Reference:Functions.inc
This include file contains interfaces to internal functions as well as several predefined functions. The ID's used to access the internal functions through calls to internal(XX), are not guaranteed to stay the same between POV-Ray versions, so users are encouraged to use the functions declared here.
The number of required parameters and what they control are also given in the include file, this chapter gives more information. For starter
values of the parameters, see the ~scenes/incdemo/i_internal.pov
demo file.
Syntax to be used:
#include "functions.inc" isosurface { function { f_torus_gumdrop(x,y,z, P0) } ... } pigment { function { f_cross_ellipsoids(x,y,z, P0, P1, P2, P3) } COLOR_MAP ... }
Some special parameters are found in several of these functions. These are described in the next section and later referred to as Cross section type, Field Strength, Field Limit, SOR parameters.
Common Parameters
Cross Section Type
In the helixes and spiral functions, the 9th parameter is the cross section type.
Some shapes are:
0
: square0.0 to 1.0
: rounded squares1
: circle1.0 to 2.0
: rounded diamonds2
: diamond2.0 to 3.0
: partially concave diamonds3
: concave diamond
Field Strength
The numerical value at a point in space generated by the function is multiplied by the Field Strength. The set of points where the function evaluates to zero are unaffected by any positive value of this parameter, so if you are just using the function on its own with threshold = 0, the generated surface is still the same.
In some cases, the field strength has a considerable effect on the speed and accuracy of rendering the surface. In general, increasing the field strength speeds up the rendering, but if you set the value too high the surface starts to break up and may disappear completely.
Setting the field strength to a negative value produces the inverse of the surface, like making the function negative.
Field Limit
This will not make any difference to the generated surface if you are using threshold that is within the field limit (and will kill the surface completely if the threshold is greater than the field limit). However, it may make a huge difference to the rendering times.
If you use the function to generate a pigment, then all points that are a long way from the surface will have the same color, the color that corresponds to the numerical value of the field limit.
SOR Switch
If greater than zero, the curve is swept out as a surface of revolution (SOR). If the value is zero or negative, the curve is extruded linearly in the Z direction.
SOR Offset
If the SOR switch is on, then the curve is shifted this distance in the X direction before being swept out.
SOR Angle
If the SOR switch is on, then the curve is rotated this number of degrees about the Z axis before being swept out.
Invert Isosurface
Sometimes, when you render a surface, you may find that you get only the shape of the container. This could be caused by the fact that some of the build in functions are defined inside out.
We can invert the isosurface by negating the whole function: -(function) - threshold
Internal Functions
Here is a list of the internal functions in the order they appear in the functions.inc include file
f_algbr_cyl1(x,y,z, P0, P1, P2, P3, P4)
: An algebraic cylinder is what you get if you take any 2d curve and plot it in 3d.
The 2d curve is simply extruded along the third axis, in this case the z axis. With the SOR Switch switched on, the figure-of-eight curve
will be rotated around the Y axis instead of being extruded along the Z axis.
P0
: Field StrengthP1
: Field LimitP2
: SOR SwitchP3
: SOR OffsetP4
: SOR Angle
f_algbr_cyl2(x,y,z, P0, P1, P2, P3, P4)
: An algebraic cylinder is what you
get if you take any 2d curve and plot it in 3d.
The 2d curve is simply extruded along the third axis, in this case the z axis.With the SOR Switch switched on, the cross section curve will
be rotated around the Y axis instead of being extruded along the Z axis.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Field LimitP2
: SOR SwitchP3
: SOR OffsetP4
: SOR Angle
f_algbr_cyl3(x,y,z, P0, P1, P2, P3, P4)
: An algebraic cylinder is what you get
if you take any 2d curve and plot it in 3d. The 2d curve
is simply extruded along the third axis, in this case the Z axis. With the SOR Switch switched on, the cross section curve will be rotated
around the Y axis instead of being extruded along the Z axis.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Field LimitP2
: SOR SwitchP3
: SOR OffsetP4
: SOR Angle
f_algbr_cyl4(x,y,z, P0, P1, P2, P3, P4)
: An algebraic cylinder is what you get
if you take any 2d curve and plot it in 3d. The 2d curve
is simply extruded along the third axis, in this case the z axis. With the SOR Switch switched on, the cross section curve will be rotated
around the Y axis instead of being extruded along the Z axis.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Field LimitP2
: SOR SwitchP3
: SOR OffsetP4
: SOR Angle
f_bicorn(x,y,z, P0, P1)
: The surface is a surface of revolution.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Scale. The mathematics of this surface suggest that the shape should be different for different values of this parameter. In practice the difference in shape is hard to spot. Setting the scale to 3 gives a surface with a radius of about 1 unit
f_bifolia(x,y,z, P0, P1)
: The bifolia surface looks something like the top part of
a a paraboloid bounded below by another paraboloid.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Scale. The surface is always the same shape. Changing this parameter has the same effect as adding a scale modifier. Setting the scale to 1 gives a surface with a radius of about 1 unit
f_blob(x,y,z, P0, P1, P2, P3, P4)
: This function generates blobs that are
similar to a CSG blob with two spherical components. This function only seems to work
with negative threshold settings.
