The specific variables that are used depends on the context that the expression language is being used in. A common convention we use is to use the following variables in different contexts. These are just examples. Usually the developer of the software using expressions will register the acceptable variables with autocomplete help so that when you type $ in the expression editor a list of acceptable variables popup.
Image Variables
Surface Shading or Texturing Activities
Local Variables
Local variables can be defined at the start of the expression:
External variables can also be overridden by local assignment. This can be useful to scale the noise frequency for instance:
float clamp ( float x, float lo, float hi ) - constrain x to range [lo, hi]
float compress ( float x, float lo, float hi )
float expand ( float x, float lo, float hi )
float contrast ( float x, float c )
float invert ( float x ) - Invert the value. Defined as 1-x.
float remap ( float x, float source, float range, float falloff, int interp )
color saturate ( color x, float amt )
color hsi ( color x, float h, float s, float i, float map=1 )
color midhsi ( color x, float h, float s, float i, float map, float falloff=1, int interp=0 )
color rgbtohsl ( color rgb )
color hsltorgb ( color hsl )
float bias ( float x, float b)
float gamma ( float x, float g) - pow(x, 1/g)
float fit ( float x, float a1, float b1, float a2, float b2 )
float mix ( float a, float b, float alpha )
float boxstep ( float x, float a )
float gaussstep ( float x, float a, float b )
float linearstep ( float x, float a, float b )
float smoothstep ( float x, float a, float b )
float rand ( [float min, float max], [float seed] )
float hash ( float seed1, [float seed2, ...] )
float cellnoise ( vector v ) float cellnoise1 ( float x )
float cellnoise2 ( float x, float y )
float cellnoise3 ( float x, float y, float z )
color ccellnoise ( vector v ) - color cellnoise
float noise ( vector v )
float noise ( float x, float y )
float noise ( float x, float y, float z )
float noise ( float x, float y, float z, float w )
color cnoise ( vector v) - color noise
float snoise ( vector v) - signed noise w/ range -1 to 1.
vector vnoise (vector v ) - signed vector noise
color cnoise4 ( vector v, float t) - color noise
float snoise4 ( vector v, float t) - signed noise w/ range -1 to 1.
vector vnoise4 (vector v, float t ) - signed vector noise
float pnoise ( vector v, vector period ) - periodic noise
float perlin ( vector v )
color cperlin ( vector v) - color noise
float sperlin ( vector v) - signed noise w/ range -1 to 1.
vector vperlin (vector v ) - signed vector noise
float fbm ( vector v, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
color cfbm ( vector v, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
vector vfbm ( vector v, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
float fbm4 ( vector v, float time, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
color cfbm4 ( vector v, float time, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
vector vfbm4 ( vector v, float time, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
float turbulence ( vector v, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
color cturbulence ( vector v, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
vector vturbulence ( vector v, int octaves = 6, float lacunarity = 2, float gain = 0.5 )
float voronoi ( vector v, int type = 1, float jitter = 0.5, float fbmScale = 0, int fbmOctaves = 4, float fbmLacunarity = 2, float fbmGain = 0.5)
color cvoronoi ( vector v, int type = 1, float jitter = 0.5, float fbmScale = 0, int fbmOctaves = 4, float fbmLacunarity = 2, float fbmGain = 0.5)
vector pvoronoi ( vector v, float jitter = 0.5, float fbmScale = 0, int fbmOctaves = 4, float fbmLacunarity = 2, float fbmGain = 0.5)
int cycle ( int index, int loRange, int hiRange )
int pick ( float index, int loRange, int hiRange, [float weights, ...] )
float choose ( float index, float choice1, float choice2, [...] )
float wchoose ( float index, float choice1, float weight1, float choice2, float weight2, [...] )
Examples:
Note: the filename for the map and projmap functions can specify an optional format-arg which will be inserted into the filename as indicated in the examples below:
float PI = 3.14159...
float E = 2.71828...
