Math / Formula for Expressions - Stage Precision

Arithmetic & Assignment Operators

Operator	Definition
+	Addition between x and y. (eg: x + y)
–	Subtraction between x and y. (eg: x – y)
*	Multiplication between x and y. (eg: x * y)
/	Division between x and y. (eg: x / y)
%	Modulus of x with respect to y. (eg: x % y)
^	x to the power of y. (eg: x ^ y)
:=	Assign the value of x to y. Where y is either a variable or vector type. (eg: y := x)
+=	Increment x by the value of the expression on the right and side. Where x is either a variable or vector type. (eg: x += abs(y – z))
-=	Decrement x by the value of the expression on the right hand side. Where x is either a variable or vector type. (eg: x[i] -= abs(y + z))
*=	Assign the multiplication of x by the value of the expression on the righthand side to x. Where x is either a variable or vector type. (eg: x *= abs(y / z))
/=	Assign the division of x by the value of the expression on the right-hand side to x. Where x is either a variable or vector type. (eg: x[i + j] /= abs(y * z))
%=	Assign x modulo the value of the expression on the right hand side to x. Where x is either a variable or vector type. (eg: x² %= y ^ 2)

Equalities & Inequalities

Operator	Definition
= or ==	True only if x is strictly equal to y. (eg: x = y or x == y)
<> or !=	True only if x does not equal y. (eg: x <> y or x != y)
<	True only if x is less than y. (eg: x < y)
<=	True only if x is less than or equal to y. (eg: x <= y)
>	True only if x is greater than y. (eg: x > y)
>=	True only if x greater than or equal to y. (eg: x >= y)

Boolean Operations

Operator	Definition
true	True state or any value other than zero (typically 1).
false	False state, value of exactly zero.
and	Logical AND, True only if x and y are both true. (eg: x and y)
mand	Multi-input logical AND, True only if all inputs are true. Left to right short-circuiting of expressions. (eg: mand(x > y, z < w, u or v, w and x))
mor	Multi-input logical OR, True if at least one of the inputs are true. Left to right short-circuiting of expressions. (eg: mor(x > y, z < w, u or v, w and x))
nand	Logical NAND, True only if either x or y is false. (eg: x nand y)
nor	Logical NOR, True only if the result of x or y is false (eg: x nor y)
not	Logical NOT, Negate the logical sense of the input. (eg: not(x and y) == x nand y)
or	Logical OR, True if either x or y is true. (eg: x or y)
xor	Logical XOR, True only if the logical states of x and y differ. (eg: x xor y)
xnor	Logical XNOR, True iff the biconditional of x and y is satisfied. (eg: x xnor y)
&	Similar to AND but with left to right expression short circuiting optimisation. (eg: (x & y) == (y and x))
❘	Similar to OR but with left to right expression short circuiting optimisation. (eg: (x ❘ y) == (y or x))

General Purpose Functions

Function	Definition
abs	Absolute value of x. (eg: abs(x))
avg	Average of all the inputs. (eg: avg(x,y,z,w,u,v) == (x + y + z + w + u + v) / 6)
ceil	Smallest integer that is greater than or equal to x.
clamp	Clamp x in range between r0 and r1, where r0 < r1. (eg: clamp(r0,x,r1))
equal	Equality test between x and y using normalised epsilon
erf	Error function of x. (eg: erf(x))
erfc	Complimentary error function of x. (eg: erfc(x))
exp	e to the power of x. (eg: exp(x))
expm1	e to the power of x minus 1, where x is very small. (eg: expm1(x))
floor	Largest integer that is less than or equal to x. (eg: floor(x))
frac	Fractional portion of x. (eg: frac(x))
hypot	Hypotenuse of x and y (eg: hypot(x,y) = sqrt(xx + yy))
iclamp	Inverse-clamp x outside of the range r0 and r1. Where r0 < r1. If x is within the range it will snap to the closest bound. (eg: iclamp(r0,x,r1)
inrange	In-range returns ‘true’ when x is within the range r0 and r1. Where r0 < r1. (eg: inrange(r0,x,r1)
log	Natural logarithm of x. (eg: log(x))
log10	Base 10 logarithm of x. (eg: log10(x))
log1p	Natural logarithm of 1 + x, where x is very small. (eg: log1p(x))
log2	Base 2 logarithm of x. (eg: log2(x))
logn	Base N logarithm of x. where n is a positive integer. (eg: logn(x,8))
max	Largest value of all the inputs. (eg: max(x,y,z,w,u,v))
min	Smallest value of all the inputs. (eg: min(x,y,z,w,u))
mul	Product of all the inputs. (eg: mul(x,y,z,w,u,v,t) == (x * y * z * w * u * v * t))
ncdf	Normal cumulative distribution function. (eg: ncdf(x))
nequal	Not-equal test between x and y using normalised epsilon
pow	x to the power of y. (eg: pow(x,y) == x ^ y)
root	Nth-Root of x. where n is a positive integer. (eg: root(x,3) == x^(1/3))
round	Round x to the nearest integer. (eg: round(x))
roundn	Round x to n decimal places (eg: roundn(x,3)) where n > 0 and is an integer. (eg: roundn(1.2345678,4) == 1.2346)
sgn	Sign of x, -1 where x < 0, +1 where x > 0, else zero. (eg: sgn(x))
sqrt	Square root of x, where x >= 0. (eg: sqrt(x))
sum	Sum of all the inputs. (eg: sum(x,y,z,w,u,v,t) == (x + y + z + w + u + v + t))
swap	Swap the values of the variables x and y and return the
<=>	current value of y. (eg: swap(x,y) or x <=> y)
trunc	Integer portion of x. (eg: trunc(x))

