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// LibFile: math.scad
// Math helper functions.
// To use, add the following lines to the beginning of your file:
// ```
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// use <BOSL2/std.scad>
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// ```
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//////////////////////////////////////////////////////////////////////
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// Section: Math Constants
PHI = ( 1 + sqrt ( 5 ) ) / 2 ; // The golden ratio phi.
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EPSILON = 1e-9 ; // A really small value useful in comparing FP numbers. ie: abs(a-b)<EPSILON
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// Section: Simple math
// Function: sqr()
// Usage:
// sqr(x);
// Description:
// Returns the square of the given number.
// Examples:
// sqr(3); // Returns: 9
// sqr(-4); // Returns: 16
function sqr ( x ) = x * x ;
// Function: log2()
// Usage:
// foo = log2(x);
// Description:
// Returns the logarithm base 2 of the value given.
// Examples:
// log2(0.125); // Returns: -3
// log2(16); // Returns: 4
// log2(256); // Returns: 8
function log2 ( x ) = ln ( x ) / ln ( 2 ) ;
// Function: hypot()
// Usage:
// l = hypot(x,y,[z]);
// Description:
// Calculate hypotenuse length of a 2D or 3D triangle.
// Arguments:
// x = Length on the X axis.
// y = Length on the Y axis.
// z = Length on the Z axis. Optional.
// Example:
// l = hypot(3,4); // Returns: 5
// l = hypot(3,4,5); // Returns: ~7.0710678119
function hypot ( x , y , z = 0 ) = norm ( [ x , y , z ] ) ;
// Function: factorial()
// Usage:
// x = factorial(n,[d]);
// Description:
// Returns the factorial of the given integer value.
// Arguments:
// n = The integer number to get the factorial of. (n!)
// d = If given, the returned value will be (n! / d!)
// Example:
// x = factorial(4); // Returns: 24
// y = factorial(6); // Returns: 720
// z = factorial(9); // Returns: 362880
function factorial ( n , d = 1 ) = product ( [ for ( i = [ n : - 1 : d ] ) i ] ) ;
// Function: lerp()
// Usage:
// x = lerp(a, b, u);
// l = lerp(a, b, LIST);
// Description:
// Interpolate between two values or vectors.
// If `u` is given as a number, returns the single interpolated value.
// If `u` is 0.0, then the value of `a` is returned.
// If `u` is 1.0, then the value of `b` is returned.
// If `u` is a range, or list of numbers, returns a list of interpolated values.
// It is valid to use a `u` value outside the range 0 to 1. The result will be a predicted
// value along the slope formed by `a` and `b`, but not between those two values.
// Arguments:
// a = First value or vector.
// b = Second value or vector.
// u = The proportion from `a` to `b` to calculate. Standard range is 0.0 to 1.0, inclusive. If given as a list or range of values, returns a list of results.
// Example:
// x = lerp(0,20,0.3); // Returns: 6
// x = lerp(0,20,0.8); // Returns: 16
// x = lerp(0,20,-0.1); // Returns: -2
// x = lerp(0,20,1.1); // Returns: 22
// p = lerp([0,0],[20,10],0.25); // Returns [5,2.5]
// l = lerp(0,20,[0.4,0.6]); // Returns: [8,12]
// l = lerp(0,20,[0.25:0.25:0.75]); // Returns: [5,10,15]
// Example(2D):
// p1 = [-50,-20]; p2 = [50,30];
// stroke([p1,p2]);
// pts = lerp(p1, p2, [0:1/8:1]);
// // Points colored in ROYGBIV order.
