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// To view a copy of this license, visit http://creativecommons.org/licenses/by-sa/3.0/ or send a
// letter to Creative Commons, 444 Castro Street, Suite 900, Mountain View, California, 94041, USA.
// Persistence of Vision Ray Tracer version 3.5 Include File
// File: math.inc
// Last updated: 2004.07.23
// Description: This file contains various math macros and functions
#ifndef(MATH_INC_TEMP)
#declare MATH_INC_TEMP = version;
#version 3.5;
#ifdef(View_POV_Include_Stack)
#debug "including math.inc\n"
#end
#include "functions.inc"
// --------------------------------------------------------
// Statistics macros: (some from variate.inc)
// --------------------------------------------------------
// Mean(rewritten, original from basemcr.inc by Margus Ramst)
#macro Mean(A)
#local N = dimension_size(A,1);
#local C = 0;
// (
// #while(C<N-1)
// A[C]+
// #local C=C+1;
// #end
// A[C])/N
#local V = 0;
#while(C < N)
#local V = V + A[C];
#local C=C+1;
#end
(V/N)
#end
// Standard deviation(rewritten, original from basemcr.inc by Margus Ramst)
#macro Std_Dev(A, M)
#local N = dimension_size(A,1);
#local C = 0;
// sqrt((
// #while(C<N-1)
// pow(A[C]-M,2)+
// #local C=C+1;
// #end
// pow(A[C]-M,2))/N)
#local V = 0;
#while(C < N)
#local V = V + pow(A[C] - M, 2);
#local C=C+1;
#end
sqrt(V/N)
#end
// Macros for statistical analysis
// Input: an array of values
// Output: a global array "StatisticsArray" is
// declared containing: N, Mean, Min, Max, StdDev
#macro GetStats(ValArr)
#local SquareSum=0; #local Sum=0;
#local Min=10e15; #local Max=-10e15;
#local N=dimension_size(ValArr,1);
#local I=0;
#while (I<N)
#local Val=ValArr[I];
#local Sum=Sum+Val;
#local SquareSum=SquareSum+(Val*Val);
#if (Val>Max)
#local Max=Val;
#end
#if (Val<Min)
#local Min=Val;
#end
#local I=I+1;
#end
#local Avg=Sum/N;
#local StdDev=sqrt((SquareSum/N)-Avg*Avg);
#debug concat("\nN = ",str(N,0,0),"\n")
#debug concat("Mean = ",str(Avg,0,-1),"\n")
#debug concat("Min = ",str(Min,0,-1),"\n")
#debug concat("Max = ",str(Max,0,-1),"\n")
#debug concat("StdDev = ",str(StdDev,0,-1),"\n")
#declare StatisticsArray=array[5]{N,Avg,Min,Max,StdDev}
#end
// Input: an array with values and the wanted amount of intervals / bins.
// Output: a global array "HistogramArray" is declared,
// it is a two dimensional array, the first value is the center
// of the interval / bin, the second the amount of values
// in that interval.
#macro Histogram(ValArr, Intervals)
GetStats(ValArr)
#local Min=StatisticsArray[2];
#local Max=StatisticsArray[3];
#local Intervals=int(Intervals);
#local Width=(Max-Min)/(Intervals);
#local HistArr=array[Intervals][2]
#local I=0;
#while(I<Intervals)
#local HistArr[I][0]=Min+Width*(I+0.5); // center of interval
#local HistArr[I][1]=0;
#local I=I+1;
#end
#local I=0;
#while (I<N) // 'put' the values into the right
#local Index=int((ValArr[I]-Min)/Width); // intervals and count them.