Trigonometry Functions

Function	Definition
acos	Arc cosine of x expressed in radians. Interval [-1,+1] (eg: acos(x))
acosh	Inverse hyperbolic cosine of x expressed in radians. (eg: acosh(x))
asin	Arc sine of x expressed in radians. Interval [-1,+1] (eg: asin(x))
asinh	Inverse hyperbolic sine of x expressed in radians. (eg: asinh(x))
atan	Arc tangent of x expressed in radians. Interval [-1,+1] (eg: atan(x))
atan2	Arc tangent of (x / y) expressed in radians. [-pi,+pi] eg: atan2(x,y)
atanh	Inverse hyperbolic tangent of x expressed in radians. (eg: atanh(x))
cos	Cosine of x. (eg: cos(x))
cosh	Hyperbolic cosine of x. (eg: cosh(x))
cot	Cotangent of x. (eg: cot(x))
csc	Cosecant of x. (eg: csc(x))
sec	Secant of x. (eg: sec(x))
sin	Sine of x. (eg: sin(x))
sinc	Sine cardinal of x. (eg: sinc(x))
sinh	Hyperbolic sine of x. (eg: sinh(x))
tan	Tangent of x. (eg: tan(x))
tanh	Hyperbolic tangent of x. (eg: tanh(x))
deg2rad	Convert x from degrees to radians. (eg: deg2rad(x))
deg2grad	Convert x from degrees to gradians. (eg: deg2grad(x))
rad2deg	Convert x from radians to degrees. (eg: rad2deg(x))
grad2deg	Convert x from gradians to degrees. (eg: grad2deg(x))

String Processing

Function	Definition
= , ==	All common equality/inequality operators are applicable
!=, <>	to strings and are applied in a case sensitive manner.
<=, >=	In the following example x, y and z are of type string.
< , >	(eg: not((x <= ‘AbC’) and (‘1×2y3z’ <> y)) or (z == x)
in	True only if x is a substring of y. (eg: x in y or ‘abc’ in ‘abcdefgh’)
like	True only if the string x matches the pattern y. Available wildcard characters are ‘’ and ‘?’ denoting zero or more and zero or one matches respectively. (eg: x like y or ‘abcdefgh’ like ‘a?dh’)
ilike	True only if the string x matches the pattern y in a case insensitive manner. Available wildcard characters are ‘’ and ‘?’ denoting zero or more and zero or one matches respectively. (eg: x ilike y or ‘a1B2c3D4e5F6g7H’ ilike ‘a?dh’)
[r0:r1]	The closed interval [r0,r1] of the specified string. eg: Given a string x with a value of ‘abcdefgh’ then: 1. x[1:4] ==‘bcde’ 2. x[ :5] ==x[:10 / 2] ==‘abcdef’ 3. x[2 + 1: ] ==x[3:] ==defgh’ 4. x[ : ] ==x[:] ==‘abcdefgh’ 5. x[4/2:3+2] ==x[2:5] ==‘cdef’ Note: Both r0 and r1 are assumed to be integers, where r0 <= r1. They may also be the result of an expression, in the event they have fractional components truncation will be performed. (eg: 1.67 —> 1)
:=	Assign the value of x to y. Where y is a mutable string or string range and x is either a string or a string range. eg: 1. y := x 2. y := ‘abc’ 3. y := x[:i + j] 4. y := ‘0123456789’[2:7] 5. y := ‘0123456789’[2i + 1:7] 6. y := (x := ‘0123456789’[2:7]) 7. y[i:j] := x 8. y[i:j] := (x + ‘abcdefg’[8 / 4:5])[m:n] Note: For options 7 and 8 the shorter of the two ranges will denote the number characters that are to be copied.
+	Concatenation of x and y. Where x and y are strings or string ranges. eg 1. x + y 2. x + ‘abc’ 3. x + y[:i + j] 4. x[i:j] + y[2:3] + ‘0123456789’[2:7] 5. ‘abc’ + x + y 6. ‘abc’ + ‘1234567’ 7. (x + ‘a1B2c3D4’ + y)[i:2j]
+=	Append to x the value of y. Where x is a mutable string and y is either a string or a string range. eg: 1. x += y 2. x += ‘abc’ 3. x += y[:i + j] + ‘abc’ 4. x += ‘0123456789’[2:7]
<=>	Swap the values of x and y. Where x and y are mutable strings. (eg: x <=> y)
[]	The string size operator returns the size of the string being actioned. eg: 1. ‘abc’[] 3 * 2. var max_str_length := max(s0[],s1[],s2[],s3[]) * 3. ('abc' + 'xyz')[] 6 4. ((‘abc’ + ‘xyz’)[1:4])[] == 4

