mesh might be reloaded with the mesh set via setMaskMeshName().
Arguments
- const Ptr<Mesh> & mesh - Pointer to the mesh.
Return value
1 if the mesh is set successfully; otherwise - 0.int getMaskMesh(const Ptr<Mesh> & mesh)
Returns a value indicating if the mesh mask exists.Arguments
- const Ptr<Mesh> & mesh - Pointer to the mesh.
Return value
1 if mesh mask exists; otherwise - 0.void setMaskMeshName(const char * name)
Sets a mesh to be used as a mask for the mesh clutter. This mesh should be plane.Arguments
- const char * name - Path to the *.mesh file.
const char * getMaskMeshName()
Returns the current mesh to used as a mask for the mesh clutter. This mesh should be plane.Return value
Path to the *.mesh file.void setMaskMinValue(int value)
Sets the minimum value of the mask application range.Arguments
- int value - Minimum mask value, [0;255].
int getMaskMinValue()
Returns the minimum value of the mask application range.Return value
Minimum mask value.void setMaxScale(float mean, float spread)
Sets the scale for meshes in the areas with high density (according to the mask). With the minimum scale it is possible to automatically render, for example, big trees in the center of the forest. A spread value allows you to control the range of scales relative to the mean value.Arguments
- float mean - Scale mean value.
- float spread - Maximum spread value to randomly upscale or downscale objects.
float getMaxScaleMean()
Returns the scale mean value for meshes in the areas with high density (according to the mask).Return value
Scale mean value.float getMaxScaleSpread()
Returns the scale spread value that controls the range of mesh scales in the areas with high density (according to the mask).Return value
Scale spread value.int setMesh(const Ptr<Mesh> & mesh)
Copies the source mesh into the current mesh.Arguments
- const Ptr<Mesh> & mesh - The source mesh to be copied.
Return value
1 if the mesh is copied successfully; otherwise, 0.int getMesh(const Ptr<Mesh> & mesh)
Copies the current mesh into the source mesh.Arguments
- const Ptr<Mesh> & mesh - The source mesh.
Return value
1 if the mesh is copied successfully; otherwise, 0.void setMeshesRotation(const Math::vec3 & mean, const Math::vec3 & spread)
Arguments
- const Math::vec3 & mean
- const Math::vec3 & spread
Math::vec3 getMeshesRotationMean()
Math::vec3 getMeshesRotationSpread()
void setMeshName(const char * name, int force_load = 0)
Sets a name for the mesh scattered by the mesh clutter and forces creating of the mesh with the new name.Arguments
- const char * name - Name to be set for the mesh.
- int force_load - Force flag.
- If 1 is specified, the mesh with the new name will be created immediately with the unique flag set to 0.
- If 0 is specified, only the mesh name will be updated.
const char * getMeshName()
Returns the name of the mesh scattered by mesh clutter.Return value
Mesh name.void setMinScale(float mean, float spread)
Sets the scale for meshes in the areas with low density (according to the mask). With the minimum scale it is possible to automatically render, for example, small trees at the forest border. A spread value allows you to control the range of scales relative to the mean value.Arguments
- float mean - Scale mean value.
- float spread - Maximum spread value to randomly upscale or downscale objects.
float getMinScaleMean()
Returns the scale mean value for meshes in the areas with low density (according to the mask).Return value
Scale mean value.float getMinScaleSpread()
Returns the scale spread value that controls the range of mesh scales in the areas with low density (according to the mask).Return value
Scale spread value.int getNumSurfaceTargets(int surface)
Returns the total number of surface targets.Arguments
- int surface - Surface number.
Return value
Total number of surface targets.void setOffset(float mean, float spread)
Sets the vertical offset that determines the placement of meshes above or below the surface.Arguments
- float mean - Mean value of the offset in units.