#if (Index>=Intervals)
#local Index=Index-1;
#end
#local HistArr[Index][1]=HistArr[Index][1]+1;
#local I=I+1;
#end
#declare HistogramArray=HistArr
#end
// --------------------------------------------------------
// Trig:
// --------------------------------------------------------
#declare sind = function (x) {sin(radians(x))}
#declare cosd = function (x) {cos(radians(x))}
#declare tand = function (x) {tan(radians(x))}
#declare asind = function (x) {degrees(asin(x))}
#declare acosd = function (x) {degrees(acos(x))}
#declare atand = function (x) {degrees(atan(x))}
#declare atan2d = function (x, y) {degrees(atan2(x, y))}
// --------------------------------------------------------
// Misc:
// --------------------------------------------------------
#declare max3 = function (x, y, z) {max(x,y,z)}
#declare min3 = function (x, y, z) {min(x,y,z)}
#declare even = function(x) {select(mod(x, 2), 0, 1, 0)}
#declare odd = function(x) {select(mod(x, 2), 1, 0, 1)}
// Squares the value
#declare f_sqr = function (x) {(x*x)}
// Returns the sign of a value
#declare sgn = function (x) {select(x,-1, 0, 1)}
//#declare sgn = function (x) {x/abs(x)}
// Range handling
// clips a number (x) to the range [Min, Max] ([y, z]). Values above Max return Max,
// below Min return Min.
#declare clip = function (x, y, z) {min(z, max(x, y))}
// Clamps a number (x) to the range [Min, Max] ([y, z]).
// Values outside this range wrap around.
#declare clamp = function (x, y, z) {mod(x - y, z - y) + select(mod(x - y, z - y), z, y)}
// Adjusts input values (x) in the range [0, 1] to output values in range [Rmn, Rmx] ([y, z]).
#declare adj_range = function (x, y, z) {x*(z - y) + y}
// Adjusts values in a specified range [Rmn, Rmx] to the specified range [Min, Max]
#declare adj_range2 =
function (x, y, z, _Math_INC_OMn, _Math_INC_OMx) {
((x - y)/(z - y))*(_Math_INC_OMx - _Math_INC_OMn) + _Math_INC_OMn
}
// Interpolate author: Margus Ramst
// Interpolation
// GC - global current
// GS - global start
// GE - global end
// TS - target start
// TE - target end
// Method - interpolation method:
// Method = 0 - cosine interpolation
// Method > 0 - exponential (1 - linear, etc)
#macro Interpolate(GC, GS, GE, TS, TE, Method)
(#if(Method!=0)
(TS+(TE-TS)*pow((GC-GS)/(GE-GS),Method))
#else
#local X=(GC-GS)/(GE-GS);
#local F=(1-cos(X*pi))*.5;
(TS*(1-F)+TE*F)
#end)
#end
// --------------------------------------------------------
// Vector macros:
// --------------------------------------------------------
// Squares the components of a vector
#macro VSqr(V) (V*V) #end
// Raises the components of a vector to a given power
#macro VPow(V, P) <pow(V.x, P), pow(V.y, P), pow(V.z, P)> #end
#macro VPow5D(V, P) <pow(V.x, P), pow(V.y, P), pow(V.z, P), pow(V.filter, P), pow(V.transmit, P)> #end
// Returns true if vectors are equal, otherwise false
#macro VEq(V1, V2) (V1.x = V2.x & V1.y = V2.y & V1.z = V2.z) #end
#macro VEq5D(V1, V2)
( V1.x = V2.x
& V1.y = V2.y
& V1.z = V2.z
& V1.filter = V2.filter
& V1.transmit = V2.transmit)
#end
// Returns true if vector is <0,0,0>, otherwise false
#macro VZero(V1) (V1.x = 0 & V1.y = 0 & V1.z = 0) #end
// Returns true if vector is <0,0,0,0,0>, otherwise false
#macro VZero5D(V1) (V1.x = 0 & V1.y = 0 & V1.z = 0 & V1.filter = 0 & V1.transmit = 0) #end
#macro VLength5D(V) sqrt(V.x*V.x + V.y*V.y + V.z*V.z + V.filter*V.filter + V.transmit*V.transmit) #end
#macro VNormalize5D(V) (V/sqrt(V.x*V.x + V.y*V.y + V.z*V.z + V.filter*V.filter + V.transmit*V.transmit)) #end
#macro VDot5D(V1, V2) (V1.x*V2.x + V1.y*V2.y + V1.z*V2.z + V1.filter*V2.filter + V1.transmit*V2.transmit) #end
// Cosine of angle between V1 and V2
#macro VCos_Angle(V1, V2) vdot(vnormalize(V1), vnormalize(V2)) #end
// Angle in radians between V1 and V2
#macro VAngle(V1, V2) acos(min(1, vdot(vnormalize(V1), vnormalize(V2)))) #end
// Angle in degrees between V1 and V2
#macro VAngleD(V1, V2) degrees(acos(min(1,vdot(vnormalize(V1), vnormalize(V2))))) #end
// VRotation() will find the rotation angle from V1 to V2
// around Axis. Axis should be perpendicular to both V1
// and V2. The output will be in the range between -pi and
// pi radians or between -180 degrees and 180 degrees if
// you are using the degree version. However, if Axis is
// set to <0,0,0> the output will always be positive or
// zero, the same result you will get with the VAngle() macros.