Control Structures

Structure	Definition
if	If x is true then return y else return z. eg: 1. if (x, y, z) 2. if ((x + 1) > 2y, z + 1, w / v) 3. if (x > y) z; 4. if (x <= 2*y) { z + w };
if-else	The if-else/else-if statement. Subject to the condition branch the statement will return either the value of the consequent or the alternative branch. eg: 1. if (x > y) z; else w; 2. if (x > y) z; else if (w != u) v; 3. if (x < y) { z; w + 1; } else u; 4. if ((x != y) and (z > w)) { y := sin(x) / u; z := w + 1; } else if (x > (z + 1)) { w := abs (x – y) + z; u := (x + 1) > 2y ? 2u : 3u; }
switch	The first true case condition that is encountered will determine the result of the switch. If none of the case conditions hold true, the default action is assumed as the final return value. This is sometimes also known as a multi-way branch mechanism eg: switch { case x > (y + z) : 2 * x / abs(y – z); case x < 3 : sin(x + y); default : 1 + x; }
while	The structure will repeatedly evaluate the internal statement(s) ‘while’ the condition is true. The final statement in the final iteration will be used as the return value of the loop. eg: while ((x -= 1) > 0) { y := x + z; w := u + y; }
repeat/until	The structure will repeatedly evaluate the internal statement(s) ‘until’ the condition is true. The final statement in the final iteration will be used as the return value of the loop.eg: repeat y := x + z; w := u + y; until ((x += 1) > 100)
for	The structure will repeatedly evaluate the internal statement(s) while the condition is true. On each loop iteration, an ‘incrementing’ expression is evaluated. The conditional is mandatory whereas the initialiser and incrementing expressions are optional. eg: for (var x := 0; (x < n) and (x != y); x += 1) { y := y + x / 2 – z; w := u + y; }
break, break[]	Break terminates the execution of the nearest enclosed loop, allowing for the execution to continue on externa to the loop. The default break statement will set the return value of the loop to NaN, where as the return based form will set the value to that of the break expression. eg: while ((i += 1) < 10) { if (i < 5) j -= i + 2; else if (i % 2 == 0) break; else break[2i + 3]; }
continue	Continue results in the remaining portion of the neares enclosing loop body to be skipped. eg: for (var i := 0; i < 10; i += 1) { if (i < 5) continue; j -= i + 2; }
return	Return immediately from within the current expression. With the option of passing back a variable number of values (scalar, vector or string). eg: 1. return [1]; 2. return [x, ‘abx’]; 3. return [x, x + y,‘abx’]; 4. return []; 5. if (x < y) return [x, x – y, ‘result-set1’, 123.456]; else return [y, x + y, ‘result-set2’];
?:	Ternary conditional statement, similar to that of the above denoted if-statement. eg: 1. x ? y : z 2. x + 1 > 2y ? z + 1 : (w / v) 3. min(x,y) > z ? (x < y + 1) ? x : y : (w * v)
~	Evaluate each sub-expression, then return as the result the value of the last sub-expression. This is sometimes known as multiple sequence point evaluation. eg: ~(i := x + 1, j := y / z, k := sin(w/u)) == (sin(w/u))) ~{i := x + 1; j := y / z; k := sin(w/u)} == (sin(w/u)))
[*]	Evaluate any consequent for which its case statement is true. The return value will be either zero or the result of the last consequent to have been evaluated. eg: [] { case (x + 1) > (y – 2) : x := z / 2 + sin(y / pi); case (x + 2) < abs(y + 3) : w / 4 + min(5y,9); case (x + 3) == (y 4) : y := abs(z / 6) + 7y; }
[]	The vector size operator returns the size of the vector being actioned. eg: 1. v[] 2. max_size := max(v0[],v1[],v2[],v3[])

Pool Script event functions

Motions