P0
: X distance between the two componentsP1
: Blob strength of component 1P2
: Inverse blob radius of component 1P3
: Blob strength of component 2P4
: Inverse blob radius of component 2
f_blob2(x,y,z, P0, P1, P2, P3)
: The surface is similar to a CSG blob
with two spherical components.
P0
: Separation. One blob component is at the origin, and the other is this distance away on the X axisP1
: Inverse size. Increase this to decrease the size of the surfaceP2
: Blob strengthP3
: Threshold. Setting this parameter to 1 and the threshold to zero has exactly the same effect as setting this parameter to zero and the threshold to -1
f_boy_surface(x,y,z, P0, P1)
: For this surface, it helps if the field strength
is set low, otherwise the surface has a tendency to break up or disappear entirely. This has
the side effect of making the rendering times extremely long.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Scale. The surface is always the same shape. Changing this parameter has the same effect as adding a scale modifier
f_comma(x,y,z, P0)
: The comma surface is very much like a comma-shape.
P0
: Scale
f_cross_ellipsoids(x,y,z, P0, P1, P2, P3)
: The cross ellipsoids surface is
like the union of three crossed ellipsoids, one oriented along each axis.
P0
: Eccentricity. When less than 1, the ellipsoids are oblate, when greater than 1 the ellipsoids are prolate, when zero the ellipsoids are spherical (and hence the whole surface is a sphere)P1
: Inverse size. Increase this to decrease the size of the surfaceP2
: Diameter. Increase this to increase the size of the ellipsoidsP3
: Threshold. Setting this parameter to 1 and the threshold to zero has exactly the same effect as setting this parameter to zero and the threshold to -1
f_crossed_trough(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_cubic_saddle(x,y,z, P0)
: For this surface, it helps if the field strength is set quite low, otherwise the surface has a
tendency to break up or disappear entirely.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_cushion(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_devils_curve(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_devils_curve_2d(x,y,z, P0, P1, P2, P3, P4, P5)
: The f_devils_curve_2d
curve can be
extruded along the z axis, or using the SOR parameters it can be made into a surface of revolution.
The X and Y factors control the size of the central feature.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: X factorP2
: Y factorP3
: SOR SwitchP4
: SOR OffsetP5
: SOR Angle
f_dupin_cyclid(x,y,z, P0, P1, P2, P3, P4, P5)
:
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Major radius of torusP2
: Minor radius of torusP3
: X displacement of torusP4
: Y displacement of torusP5
: Radius of inversion
f_ellipsoid(x,y,z, P0, P1, P2)
: f_ellipsoid
generates spheres and ellipsoids. Needs threshold 1
.
Setting these scaling parameters to 1/n gives exactly the same effect as performing a scale operation to increase the scaling by n
in the corresponding direction.