// Author: Rune S. Johansen
#macro VRotation(V1, V2, Axis)
(acos(min(vdot(vnormalize(V1),vnormalize(V2)),1))
*(vdot(Axis,vcross(V1,V2))<0?-1:1))
#end
#macro VRotationD(V1, V2, Axis)
(degrees(acos(min(vdot(vnormalize(V1),vnormalize(V2)),1)))
*(vdot(Axis,vcross(V1,V2))<0?-1:1))
#end
// Distance between V1 and V2
#macro VDist(V1, V2) vlength(V1 - V2) #end
// Returns a vector perpendicular to V
// Author: Tor Olav Kristensen
#macro VPerp_To_Vector(v0)
#if (vlength(v0) = 0)
#local vN = <0, 0, 0>;
#else
#local Dm = min(abs(v0.x), abs(v0.y), abs(v0.z));
#if (abs(v0.z) = Dm)
#local vN = vnormalize(vcross(v0, z));
#else
#if (abs(v0.y) = Dm)
#local vN = vnormalize(vcross(v0, y));
#else
#local vN = vnormalize(vcross(v0, x));
#end
#end
#end
vN
#end
// Returns a vector perpendicular to V1 and V2
#macro VPerp_To_Plane(V1, V2) (vnormalize(vcross(V1, V2))) #end
// Find a vector perpendicular to Axis and in the plane of
// V1 and Axis. In other words, the new vector is a version
// of V1 adjusted to be perpendicular to Axis.
#macro VPerp_Adjust(V, Axis)
vnormalize(vcross(vcross(Axis, V), Axis))
#end
// Projects a vector onto the plane defined by Axis.
// Based on code by Ron Parker
#macro VProject_Plane(V, Axis)
#local A = vnormalize(Axis);
(V - vdot(V, A)*A)
#end
// Projects a vector onto the an axis.
// Based on code by Ron Parker
#macro VProject_Axis(V, Axis)
(Axis*vdot(V, Axis)/vdot(Axis, Axis))
#end
// Smallest component of V
#macro VMin(V) (min3(V.x, V.y, V.z)) #end
// Largest component of V
#macro VMax(V) (max3(V.x, V.y, V.z)) #end
// Creates a vector going in the direction of the
// given vector with the specified length
#macro VWith_Len(V, Len) (Len*vnormalize(V)) #end
// --------------------------------------------------------
// Vector analysis macros
// --------------------------------------------------------
// Authors: Christoph Hormann and Tor Olav Kristensen
// Various functions of vector analysis in form of macros
// that can be used in user defined functions or expressions
//
// all macros make use of a constant named
// '__Gradient_Fn_Accuracy_' for numerical approximation
// of the derivatives.
// This constant can be changed with the
// 'SetGradientAccuracy()' macro, the default value is 0.001.
//
// Because vector functions can only be created as pigment
// or transform/spline functions and can not be passed as
// a macro parameter there is no fn_Curl() function and the
// divergence and curl macros use 3 float functions for
// defining the vector field.