- float spread - Spread value of the offset in units.
float getOffsetMean()
Returns the current mean value of the vertical offset that determines the placement of meshes above or below the surface.Return value
Mean value of the offset in units.float getOffsetSpread()
Returns the current spread value of the vertical offset that determines the placement of meshes above or below the surface.Return value
Spread value of the offset in units.void setOrientation(int orientation)
Sets a value indicating whether meshes should be oriented along the normals of the ground (either the terrain or a mesh set as a parent node).Arguments
- int orientation - Positive number to enable orientation; 0 to disable.
int getOrientation()
Returns a value indicating whether meshes are oriented along the normals of the ground (either the terrain or a mesh set as a parent node).Return value
1 if orientation is enabled; otherwise, 0.void setSeed(int seed)
Sets the seed for pseudo-random positioning of meshes.Arguments
- int seed - Number used to initialize a pseudo-random sequence. If a negative value is provided, 0 will be used instead.
int getSeed()
Returns the seed used for pseudo-random positioning of meshes.Return value
Number used to initialize a pseudo-random sequence.void setSizeX(float sizex)
Sets the width of the mesh clutter along the X-coordinate.Arguments
- float sizex - X-coordinate width in units. If a negative value is provided, 0 will be used instead.
float getSizeX()
Returns the current width of the mesh clutter along the X-coordinate.Return value
X-coordinate width in units.void setSizeY(float sizey)
Sets the length of the mesh clutter along the Y-coordinate.Arguments
- float sizey - Y-coordinate length in units. If a negative value is provided, 0 will be used instead.
float getSizeY()
Returns the current length of the mesh clutter along the Y-coordinate.Return value
Y-coordinate length in units.int getSpawnCount()
Returns the number of cells to be generated.Return value
Number of cells to be generated if the scene generation is not completed; otherwise, 0.void setStep(float step)
Sets the step for cells used to render mesh clutter.Arguments
- float step - Step for clutter cells in units.
float getStep()
Returns the step for cells used to render meshes scattered by the mesh clutter.Return value
Step for clutter cells in units.const char * getSurfaceTargetName(int surface, int target)
Returns the name of a given surface target.Arguments
- int surface - Surface number.
- int target - Target number.
Return value
Target name.void setThreshold(float threshold)
Sets the density threshold (for a mask) starting from which meshes are rendered if placed dense enough.Arguments
- float threshold - Density threshold. The provided value will be clipped in range [0;1].
float getThreshold()
Returns the current density threshold (for a mask) starting from which meshes are rendered if placed dense enough.Return value
Density threshold.void setVisibleDistance(float distance)
Sets the distance up to which meshes scattered by the mesh clutter will be rendered.Arguments
- float distance - Distance of visibility for meshes in units. If a negative value is provided, 0 will be used instead.
float getVisibleDistance()
Returns the current distance up to which meshes scattered by the mesh clutter are rendered.Return value
Distance of visibility for meshes in units.int createMesh(const char * name, int unique = 0)
Creates the clutter mesh with the specified parameters.Arguments
- const char * name - Path to the mesh file.
- int unique - When you create several objects out of a single .mesh file, the instance of the mesh geometry is created. If you then change the source geometry, its instances will be changed as well. To avoid this, set the unique flag to 1, so a copy of the mesh geometry will be created and changes won't be applied.
Return value
1 if the mesh is created successfully; otherwise, 0.int findSurfaceTarget(const char * name, int surface)
Searches for a surface target with a given name.Arguments
- const char * name - Target name.
- int surface - Surface number.
Return value
Target number if it exists; otherwise, -1.void flushMesh()
Flushes the mesh geometry into the video memory.int loadMesh(const char * name)
Loads a new mesh instead of the current mesh from the .mesh file. This function doesn't change the mesh name.Arguments
- const char * name - Path to the mesh file.
Return value
1 if the mesh is loaded successfully; otherwise, 0.int saveMesh(const char * name)
Saves the mesh into a file.Arguments
- const char * name - Path to the mesh file.
Return value
1 if the mesh is saved successfully; otherwise, 0.static int type()
Returns the type of ObjectMeshStatic.Return value
ObjectMeshStatic type identifier.Last update: 20.10.2017
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