// rainbow(pts) translate($item) circle(d=3,$fn=8);
function lerp ( a , b , u ) =
is_num ( u ) ? ( 1 - u ) * a + u * b :
[ for ( v = u ) lerp ( a , b , v ) ] ;
// Section: Hyperbolic Trigonometry
// Function: sinh()
// Description: Takes a value `x`, and returns the hyperbolic sine of it.
function sinh ( x ) =
( exp ( x ) - exp ( - x ) ) / 2 ;
// Function: cosh()
// Description: Takes a value `x`, and returns the hyperbolic cosine of it.
function cosh ( x ) =
( exp ( x ) + exp ( - x ) ) / 2 ;
// Function: tanh()
// Description: Takes a value `x`, and returns the hyperbolic tangent of it.
function tanh ( x ) =
sinh ( x ) / cosh ( x ) ;
// Function: asinh()
// Description: Takes a value `x`, and returns the inverse hyperbolic sine of it.
function asinh ( x ) =
ln ( x + sqrt ( x * x + 1 ) ) ;
// Function: acosh()
// Description: Takes a value `x`, and returns the inverse hyperbolic cosine of it.
function acosh ( x ) =
ln ( x + sqrt ( x * x - 1 ) ) ;
// Function: atanh()
// Description: Takes a value `x`, and returns the inverse hyperbolic tangent of it.
function atanh ( x ) =
ln ( ( 1 + x ) / ( 1 - x ) ) / 2 ;
// Section: Quantization
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// Function: quant()
// Description:
// Quantize a value `x` to an integer multiple of `y`, rounding to the nearest multiple.
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// If `x` is a list, then every item in that list will be recursively quantized.
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// Arguments:
// x = The value to quantize.
// y = The multiple to quantize to.
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// Example:
// quant(12,4); // Returns: 12
// quant(13,4); // Returns: 12
// quant(13.1,4); // Returns: 12
// quant(14,4); // Returns: 16
// quant(14.1,4); // Returns: 16
// quant(15,4); // Returns: 16
// quant(16,4); // Returns: 16
// quant(9,3); // Returns: 9
// quant(10,3); // Returns: 9
// quant(10.4,3); // Returns: 9
// quant(10.5,3); // Returns: 12
// quant(11,3); // Returns: 12
// quant(12,3); // Returns: 12
// quant([12,13,13.1,14,14.1,15,16],4); // Returns: [12,12,12,16,16,16,16]
// quant([9,10,10.4,10.5,11,12],3); // Returns: [9,9,9,12,12,12]
// quant([[9,10,10.4],[10.5,11,12]],3); // Returns: [[9,9,9],[12,12,12]]
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function quant ( x , y ) =
is_list ( x ) ? [ for ( v = x ) quant ( v , y ) ] :
floor ( x / y + 0.5 ) * y ;
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// Function: quantdn()
// Description:
// Quantize a value `x` to an integer multiple of `y`, rounding down to the previous multiple.
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// If `x` is a list, then every item in that list will be recursively quantized down.
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// Arguments:
// x = The value to quantize.
// y = The multiple to quantize to.
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// Examples:
// quantdn(12,4); // Returns: 12
// quantdn(13,4); // Returns: 12
// quantdn(13.1,4); // Returns: 12
// quantdn(14,4); // Returns: 12
// quantdn(14.1,4); // Returns: 12
// quantdn(15,4); // Returns: 12
// quantdn(16,4); // Returns: 16
// quantdn(9,3); // Returns: 9
// quantdn(10,3); // Returns: 9
// quantdn(10.4,3); // Returns: 9
// quantdn(10.5,3); // Returns: 9
// quantdn(11,3); // Returns: 9
// quantdn(12,3); // Returns: 12
// quantdn([12,13,13.1,14,14.1,15,16],4); // Returns: [12,12,12,12,12,12,16]
// quantdn([9,10,10.4,10.5,11,12],3); // Returns: [9,9,9,9,9,12]
// quantdn([[9,10,10.4],[10.5,11,12]],3); // Returns: [[9,9,9],[9,9,12]]
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function quantdn ( x , y ) =
is_list ( x ) ? [ for ( v = x ) quantdn ( v , y ) ] :
floor ( x / y ) * y ;
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// Function: quantup()
// Description:
// Quantize a value `x` to an integer multiple of `y`, rounding up to the next multiple.
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// If `x` is a list, then every item in that list will be recursively quantized up.
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// Arguments:
// x = The value to quantize.
// y = The multiple to quantize to.