#ifndef (__Gradient_Fn_Accuracy_)
#declare __Gradient_Fn_Accuracy_=0.001;
#end
#macro SetGradientAccuracy(Value)
#declare __Gradient_Fn_Accuracy_=abs(Value);
#end
// macro calculating the gradient of a function
// as a function
//
// Parameters:
// __Gradient_Fn: function to calculate the gradient from
//
// Output: the length of the gradient as a function
#macro fn_Gradient(__Gradient_Fn)
function {
f_r(
__Gradient_Fn(x + __Gradient_Fn_Accuracy_, y, z) - __Gradient_Fn(x - __Gradient_Fn_Accuracy_, y, z),
__Gradient_Fn(x, y + __Gradient_Fn_Accuracy_, z) - __Gradient_Fn(x, y - __Gradient_Fn_Accuracy_, z),
__Gradient_Fn(x, y, z + __Gradient_Fn_Accuracy_) - __Gradient_Fn(x, y, z - __Gradient_Fn_Accuracy_)
)/(2*__Gradient_Fn_Accuracy_)
}
#end
// macro calculating the gradient of a function
// in one direction as a function
//
// Parameters:
// __Gradient_Fn: function to calculate the gradient from
// Dir: direction to calculate the gradient
//
// Output: the gradient in that direction as a function
#macro fn_Gradient_Directional(__Gradient_Fn, Dir)
#local Dirx = vnormalize(Dir).x;
#local Diry = vnormalize(Dir).y;
#local Dirz = vnormalize(Dir).z;
function {
(
(__Gradient_Fn(x + __Gradient_Fn_Accuracy_, y, z) - __Gradient_Fn(x - __Gradient_Fn_Accuracy_, y, z))*Dirx +
(__Gradient_Fn(x, y + __Gradient_Fn_Accuracy_, z) - __Gradient_Fn(x, y - __Gradient_Fn_Accuracy_, z))*Diry +
(__Gradient_Fn(x, y, z + __Gradient_Fn_Accuracy_) - __Gradient_Fn(x, y, z - __Gradient_Fn_Accuracy_))*Dirz
)/(2*__Gradient_Fn_Accuracy_)
}
#end
// macro calculating the divergence of a (vector) function
// as a function
//
// Parameters:
// __Gradient_Fnx,
// __Gradient_Fny,
// __Gradient_Fnz: x, y and z components of a vector function
//
// Output: the divergence as a function
#macro fn_Divergence(__Gradient_Fnx, __Gradient_Fny, __Gradient_Fnz)
function {
(
__Gradient_Fnx(x + __Gradient_Fn_Accuracy_, y, z) - __Gradient_Fnx(x - __Gradient_Fn_Accuracy_, y, z)+
__Gradient_Fny(x, y + __Gradient_Fn_Accuracy_, z) - __Gradient_Fny(x, y - __Gradient_Fn_Accuracy_, z)+
__Gradient_Fnz(x, y, z + __Gradient_Fn_Accuracy_) - __Gradient_Fnz(x, y, z - __Gradient_Fn_Accuracy_)
)/(2*__Gradient_Fn_Accuracy_)
}
#end
// macro calculating the gradient of a function
// as a vector expression
//
// Parameters:
// __Gradient_Fn: function to calculate the gradient from
// p0: point where to calculate the gradient
//
// Output: the gradient as a vector expression
#macro vGradient(__Gradient_Fn, p0)
#local p0x=p0.x;
#local p0y=p0.y;
#local p0z=p0.z;
(
<
__Gradient_Fn(p0x + __Gradient_Fn_Accuracy_, p0y, p0z) - __Gradient_Fn(p0x - __Gradient_Fn_Accuracy_, p0y, p0z),
__Gradient_Fn(p0x, p0y + __Gradient_Fn_Accuracy_, p0z) - __Gradient_Fn(p0x, p0y - __Gradient_Fn_Accuracy_, p0z),
__Gradient_Fn(p0x, p0y, p0z + __Gradient_Fn_Accuracy_) - __Gradient_Fn(p0x, p0y, p0z - __Gradient_Fn_Accuracy_)
>/(2*__Gradient_Fn_Accuracy_)