P0
: X scale (inverse)P1
: Y scale (inverse)P2
: Z scale (inverse)
f_enneper(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_flange_cover(x,y,z, P0, P1, P2, P3)
:
P0
: Spikiness. Set this to very low values to increase the spikes. Set it to 1 and you get a sphereP1
: Inverse size. Increase this to decrease the size of the surface. (The other parameters also drastically affect the size, but this parameter has no other effects)P2
: Flange. Increase this to increase the flanges that appear between the spikes. Set it to 1 for no flangesP3
: Threshold. Setting this parameter to 1 and the threshold to zero has exactly the same effect as setting this parameter to zero and the threshold to -1
f_folium_surface(x,y,z, P0, P1, P2)
: A folium surface looks something like a paraboloid glued to a plane.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Neck width factor - the larger you set this, the narrower the neck where the paraboloid meets the planeP2
: Divergence - the higher you set this value, the wider the paraboloid gets
f_folium_surface_2d(x,y,z, P0, P1, P2, P3, P4, P5)
: The f_folium_surface_2d
curve can be
rotated around the X axis to generate the same 3d surface as the f_folium_surface
, or it can be extruded
in the Z direction (by switching the SOR switch off)
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Neck width factor - same as the 3d surface if you are revolving it around the Y axisP2
: Divergence - same as the 3d surface if you are revolving it around the Y axisP3
: SOR SwitchP4
: SOR OffsetP5
: SOR Angle
f_glob(x,y,z, P0)
: One part of this surface would actually go off to
infinity if it were not restricted by the contained_by shape.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_heart(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_helical_torus(x,y,z, P0, P1, P2, P3, P4, P5, P6, P7, P8, P9)
: With some sets of parameters, it looks like a torus with a
helical winding around it. The
winding optionally has grooves around the outside.
P0
: Major radiusP1
: Number of winding loopsP2
: Twistiness of winding. When zero, each winding loop is separate. When set to one, each loop twists into the next one. When set to two, each loop twists into the one after nextP3
: Fatness of winding?P4
: Threshold. Setting this parameter to 1 and the threshold to zero has s similar effect as setting this parameter to zero and the threshold to 1P5
: Negative minor radius? Reducing this parameter increases the minor radius of the central torus. Increasing it can make the torus disappear and be replaced by a vertical column. The value at which the surface switches from one form to the other depends on several other parametersP6
: Another fatness of winding control?P7
: Groove period. Increase this for more groovesP8
: Groove amplitude. Increase this for deeper groovesP9
: Groove phase. Set this to zero for symmetrical grooves
f_helix1(x,y,z, P0, P1, P2, P3, P4, P5, P6)
:
P0
: Number of helixes - e.g. 2 for a double helixP1
: Period - is related to the number of turns per unit lengthP2
: Minor radius (major radius > minor radius)P3
: Major radiusP4
: Shape parameter. If this is greater than 1 then the tube becomes fatter in the y directionP5
: Cross section typeP6
: Cross section rotation angle (degrees)
f_helix2(x,y,z, P0, P1, P2, P3, P4, P5, P6)
: Needs a negated function
P0
: Not usedP1
: Period - is related to the number of turns per unit lengthP2
: Minor radius (minor radius > major radius)P3
: Major radiusP4
: Not usedP5
: Cross section typeP6
: Cross section rotation angle (degrees)
f_hex_x(x,y,z, P0)
: This creates a grid of hexagonal cylinders stretching along
the z-axis. The fatness is controlled
by the threshold value. When this value equals 0.8660254 or cos(30) the sides will touch, because
this is the distance between centers. Negating the function will inverse the surface and create a
honey-comb structure. This function is also useful as pigment function.
P0
: No effect (but the syntax requires at least one parameter)
f_hex_y(x,y,z, P0)
: This is function forms a lattice of infinite boxes
stretching along the z-axis. The fatness is
controlled by the threshold value. These boxes are rotated 60 degrees around centers, which
are 0.8660254 or cos(30) away from each other. This function is also useful as pigment function.
P0
: No effect (but the syntax requires at least one parameter)
f_hetero_mf(x,y,z, P0, P1, P2, P3, P4, P5)
: f_hetero_mf (x,0,z)
makes multifractal height fields and patterns
of 1/f noise. Multifractal refers to their characteristic of having a fractal dimension which varies with
altitude. Built from summing noise of a number of frequencies, the hetero_mf parameters determine how many, and which frequencies are to be
summed. An advantage to using these instead of a height_field {} from an image (a number of height field programs output multifractal types
of images) is that the hetero_mf function domain extends arbitrarily far in the x and z directions so huge landscapes can be made without
losing resolution or having to tile a height field. Other functions of interest are f_ridged_mf
and f_ridge
.