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// Examples:
// quantup(12,4); // Returns: 12
// quantup(13,4); // Returns: 16
// quantup(13.1,4); // Returns: 16
// quantup(14,4); // Returns: 16
// quantup(14.1,4); // Returns: 16
// quantup(15,4); // Returns: 16
// quantup(16,4); // Returns: 16
// quantup(9,3); // Returns: 9
// quantup(10,3); // Returns: 12
// quantup(10.4,3); // Returns: 12
// quantup(10.5,3); // Returns: 12
// quantup(11,3); // Returns: 12
// quantup(12,3); // Returns: 12
// quantup([12,13,13.1,14,14.1,15,16],4); // Returns: [12,16,16,16,16,16,16]
// quantup([9,10,10.4,10.5,11,12],3); // Returns: [9,12,12,12,12,12]
// quantup([[9,10,10.4],[10.5,11,12]],3); // Returns: [[9,12,12],[12,12,12]]
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function quantup ( x , y ) =
is_list ( x ) ? [ for ( v = x ) quantup ( v , y ) ] :
ceil ( x / y ) * y ;
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// Section: Constraints and Modulos
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// Function: constrain()
// Usage:
// constrain(v, minval, maxval);
// Description:
// Constrains value to a range of values between minval and maxval, inclusive.
// Arguments:
// v = value to constrain.
// minval = minimum value to return, if out of range.
// maxval = maximum value to return, if out of range.
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// Example:
// constrain(-5, -1, 1); // Returns: -1
// constrain(5, -1, 1); // Returns: 1
// constrain(0.3, -1, 1); // Returns: 0.3
// constrain(9.1, 0, 9); // Returns: 9
// constrain(-0.1, 0, 9); // Returns: 0
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function constrain ( v , minval , maxval ) = min ( maxval , max ( minval , v ) ) ;
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// Function: posmod()
// Usage:
// posmod(x,m)
// Description:
// Returns the positive modulo `m` of `x`. Value returned will be in the range 0 ... `m`-1.
// Arguments:
// x = The value to constrain.
// m = Modulo value.
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// Example:
// posmod(-700,360); // Returns: 340
// posmod(-270,360); // Returns: 90
// posmod(-120,360); // Returns: 240
// posmod(120,360); // Returns: 120
// posmod(270,360); // Returns: 270
// posmod(700,360); // Returns: 340
// posmod(3,2.5); // Returns: 0.5
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function posmod ( x , m ) = ( x % m + m ) % m ;
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// Function: modang(x)
// Usage:
// ang = modang(x)
// Description:
// Takes an angle in degrees and normalizes it to an equivalent angle value between -180 and 180.
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// Example:
// modang(-700,360); // Returns: 20
// modang(-270,360); // Returns: 90
// modang(-120,360); // Returns: -120
// modang(120,360); // Returns: 120
// modang(270,360); // Returns: -90
// modang(700,360); // Returns: -20
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function modang ( x ) =
let ( xx = posmod ( x , 360 ) ) xx < 180 ? xx : xx - 360 ;
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// Function: modrange()
// Usage:
// modrange(x, y, m, [step])
// Description:
// Returns a normalized list of values from `x` to `y`, by `step`, modulo `m`. Wraps if `x` > `y`.
// Arguments:
// x = The start value to constrain.
// y = The end value to constrain.
// m = Modulo value.
// step = Step by this amount.
// Examples:
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// modrange(90,270,360, step=45); // Returns: [90,135,180,225,270]
// modrange(270,90,360, step=45); // Returns: [270,315,0,45,90]
// modrange(90,270,360, step=-45); // Returns: [90,45,0,315,270]
// modrange(270,90,360, step=-45); // Returns: [270,225,180,135,90]
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function modrange ( x , y , m , step = 1 ) =
let (
a = posmod ( x , m ) ,
b = posmod ( y , m ) ,
c = step > 0 ? ( a > b ? b + m : b ) : ( a < b ? b - m : b )
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) [ for ( i = [ a : step : c ] ) ( i % m + m ) % m ] ;
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// Section: Random Number Generation
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// Function: rand_int()
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// Usage:
// rand_int(min,max,N,[seed]);
// Description:
// Return a list of random integers in the range of min to max, inclusive.
// Arguments:
// min = Minimum integer value to return.