)
#end
// macro calculating the curl of a (vector) function
// as a vector expression
//
// Parameters:
// __Gradient_Fnx,
// __Gradient_Fny,
// __Gradient_Fnz: x, y and z components of a vector function
// p0: point where to calculate the curl
//
// Output: the curl as a vector expression
#macro vCurl(__Gradient_Fnx, __Gradient_Fny, __Gradient_Fnz, p0)
#local p0x=p0.x;
#local p0y=p0.y;
#local p0z=p0.z;
(
<
__Gradient_Fnz(p0x, p0y + __Gradient_Fn_Accuracy_, p0z) - __Gradient_Fnz(p0x, p0y - __Gradient_Fn_Accuracy_, p0z) -
__Gradient_Fny(p0x, p0y, p0z + __Gradient_Fn_Accuracy_) + __Gradient_Fny(p0x, p0y, p0z - __Gradient_Fn_Accuracy_),
__Gradient_Fnx(p0x, p0y, p0z + __Gradient_Fn_Accuracy_) - __Gradient_Fnx(p0x, p0y, p0z - __Gradient_Fn_Accuracy_) -
__Gradient_Fnz(p0x + __Gradient_Fn_Accuracy_, p0y, p0z) + __Gradient_Fnz(p0x - __Gradient_Fn_Accuracy_, p0y, p0z),
__Gradient_Fny(p0x + __Gradient_Fn_Accuracy_, p0y, p0z) - __Gradient_Fny(p0x - __Gradient_Fn_Accuracy_, p0y, p0z) -
__Gradient_Fnx(p0x, p0y + __Gradient_Fn_Accuracy_, p0z) + __Gradient_Fnx(p0x, p0y - __Gradient_Fn_Accuracy_, p0z)
>/(2*__Gradient_Fn_Accuracy_)
)
#end
// macro calculating the divergence of a (vector) function
// as a float expression
//
// Parameters:
// __Gradient_Fnx,
// __Gradient_Fny,
// __Gradient_Fnz: x, y and z components of a vector function
// p0: point where to calculate the divergence
//
// Output: the divergence as a float expression
#macro Divergence(__Gradient_Fnx, __Gradient_Fny, __Gradient_Fnz, p0)
#local p0x=p0.x;
#local p0y=p0.y;
#local p0z=p0.z;
(
(
__Gradient_Fnx(p0x + __Gradient_Fn_Accuracy_, p0y, p0z) - __Gradient_Fnx(p0x - __Gradient_Fn_Accuracy_, p0y, p0z)+
__Gradient_Fny(p0x, p0y + __Gradient_Fn_Accuracy_, p0z) - __Gradient_Fny(p0x, p0y - __Gradient_Fn_Accuracy_, p0z)+
__Gradient_Fnz(p0x, p0y, p0z + __Gradient_Fn_Accuracy_) - __Gradient_Fnz(p0x, p0y, p0z - __Gradient_Fn_Accuracy_)
)/(2*__Gradient_Fn_Accuracy_)
)
#end
// macro calculating the length of the gradient
// of a function as a float expression
//
// Parameters:
// __Gradient_Fn: function to calculate the gradient from
// p0: point where to calculate the gradient
//
// Output: the length of the gradient as a float expression
#macro Gradient_Length(__Gradient_Fn, p0)
vlength(vGradient( function { __Gradient_Fn(x, y, z) } , p0))
#end
// macro calculating the gradient of a function
// in one direction as a float expression
//
// Parameters:
// __Gradient_Fn: function to calculate the gradient from
// p0: point where to calculate the gradient
// Dir: direction to calculate the gradient
//
// Output: the gradient in that direction as a float expression
#macro Gradient_Directional(__Gradient_Fn, p0, Dir)
vdot(
vGradient( function { __Gradient_Fn(x, y, z) }, p0),
vnormalize(Dir)
)
#end
#version MATH_INC_TEMP;
#end//math.inc
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