P0
: H is the negative of the exponent of the basis noise frequencies used in building these functions (each frequency f's amplitude is weighted by the factor f - H ). In landscapes, and many natural forms, the amplitude of high frequency contributions are usually less than the lower frequencies. When H is 1, the fractalization is relatively smooth (1/f noise). As H nears 0, the high frequencies contribute equally with low frequencies as in white noise.P1
: Lacunarity is the multiplier used to get from one octave to the next. This parameter affects the size of the frequency gaps in the pattern. Make this greater than 1.0P2
: Octaves is the number of different frequencies added to the fractal. Each Octave frequency is the previous one multiplied by Lacunarity, so that using a large number of octaves can get into very high frequencies very quickly.P3
: Offset is the base altitude (sea level) used for the heterogeneous scalingP4
: T scales the heterogeneity of the fractal. T=0 gives straight 1/f (no heterogeneous scaling). T=1 suppresses higher frequencies at lower altitudesP5
: Generator type used to generate the noise3d. 0, 1, 2 and 3 are legal values.
f_hunt_surface(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_hyperbolic_torus(x,y,z, P0, P1, P2)
:
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Major radius: separation between the centers of the tubes at the closest pointP2
: Minor radius: thickness of the tubes at the closest point
f_isect_ellipsoids(x,y,z, P0, P1, P2, P3)
: The isect ellipsoids surface is like the
intersection of three crossed ellipsoids, one oriented along each axis.
P0
: Eccentricity. When less than 1, the ellipsoids are oblate, when greater than 1 the ellipsoids are prolate, when zero the ellipsoids are spherical (and hence the whole surface is a sphere)P1
: Inverse size. Increase this to decrease the size of the surfaceP2
: Diameter. Increase this to increase the size of the ellipsoidsP3
: Threshold. Setting this parameter to 1 and the threshold to zero has exactly the same effect as setting this parameter to zero and the threshold to -1
f_kampyle_of_eudoxus(x,y,z, P0, P1, P2)
: The kampyle of eudoxus is like two infinite planes with a dimple at the
center.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Dimple: When zero, the two dimples punch right through and meet at the center. Non-zero values give less dimplingP2
: Closeness: Higher values make the two planes become closer
f_kampyle_of_eudoxus_2d(x,y,z, P0, P1, P2, P3, P4, P5)
: The 2d curve that generates the above surface can be extruded in the
Z direction or rotated about various axes by using the SOR parameters.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Dimple: When zero, the two dimples punch right through and meet at the center. Non-zero values give less dimplingP2
: Closeness: Higher values make the two planes become closerP3
: SOR SwitchP4
: SOR OffsetP5
: SOR Angle
f_klein_bottle(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_kummer_surface_v1(x,y,z, P0)
: The Kummer surface consists of a collection of radiating rods.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_kummer_surface_v2(x,y,z, P0, P1, P2, P3)
: Version 2 of the kummer surface only looks like radiating rods when the
parameters are set to particular negative values. For positive values it tends to look rather like a superellipsoid.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Rod width (negative): Setting this parameter to larger negative values increases the diameter of the rodsP2
: Divergence (negative): Setting this number to -1 causes the rods to become approximately cylindrical. Larger negative values cause the rods to become fatter further from the origin. Smaller negative numbers cause the rods to become narrower away from the origin, and have a finite lengthP3
: Influences the length of half of the rods.Changing the sign affects the other half of the rods. 0 has no effect
f_lemniscate_of_gerono(x,y,z, P0)
: The Lemniscate of Gerono surface is an hourglass shape, or two teardrops with
their ends connected.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_lemniscate_of_gerono_2d(x,y,z, P0, P1, P2, P3, P4, P5)
: The 2d version of the Lemniscate can be extruded in the Z
direction, or used as a surface of revolution to generate the equivalent of the 3d version, or revolved in different ways.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Size: increasing this makes the 2d curve larger and less roundedP2
: Width: increasing this makes the 2d curve fatterP3
: SOR SwitchP4
: SOR OffsetP5
: SOR Angle
f_mesh1(x,y,z, P0, P1, P2, P3, P4)
: The overall thickness of the threads is controlled by the isosurface threshold, not
by a parameter. If you render a mesh1 with zero threshold, the threads have zero thickness and are therefore invisible. Parameters P2 and P4
control the shape of the thread relative to this threshold parameter.