// max = Maximum integer value to return.
// N = Number of random integers to return.
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// seed = If given, sets the random number seed.
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// Example:
// ints = rand_int(0,100,3);
// int = rand_int(-10,10,1)[0];
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function rand_int ( min , max , N , seed = undef ) =
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assert ( max >= min , "Max value cannot be smaller than min" )
let ( rvect = is_def ( seed ) ? rands ( min , max + 1 , N , seed ) : rands ( min , max + 1 , N ) )
[ for ( entry = rvect ) floor ( entry ) ] ;
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// Function: gaussian_rands()
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// Usage:
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// gaussian_rands(mean, stddev, [N], [seed])
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// Description:
// Returns a random number with a gaussian/normal distribution.
// Arguments:
// mean = The average random number returned.
// stddev = The standard deviation of the numbers to be returned.
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// N = Number of random numbers to return. Default: 1
// seed = If given, sets the random number seed.
function gaussian_rands ( mean , stddev , N = 1 , seed = undef ) =
let ( nums = is_undef ( seed ) ? rands ( 0 , 1 , N * 2 ) : rands ( 0 , 1 , N * 2 , seed ) )
[ for ( i = list_range ( N ) ) mean + stddev * sqrt ( - 2 * ln ( nums [ i * 2 ] ) ) * cos ( 360 * nums [ i * 2 + 1 ] ) ] ;
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// Function: log_rands()
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// Usage:
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// log_rands(minval, maxval, factor, [N], [seed]);
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// Description:
// Returns a single random number, with a logarithmic distribution.
// Arguments:
// minval = Minimum value to return.
// maxval = Maximum value to return. `minval` <= X < `maxval`.
// factor = Log factor to use. Values of X are returned `factor` times more often than X+1.
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// N = Number of random numbers to return. Default: 1
// seed = If given, sets the random number seed.
function log_rands ( minval , maxval , factor , N = 1 , seed = undef ) =
assert ( maxval >= minval , "maxval cannot be smaller than minval" )
let (
minv = 1 - 1 / pow ( factor , minval ) ,
maxv = 1 - 1 / pow ( factor , maxval ) ,
nums = is_undef ( seed ) ? rands ( minv , maxv , N ) : rands ( minv , maxv , N , seed )
) [ for ( num = nums ) - ln ( 1 - num ) / ln ( factor ) ] ;
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// Section: GCD/GCF, LCM
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// If argument is a list return it. Otherwise return a singleton list containing the argument.
function _force_list ( x ) = is_list ( x ) ? x : [ x ] ;
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// Function: gcd()
// Usage:
// gcd(a,b)
// Description:
// Computes the Greatest Common Divisor/Factor of `a` and `b`.
function gcd ( a , b ) =
assert ( is_int ( a ) && is_int ( b ) , "Arguments to gcd must be integers" )
b = = 0 ? abs ( a ) : gcd ( b , a % b ) ;
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// Computes lcm for two scalars
function _lcm ( a , b ) =
assert ( is_int ( a ) , "Invalid non-integer parameters to lcm" )
assert ( is_int ( b ) , "Invalid non-integer parameters to lcm" )
assert ( a ! = 0 && b ! = 0 , "Arguments to lcm must be nonzero" )
abs ( a * b ) / gcd ( a , b ) ;
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// Computes lcm for a list of values
function _lcmlist ( a ) =
len ( a ) = = 1 ? a [ 0 ] :
_lcmlist ( concat ( slice ( a , 0 , len ( a ) - 2 ) , [ lcm ( a [ len ( a ) - 2 ] , a [ len ( a ) - 1 ] ) ] ) ) ;
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// Function: lcm()
// Usage:
// lcm(a,b)
// lcm(list)
// Description:
// Computes the Least Common Multiple of the two arguments or a list of arguments. Inputs should
// be non-zero integers. The output is always a positive integer. It is an error to pass zero
// as an argument.
function lcm ( a , b = [ ] ) =
! is_list ( a ) && ! is_list ( b ) ? _lcm ( a , b ) :
let (
arglist = concat ( _force_list ( a ) , _force_list ( b ) )
)
assert ( len ( arglist ) > 0 , "invalid call to lcm with empty list(s)" )
_lcmlist ( arglist ) ;
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// Section: Sums, Products, Aggregate Functions.