float abs ( float x) - absolute value of x
float max ( float a, float b ) - greater of a and b
float min ( float a, float b ) - lesser of a and b
float fmod ( float x, float y) - remainder of x / y (also available as ' % ' operator)
float cbrt ( float x ) - cube root
float sqrt ( float x ) - square root
float ceil ( float x ) - next higher integer
float floor ( float x ) - next lower integer
float round ( float x ) - nearest integer
float trunc ( float x ) - nearest integer towards zero
float exp ( float x ) - E raised to the x power
float log ( float x ) - natural logarithm
float log10 ( float x ) - base 10 logarithm
float pow ( float x, float y ) - x to the y power (also available as ' ^ ' operator)
float acos ( float x ) - arc cosine
float asin ( float x ) - arc sine
float atan ( float x ) - arc tangent
float atan2 ( float y, float x) - arc tangent of y/x between -PI and PI
float cos ( float x ) - cosine
float sin ( float x ) - sine
float tan ( float x ) - tangent
float acosd ( float x ) - arc cosine in degrees
float asind ( float x ) - arc sine in degrees
float atand ( float x ) - arc tangent in degrees
float atan2d ( float y, float x ) - arc tangent in degrees of y/x between -180 and 180
float cosd ( float x ) - cosine in degrees
float sind ( float x ) - sine in degrees
float tand ( float x ) - tangent in degrees
float acosh ( float x ) - hyperbolic arc cosine
float asinh ( float x ) - hyperbolic arc sine
float atanh ( float x ) - hyperbolic arc tangent
float cosh ( float x ) - hyperbolic cosine
float sinh ( float x ) - hyperbolic sine
float tanh ( float x ) - hyperbolic tangent
float deg ( float x ) - radians to degrees
float rad ( float x ) - degrees to radians
float hypot ( float x, float y ) - length of 2d vector (x,y)
float angle ( vector a, vector b ) - angle between two vectors (in radians)
vector cross ( vector a, vector b ) - vector cross product
float dist (vectA[0], vectA[1], vectA[2], vectB[0], vectB[1], vectB[2]) - distance between two points
Vector Support
float dot ( vector a, vector b) - vector dot product
float length ( vector v ) - length of vector
vector norm ( vector v ) - vector scaled to unit length
vector ortho ( vector a, vector b ) - vector orthographic to two vectors
vector up ( vector v, vector up ) - rotates v such that the Y axis points in the given up direction
vector rotate ( vector v, vector axis, float angle ) - rotates v around axis by given angle (in radians)
Vectors (points, colors, or 3d vectors) may be intermixed with scalars (simple float values). If a scalar is used in a vector context, it is replicated into the three components (e.g. 0.5 becomes [0.5, 0.5, 0.5] ). If a vector is used in a scalar context, only the first component is used.
One of the benefits of this is that all the functions that are defined to work with scalars automatically extend to vectors. For instance, pick, choose, cycle, spline, etc., will work just fine with vectors.
Arithmetic operators such as +, *, etc., and scalar functions are applied component-wise to vectors. For example, applying the gamma function to a map adjusts the gamma of all three color channels.
Interpolation of parameter values to a set of control points is governed by the following functions.
color ccurve(float param,float pos0,color val0,int interp0,float pos1,color val1,int interp1,[...])
Interpolates color ramp given by control points at 'param'. Control points are specified by triples of parameters pos_i, val_i, and interp_i. Interpolation codes are 0 - none, 1 - linear, 2 - smooth, 3 - spline, 4 - monotone (non-oscillating) spline
float curve(float param,float pos0,float val0,int interp0,float pos1,float val1,int interp1,[...])
Interpolates a 1D ramp defined by control points at 'param'. Control points are specified by triples of parameters pos_i, val_i, and interp_i. Interpolation codes are 0 - none, 1 - linear, 2 - smooth, 3 - spline, 4 - monotone (non-oscillating) spline
float spline(float param,float y1,float y2,float y3,float y4,[...])
Interpolates a set of values to the parameter specified where y1, ..., yn are distributed evenly from [0...1]
void printf(string format,[param0,param1,...])
Prints a string to stdout that is formatted as given. Formatting parameters possible are %f for float (takes first component of vector argument) or %v for vector. For example if you wrote printf("test %f %v",[1,2,3],[4,5,6]); you would get "test 1 [4,5,6]".
[ a, b, c ] [ n ] | vector constructor vector component access - n must be 0, 1, or 2 (e.g. $P[0]) |
^ | exponentiation (same as pow function) |
! | logical NOT |
~ | inversion (i.e. ~$A gives the same result as 1-$A) |
* / % | multiply, divide, modulus (same as fmod function) |
+ - | add, subtract |
< > <= >= | comparison (only uses [0] component of vectors) |
== != | equality, inequality |
&& | logical AND |
|| | logical OR |
? : | conditional (like if-then-else, e.g. $u < .5 ? 0 : 1) |
-> | apply - The function on the right of the arrow is applied to the expression on the left. Examples: $Cs -> contrast(.7) -> clamp(0.2, 0.8) $u -> hsi(20, 1.2, 1, $Cs -> gamma(1.2)) |
Besides the basic assignment statement "$foo=$bar;" you can also do operator assignments such as "$foo+=$bar;" which is equivalent to "$foo=$foo+$bar;". Additionally there are, +=, -=, /=, %=, *=, ^=.
Any characters following a '#' to the end of the line are ignored and may be used as a comment, or for "commenting out" part of the expression. For a multi-line expression, each line may have its own comment.
Custom fuctions may be written in C++ and loaded as one or more dynamic plugins.