P0
: Distance between neighboring threads in the x directionP1
: Distance between neighboring threads in the z directionP2
: Relative thickness in the x and z directionsP3
: Amplitude of the weaving effect. Set to zero for a flat gridP4
: Relative thickness in the y direction
f_mitre(x,y,z, P0)
: The Mitre surface looks a bit like an ellipsoid which has been nipped at each end with a pair
of sharp nosed pliers.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_nodal_cubic(x,y,z, P0)
: The Nodal Cubic is something like what you would get if you were to extrude the Stophid2D
curve along the X axis and then lean it over.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_noise3d(x,y,z)
:
f_noise_generator(x,y,z, P0)
:
P0
: Noise generator number
f_odd(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_ovals_of_cassini(x,y,z, P0, P1, P2, P3)
: The Ovals of Cassini are a generalization of the torus shape.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Major radius - like the major radius of a torusP2
: Filling. Set this to zero, and you get a torus. Set this to a higher value and the hole in the middle starts to heal up. Set it even higher and you get an ellipsoid with a dimpleP3
: Thickness. The higher you set this value, the plumper is the result
f_paraboloid(x,y,z, P0)
: This paraboloid is the surface of revolution that you get if you rotate a parabola about the Y
axis.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_parabolic_torus(x,y,z, P0, P1, P2)
:
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Major radiusP2
: Minor radius
f_ph(x,y,z)
: When used alone, the PH function gives a surface that consists of all points that are at a particular
latitude, i.e. a cone. If you use a threshold of zero (the default) this gives a cone of width zero, which is invisible. Also look at
f_th
and f_r
f_pillow(x,y,z, P0)
:
P0
: Field Strength
f_piriform(x,y,z, P0)
: The piriform surface looks rather like half a lemniscate.
P0
: Field Strength
f_piriform_2d(x,y,z, P0, P1, P2, P3, P4, P5, P6)
: The 2d version of the Piriform can be extruded in the Z
direction, or used as a surface of revolution to generate the equivalent of the 3d version.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Size factor 1: increasing this makes the curve largerP2
: Size factor 2: making this less negative makes the curve larger but also thinnerP3
: Fatness: increasing this makes the curve fatterP4
: SOR SwitchP5
: SOR OffsetP6
: SOR Angle
f_poly4(x,y,z, P0, P1, P2, P3, P4)
: This f_poly4
can be used to generate the surface of revolution of any
polynomial up to degree 4. To put it another way: If we call the parameters A, B, C, D, E; then this function generates the surface of
revolution formed by revolving x = A + By + Cy2 + Dy3 + Ey4
around the Y axis.
P0
: ConstantP1
: Y coefficientP2
: Y2 coefficientP3
: Y3 coefficientP4
: Y4 coefficient
f_polytubes(x,y,z, P0, P1, P2, P3, P4, P5)
: The Polytubes surface consists of a number of tubes. Each tube follows
a 2d curve which is specified by a polynomial of degree 4 or less. If we look at the parameters, then this function generates P0
tubes which all follow the equation x = P1 + P2y + P3y2 + P4y3 + P5y4
arranged around the Y axis. This function needs a
positive threshold (fatness of the tubes).
P0
: Number of tubesP1
: ConstantP2
: Y coefficientP3
: Y2 coefficientP4
: Y3 coefficientP5
: Y4 coefficient
f_quantum(x,y,z, P0)
: It resembles the shape of the electron density cloud for one of the d orbitals.
P0
: Not used, but required
f_quartic_paraboloid(x,y,z, P0)
: The Quartic Paraboloid is similar to a paraboloid, but has a squarer shape.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_quartic_saddle(x,y,z, P0)
: The Quartic saddle is similar to a saddle, but has a squarer shape.
P0
: Field Strength
f_quartic_cylinder(x,y,z, P0, P1, P2)
: The Quartic cylinder looks a bit like a cylinder that is swallowed an
egg.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Diameter of the eggP2
: Controls the width of the tube and the vertical scale of the egg
f_r(x,y,z)
: When used alone, the R function gives a surface that consists of all the points that are a specific
distance (threshold value) from the origin, i.e. a sphere. Also look at f_ph
and f_th
f_ridge(x,y,z, P0, P1, P2, P3, P4, P5)
: This function is mainly intended for modifying other surfaces as you might use a
height field or to use as pigment function. Other functions of interest are f_hetero_mf
and f_ridged_mf
.