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// Function: sum()
// Description:
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// Returns the sum of all entries in the given list.
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// If passed an array of vectors, returns a vector of sums of each part.
// Arguments:
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// v = The list to get the sum of.
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// Example:
// sum([1,2,3]); // returns 6.
// sum([[1,2,3], [3,4,5], [5,6,7]]); // returns [9, 12, 15]
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function sum ( v , _i = 0 , _acc ) =
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_i >= len ( v ) ? _acc :
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sum ( v , _i = _i + 1 , _acc = is_undef ( _acc ) ? v [ _i ] : _acc + v [ _i ] ) ;
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// Function: cumsum()
// Description:
// Returns a list where each item is the cumulative sum of all items up to and including the corresponding entry in the input list.
// If passed an array of vectors, returns a list of cumulative vectors sums.
// Arguments:
// v = The list to get the sum of.
// Example:
// cumsum([1,1,1]); // returns [1,2,3]
// cumsum([2,2,2]); // returns [2,4,6]
// cumsum([1,2,3]); // returns [1,3,6]
// cumsum([[1,2,3], [3,4,5], [5,6,7]]); // returns [[1,2,3], [4,6,8], [9,12,15]]
function cumsum ( v , _i = 0 , _acc = [ ] ) =
_i = = len ( v ) ? _acc :
cumsum (
v , _i + 1 ,
concat (
_acc ,
[ _i = = 0 ? v [ _i ] : select ( _acc , - 1 ) + v [ _i ] ]
)
) ;
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// Function: sum_of_squares()
// Description:
// Returns the sum of the square of each element of a vector.
// Arguments:
// v = The vector to get the sum of.
// Example:
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// sum_of_squares([1,2,3]); // Returns: 14.
// sum_of_squares([1,2,4]); // Returns: 21
// sum_of_squares([-3,-2,-1]); // Returns: 14
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function sum_of_squares ( v , i = 0 , tot = 0 ) = sum ( vmul ( v , v ) ) ;
// Function: sum_of_sines()
// Usage:
// sum_of_sines(a,sines)
// Description:
// Gives the sum of a series of sines, at a given angle.
// Arguments:
// a = Angle to get the value for.
// sines = List of [amplitude, frequency, offset] items, where the frequency is the number of times the cycle repeats around the circle.
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// Examples:
// v = sum_of_sines(30, [[10,3,0], [5,5.5,60]]);
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function sum_of_sines ( a , sines ) =
sum ( [
for ( s = sines ) let (
ss = point3d ( s ) ,
v = ss . x * sin ( a * ss . y + ss . z )
) v
] ) ;
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// Function: deltas()
// Description:
// Returns a list with the deltas of adjacent entries in the given list.
// Given [a,b,c,d], returns [b-a,c-b,d-c].
// Arguments:
// v = The list to get the deltas of.
// Example:
// deltas([2,5,9,17]); // returns [3,4,8].
// deltas([[1,2,3], [3,6,8], [4,8,11]]); // returns [[2,4,5], [1,2,3]]
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function deltas ( v ) = [ for ( p = pair ( v ) ) p . y - p . x ] ;
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// Function: product()
// Description:
// Returns the product of all entries in the given list.
// If passed an array of vectors, returns a vector of products of each part.
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// If passed an array of matrices, returns a the resulting product matrix.
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// Arguments:
// v = The list to get the product of.
// Example:
// product([2,3,4]); // returns 24.
// product([[1,2,3], [3,4,5], [5,6,7]]); // returns [15, 48, 105]
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function product ( v , i = 0 , tot = undef ) = i >= len ( v ) ? tot : product ( v , i + 1 , ( ( tot = = undef ) ? v [ i ] : is_vector ( v [ i ] ) ? vmul ( tot , v [ i ] ) : tot * v [ i ] ) ) ;
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// Function: mean()
// Description:
// Returns the mean of all entries in the given array.