P0
: LambdaP1
: OctavesP2
: OmegaP3
: OffsetP4
: RidgeP5
: Generator type used to generate the noise3d. 0, 1, 2 and 3 are legal values.
f_ridged_mf(x,y,z, P0, P1, P2, P3, P4, P5)
: The Ridged Multifractal surface can be used to create multifractal
height fields and patterns. Multifractal refers to their characteristic of having a fractal dimension which varies with altitude.
They are built from summing noise of a number of frequencies. The f_ridged_mf parameters determine how many, and which frequencies are to be
summed, and how the different frequencies are weighted in the sum.
An advantage to using these instead of a height_field{}
from an image is that the ridged_mf function domain extends
arbitrarily far in the x and z directions so huge landscapes can be made without losing resolution or having to tile a height field. Other
functions of interest are f_hetero_mf
and f_ridge
.
P0
: H is the negative of the exponent of the basis noise frequencies used in building these functions (each frequency f's amplitude is weighted by the factor fE- H ). When H is 1, the fractalization is relatively smooth. As H nears 0, the high frequencies contribute equally with low frequenciesP1
: Lacunarity is the multiplier used to get from one octave to the next in the fractalization. This parameter affects the size of the frequency gaps in the pattern. (Use values greater than 1.0)P2
: Octaves is the number of different frequencies added to the fractal. Each octave frequency is the previous one multiplied by Lacunarity. So, using a large number of octaves can get into very high frequencies very quicklyP3
: Offset gives a fractal whose fractal dimension changes from altitude to altitude. The high frequencies at low altitudes are more damped than at higher altitudes, so that lower altitudes are smoother than higher areasP4
: Gain weights the successive contributions to the accumulated fractal result to make creases stick up as ridgesP5
: Generator type used to generate the noise3d. 0, 1, 2 and 3 are legal values.
f_rounded_box(x,y,z, P0, P1, P2, P3)
: The Rounded Box is defined in a cube from <-1, -1, -1> to <1, 1, 1>. By
changing the Scale parameters, the size can be adjusted, without affecting the Radius of curvature.
P0
: Radius of curvature. Zero gives square corners, 0.1 gives corners that matchsphere {0, 0.1}
P1
: Scale xP2
: Scale yP3
: Scale z
f_sphere(x,y,z, P0)
:
P0
: radius of the sphere
f_spikes(x,y,z, P0, P1, P2, P3, P4)
:
P0
: Spikiness. Set this to very low values to increase the spikes. Set it to 1 and you get a sphereP1
: Hollowness. Increasing this causes the sides to bend in moreP2
: Size. Increasing this increases the size of the objectP3
: Roundness. This parameter has a subtle effect on the roundness of the spikesP4
: Fatness. Increasing this makes the spikes fatter
f_spikes_2d(x,y,z, P0, P1, P2, P3)
:
P0
: Height of central spikeP1
: Frequency of spikes in the X directionP2
: Frequency of spikes in the Z directionP3
: Rate at which the spikes reduce as you move away from the center
f_spiral(x,y,z, P0, P1, P2, P3, P4, P5)
:
P0
: Distance between windingsP1
: ThicknessP2
: Outer diameter of the spiral. The surface behaves as if it is contained_by a sphere of this diameterP3
: Not usedP4
: Not usedP5
: Cross section type
f_steiners_roman(x,y,z, P0)
: The Steiners Roman is composed of four identical triangular pads which together make
up a sort of rounded tetrahedron. There are creases along the X, Y and Z axes where the pads meet.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_strophoid(x,y,z, P0, P1, P2, P3)
: The Strophoid is like an infinite plane with a bulb sticking out of it.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Size of bulb. Larger values give larger bulbs. Negative values give a bulb on the other side of the planeP2
: Sharpness. When zero, the bulb is like a sphere that just touches the plane. When positive, there is a crossover point. When negative the bulb simply bulges out of the plane like a pimpleP3
: Flatness. Higher values make the top end of the bulb fatter
f_strophoid_2d(x,y,z, P0, P1, P2, P3, P4, P5, P6)
: The 2d strophoid curve can be extruded in the Z direction or rotated
about various axes by using the SOR parameters.
P0
: Field StrengthP1
: Size of bulb. Larger values give larger bulbs. Negative values give a bulb on the other side of the planeP2
: Sharpness. When zero, the bulb is like a sphere that just touches the plane. When positive, there is a crossover point. When negative the bulb simply bulges out of the plane like a pimpleP3
: Fatness. Higher values make the top end of the bulb fatterP4
: SOR SwitchP5
: SOR OffsetP6
: SOR Angle
f_superellipsoid(x,y,z, P0, P1)
: Needs a negative field strength or a negated function.
P0
: east-west exponentxP1
: north-south exponent
f_th(x,y,z)
: f_th()
is a function that is only useful when combined with other surfaces. It produces a value
which is equal to the theta angle, in radians, at any point. The theta angle is like the longitude coordinate on the Earth. It
stays the same as you move north or south, but varies from east to west. Also look at f_ph
and f_r
f_torus(x,y,z, P0, P1)
:
P0
: Major radiusP1
: Minor radius
f_torus2(x,y,z, P0, P1, P2)
: This is different from the f_torus function which just has the major and minor radii as
parameters.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Major radiusP2
: Minor radius
f_torus_gumdrop(x,y,z, P0)
: The Torus Gumdrop surface is something like a torus with a couple of gumdrops hanging
off the end.
P0
: Field Strength (Needs a negative field strength or a negated function)
f_umbrella(x,y,z, P0)
:
P0
: Field Strength (Needs a negative field strength or a negated function)
f_witch_of_agnesi(x,y,z, P0, P1, P2, P3, P4, P5)
: The Witch of Agnesi surface looks something like a witches
hat.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Controls the width of the spike. The height of the spike is always about 1 unit
f_witch_of_agnesi_2d(x,y,z, P0, P1, P2, P3, P4, P5)
: The 2d version of the Witch of Agnesi curve can be extruded in
the Z direction or rotated about various axes by use of the SOR parameters.
P0
: Field Strength (Needs a negative field strength or a negated function)P1
: Controls the size of the spikeP2
: Controls the height of the spikeP3
: SOR SwitchP4
: SOR OffsetP5
: SOR Angle
Pre defined functions
eval_pigment(Pigm, Vect)
: This macro evaluates the color of a pigment at a specific point. Some pigments require more
information than simply a point, slope pattern based pigments for example, and will not work with this macro. However, most pigments will
work fine.
Parameters:
Vect
= The point at which to evaluate the pigment.Pigm
= The pigment to evaluate.
f_snoise3d(x, y, z)
: Just like f_noise3d(), but returns values in the range [-1, 1].
f_sine_wave(val, amplitude, frequency)
: Turns a ramping waveform into a sine waveform.
f_scallop_wave(val, amplitude, frequency)
: Turns a ramping waveform into a scallop wave waveform.
Pattern functions
Predefined pattern functions, useful for building custom function patterns or performing displacement mapping on isosurfaces. Many of them are not really useful for these purposes, they are simply included for completeness.
Some are not implemented at all because they require special parameters that must be specified in the definition, or information that is not available to pattern functions. For this reason, you probably would want to define your own versions of these functions.
All of these functions take three parameters, the XYZ coordinates of the point to evaluate the pattern at.
f_agate(x, y, z)
f_boxed(x, y, z)
f_bozo(x, y, z)
f_brick(x, y, z)
f_bumps(x, y, z)
f_checker(x, y, z)
f_crackle(x, y, z)
- This pattern has many more options, this function uses the defaults.
f_cylindrical(x, y, z)
f_dents(x, y, z)
f_gradientX(x, y, z)
f_gradientY(x, y, z)
f_gradientZ(x, y, z)
f_granite(x, y, z)
f_hexagon(x, y, z)
f_leopard(x, y, z)
f_mandel(x, y, z)
- Only the basic mandel pattern is implemented, its variants and the other fractal patterns are not implemented.
f_marble(x, y, z)
f_onion(x, y, z)
f_planar(x, y, z)
f_radial(x, y, z)
f_ripples(x, y, z)
f_spherical(x, y, z)
f_spiral1(x, y, z)
f_spiral2(x, y, z)
f_spotted(x, y, z)
f_waves(x, y, z)
f_wood(x, y, z)
f_wrinkles(x, y, z)