// If passed an array of vectors, returns a vector of mean of each part.
// Arguments:
// v = The list of values to get the mean of.
// Example:
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// mean([2,3,4]); // returns 3.
// mean([[1,2,3], [3,4,5], [5,6,7]]); // returns [3, 4, 5]
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function mean ( v ) = sum ( v ) / len ( v ) ;
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// Section: Determinants
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// Function: det2()
// Description:
// Optimized function that returns the determinant for the given 2x2 square matrix.
// Arguments:
// M = The 2x2 square matrix to get the determinant of.
// Example:
// M = [ [6,-2], [1,8] ];
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// det = det2(M); // Returns: 50
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function det2 ( M ) = M [ 0 ] [ 0 ] * M [ 1 ] [ 1 ] - M [ 0 ] [ 1 ] * M [ 1 ] [ 0 ] ;
// Function: det3()
// Description:
// Optimized function that returns the determinant for the given 3x3 square matrix.
// Arguments:
// M = The 3x3 square matrix to get the determinant of.
// Example:
// M = [ [6,4,-2], [1,-2,8], [1,5,7] ];
// det = det3(M); // Returns: -334
function det3 ( M ) =
M [ 0 ] [ 0 ] * ( M [ 1 ] [ 1 ] * M [ 2 ] [ 2 ] - M [ 2 ] [ 1 ] * M [ 1 ] [ 2 ] ) -
M [ 1 ] [ 0 ] * ( M [ 0 ] [ 1 ] * M [ 2 ] [ 2 ] - M [ 2 ] [ 1 ] * M [ 0 ] [ 2 ] ) +
M [ 2 ] [ 0 ] * ( M [ 0 ] [ 1 ] * M [ 1 ] [ 2 ] - M [ 1 ] [ 1 ] * M [ 0 ] [ 2 ] ) ;
// Function: determinant()
// Description:
// Returns the determinant for the given square matrix.
// Arguments:
// M = The NxN square matrix to get the determinant of.
// Example:
// M = [ [6,4,-2,9], [1,-2,8,3], [1,5,7,6], [4,2,5,1] ];
// det = determinant(M); // Returns: 2267
function determinant ( M ) =
assert ( len ( M ) = = len ( M [ 0 ] ) )
len ( M ) = = 1 ? M [ 0 ] [ 0 ] :
len ( M ) = = 2 ? det2 ( M ) :
len ( M ) = = 3 ? det3 ( M ) :
sum (
[ for ( col = [ 0 : 1 : len ( M ) - 1 ] )
( ( col % 2 = = 0 ) ? 1 : - 1 ) *
M [ col ] [ 0 ] *
determinant (
[ for ( r = [ 1 : 1 : len ( M ) - 1 ] )
[ for ( c = [ 0 : 1 : len ( M ) - 1 ] )
if ( c ! = col ) M [ c ] [ r ]
]
]
)
]
) ;
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// Section: Comparisons and Logic
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// Function: approx()
// Usage:
// approx(a,b,[eps])
// Description:
// Compares two numbers or vectors, and returns true if they are closer than `eps` to each other.
// Arguments:
// a = First value.
// b = Second value.
// eps = The maximum allowed difference between `a` and `b` that will return true.
// Example:
// approx(-0.3333333333,-1/3); // Returns: true
// approx(0.3333333333,1/3); // Returns: true
// approx(0.3333,1/3); // Returns: false
// approx(0.3333,1/3,eps=1e-3); // Returns: true
// approx(PI,3.1415926536); // Returns: true
function approx ( a , b , eps = EPSILON ) = let ( c = a - b ) ( is_num ( c ) ? abs ( c ) : norm ( c ) ) < = eps ;
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function _type_num ( x ) =
is_undef ( x ) ? 0 :
is_bool ( x ) ? 1 :
is_num ( x ) ? 2 :
is_string ( x ) ? 3 :
is_list ( x ) ? 4 : 5 ;
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// Function: compare_vals()
// Usage:
// compare_vals(a, b);
// Description:
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// Compares two values. Lists are compared recursively.
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// If types are not the same, then undef < bool < num < str < list < range.
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// Arguments:
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// a = First value to compare.
// b = Second value to compare.
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function compare_vals ( a , b ) =
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( a = = b ) ? 0 :
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let ( t1 = _type_num ( a ) , t2 = _type_num ( b ) ) ( t1 ! = t2 ) ? ( t1 - t2 ) :
is_list ( a ) ? compare_lists ( a , b ) :
( a < b ) ? - 1 : ( a > b ) ? 1 : 0 ;
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// Function: compare_lists()
// Usage:
// compare_lists(a, b)
// Description:
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// Compare contents of two lists using `compare_vals()`.
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// Returns <0 if `a`<`b`.
// Returns 0 if `a`==`b`.
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// Returns >0 if `a`>`b`.
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// Arguments:
// a = First list to compare.
// b = Second list to compare.
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function compare_lists ( a , b ) =
a = = b ? 0 : let (
cmps = [
for ( i = [ 0 : 1 : min ( len ( a ) , len ( b ) ) - 1 ] ) let (
cmp = compare_vals ( a [ i ] , b [ i ] )
) if ( cmp ! = 0 ) cmp
]
) cmps = = [ ] ? ( len ( a ) - len ( b ) ) : cmps [ 0 ] ;
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// Function: any()
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// Description:
// Returns true if any item in list `l` evaluates as true.
// If `l` is a lists of lists, `any()` is applied recursively to each sublist.
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// Arguments:
// l = The list to test for true items.
// Example:
// any([0,false,undef]); // Returns false.
// any([1,false,undef]); // Returns true.
// any([1,5,true]); // Returns true.
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// any([[0,0], [0,0]]); // Returns false.
// any([[0,0], [1,0]]); // Returns true.
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function any ( l , i = 0 , succ = false ) =
( i >= len ( l ) || succ ) ? succ :
any (
l , i = i + 1 , succ = (
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is_list ( l [ i ] ) ? any ( l [ i ] ) :
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! ( ! l [ i ] )
)
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) ;
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// Function: all()
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// Description:
// Returns true if all items in list `l` evaluate as true.
// If `l` is a lists of lists, `all()` is applied recursively to each sublist.
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// Arguments:
// l = The list to test for true items.
// Example:
// all([0,false,undef]); // Returns false.
// all([1,false,undef]); // Returns false.
// all([1,5,true]); // Returns true.
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// all([[0,0], [0,0]]); // Returns false.
// all([[0,0], [1,0]]); // Returns false.
// all([[1,1], [1,1]]); // Returns true.
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function all ( l , i = 0 , fail = false ) =
( i >= len ( l ) || fail ) ? ( ! fail ) :
all (
l , i = i + 1 , fail = (
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is_list ( l [ i ] ) ? ! all ( l [ i ] ) :
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! l [ i ]
)
) ;
// Function: count_true()
// Usage:
// count_true(l)
// Description:
// Returns the number of items in `l` that evaluate as true.
// If `l` is a lists of lists, this is applied recursively to each
// sublist. Returns the total count of items that evaluate as true
// in all recursive sublists.
// Arguments:
// l = The list to test for true items.
// nmax = If given, stop counting if `nmax` items evaluate as true.
// Example:
// count_true([0,false,undef]); // Returns 0.
// count_true([1,false,undef]); // Returns 1.
// count_true([1,5,false]); // Returns 2.
// count_true([1,5,true]); // Returns 3.
// count_true([[0,0], [0,0]]); // Returns 0.
// count_true([[0,0], [1,0]]); // Returns 1.
// count_true([[1,1], [1,1]]); // Returns 4.
// count_true([[1,1], [1,1]], nmax=3); // Returns 3.
function count_true ( l , nmax = undef , i = 0 , cnt = 0 ) =
( i >= len ( l ) || ( nmax ! = undef && cnt >= nmax ) ) ? cnt :
count_true (
l = l , nmax = nmax , i = i + 1 , cnt = cnt + (
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is_list ( l [ i ] ) ? count_true ( l [ i ] , nmax = nmax - cnt ) :
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( l [ i ] ? 1 : 0 )
)
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) ;
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// vim: noexpandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap