Guide to NTSL2

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Overview

NTSL is the programming language used aboard the Station for modular computers, you can design a lot of interesting things with it, this guide will act as a starting place and reference for enterprising programmers aboard the Aurora.

Functions Reference

Global Functions

Global Functions These functions can be used globally, I presume.
print(x) Prints its argument to the output and appends a new line.
write(x) Prints its argument to the output.
type(x) Returns the type of x.
tostring(x) Returns X as string.
tonumber(x) Returns X as number.


Math Library

Math Library An assortment of math related functions.
math.sin(x) Returns the sine of X. Probably uses radians, maybe.
math.cos(x) Returns the cosine of X.
math.tan(x) Returns the tangent of X
math.asin(x) Returns the inverse sine of X, as in, what angle gives a sine of X. X is between -1 and 1.
math.acos(x) Inverse cosine function, x is between -1 and 1
math.atan(x, y) OR math.atan(x) Inverse tangent function, either from a pair of coordinates (x and y) or a slope (x)
math.floor(x[, r]) Rounds X to the greatest integer lower than it. Rounds to r places, or after the decimal point by default.
math.atan(x, y) OR math.atan(x) Inverse tangent function, either from a pair of coordinates (x and y) or a slope (x)
math.floor(x[, r]) Rounds X to the greatest integer lower than it. Rounds to r places, or after the decimal point by default.
math.atan(x, y) OR math.atan(x) Inverse tangent function, either from a pair of coordinates (x and y) or a slope (x)
math.floor(x[, r]) Rounds X to the greatest integer lower than it. Rounds to r places, or after the decimal point by default.
math.atan(x, y) OR math.atan(x) Inverse tangent function, either from a pair of coordinates (x and y) or a slope (x)
math.floor(x[, r]) Rounds X to the greatest integer lower than it. Rounds to r places, or after the decimal point by default.
math.acos(x) Inverse cosine function, x is between -1 and 1
math.ceil(x[, r]) Rounds X to the smallest integer greater than it. Rounds to r places, or after the decimal point by default.
math.round(x[, r]) Rounds X according to the principle of "round up on 5 or above, round down otherwise" Rounds to r places, or after the decimal point by default.
math.max(x, y) Returns the largest of its two arguments.
math.clamp(low, num, high) If num is lower than low, returns low. If num is higher than high, returns high. Otherwise, it returns numb. Equivalent to math.max(low, math.min(high, num))
math.random(high o math.random(low, high) math.random(high) returns a random decimal between 0 and high. math.random(low, high) returns a random number between low and high.
math.abs(x) Returns the absolute value of X.
math.deg(x) Converts x from radians to degrees.
math.rad(x) Converts x from degrees to radian.
math.pi Pi.

String Library

String Library

String Library These are strings.
string.sub(string, start[, end]) Returns the substring of string from position start to position end. If end is not specified, it is the end of the string.
string.match(string, pattern) Searches string for instances of pattern and returns the matched value of the matched groups. If there are multiple, then it returns as a list.. Can use regex.
string.gmatch(string, pattern) Returns an iterator function that finds all matches (similar to string.match) in a string.
string.gsub(string, pattern, replacement) Replaces all instances of pattern with replacement. Can use regex.
string.upper(string) Returns string but uppercase.
string.lower(string) Returns string but lowercase.
string.reverse(string) Reverses the string.



Term Library

Term Library These are terms.
term.set_foreground(r, g, b) Sets the text color to (r, g, b). Scaled from 0 - 1.
term.get_foreground() Returns the text color.
term.set_background(r, g, b) Sets the background color to (r, g, b). Scaled from 0 - 1.
term.get_background() Returns the background color.
term.set_cursor(x, y) Sets the cursor to the position x, y. The top left is 0, 0.
term.set_cursor_x(x) Sets the cursor's x position to x. The left side is 0.
term.set_cursor_y(y) Sets the cursor's y position to y. The top line is 0.
term.get_cursor(), term.get_cursor_x(), term.get_cursor_y() Returns the cursor's position, the cursor's x position, or the cursor's y position, respectively.
term.clear() Clears the screen with the preset background colour.
term.write() Same as write().
term.get_size() Gets the size of the terminal.
term.get_width() Returns the width of the terminal.
term.get_height() Returns the height of the terminal.
term.set_topic(x, y, width, height, topic_name) Creates a button/link at (x, y) with width width and height height, and a corresponding topic topic_name. If topic_name begins with ?, it allows you to input text, and the corresponding topic will be "topic_name?input". If text is written over this with write or similar, this will be cleared.



Syntax

  • Variables must start with a letter, but can otherwise contain any alphanumeric character. Variables can be assigned to with name = value. Local variables can be made with var name = value or local name = value.
  • Tables are values that can be indexed and can contain multiple values. They are also sometimes referred to as lists. They are constructed in the format {key1 = value1, key2 = value2, key3 = value3...}. The final value can have a comma after it, but it is not mandatory. Tables can be indexed in the form name[index].
  • Functions can be made in the following format: function funcname(arg1[ = defaultvalue1], arg2[ = defaultvalue2]){ ...code...

}

  • Arguments can have any name a variable can take, and can be assigned default values.
  • Varargs are also usable: function funcname(... args){...code...}
  • The various arguments provided to the function will be combined into a list and stored in the local variable args, or whatever name is provided. Brackets for arguments are optional if you have an anonymous function with one argument: funcname = function arg{...code…}
  • They can even be constructed in lambda calculus style: (arg1[=defaultvalue1], arg2[=defaultvalue2]) => {...code…} In the function style, function can be abbreviated to func. Varargs can also be used in the lambda calculus style. Single variable lambda calculus functions can be further simplified into the form arg => {...code...}
  • Member functions of an object can be called in the form object.function(object, other_arguments) or object::function(other_arguments). These function identically.
  • Strings can be constructed in three ways: "content", ‘content’, or `content`.
  • These are functionally identical except for in the last case, where expressions in square brackets will be evaluated and inserted into the string. This means that `con[expression]tent` is equivalent to instead performing two concatenation operations and one tostring call, "con" .. tostring(expression) .. "tent"

Program Flow/Structure

  • IF/ELSE:

IF/ELSE conditionals are part of the main program flow: if(condition){ ...code… } else { ...code... }

  • WHEN:

WHEN conditionals are similar to IF conditionals, but are asynchronous and occur outside of the main program’s flow. They also expose their ‘arguments’ to the scope of its block. A typical case is the topic variable which is set in term.topic events. when(event){ ...code… }

  • WITH:

WITH block exposes a list/table to the scope of its block, typically used for making library referencing easier: with(event){ ...code... }

An example is used in Telecomms scripts to save the constant references to tcomm: with(tcomm){ when onmessage{ broadcast(...) } }

  • FOR:

FOR loops have two alternate forms. List Iteration FOR Loop: for([var] in [list]){ ...code... } In this form, it iterates over the contents of [list], setting [var] equal to them one at a time. [list] can instead be an iterator function as well, such as string.gmatch OR Variable Iteration FOR Loop: for([i]=[initial]; [condition]; [step]){ ...code... } Where [i] is any variable, [initial] is the initial value, [condition] is any condition (presumably involving said variable, but not necessarily), [step] is some form of increment/decrement such as i++ or i--, ++i or --i, etc. This runs the for loop until [condition] is false, executing [step] after every iteration.

  • WHILE loop:

while(condition){ ...code... }

  • SWITCH block:

Evaluates [condition], runs whichever code block corresponds to that condition or, if none is found, the default. If a break or return isn’t reached, the program will fall through to the next condition. switch(condition){ :[default OR expression] ...code... :[default OR expression] ...code… … }

  • Ternary:

Evaluates [expression], if [expression] is true returns [on_true], otherwise returns [on_false]. expression ? on_true : on_false

  • Eval:

A very powerful, very dangerous function. Produces a function from NTSL2+ code contained in a string. Format is eval [expression].


  • Deop Operators:

Takes the form of either @operator or @expression. In the case of an operator, returns a function that behaves like that operator (With priority to binary operators). So @+ is equivalent to (a,b)=>a+b, though runs slightly faster. When an expression is used, this functions as a niladic operator, so is equivalent to ()=>expression. +, -, *, /, ^, %, and/&&, or/||, <, >, <=, >=, ==, and != all operate as expected. Concatenation is performed by [expr1] .. [expr2]. The length of the text representation of a string, or the number of elements in a list, can be found with #[expression]. Logical negation is performed with ![expression], binary negation is performed with ~[expression], decimal unary negation is performed with -[expression]. Integer division can be performed with [expression] // [expression]. Modulo can be performed with [expression] % [expression]. Bitwise operators are also available, such as |, &, <<, >>, &, and [expression] ~ [expression] (xor, do not confuse with unary base 2 negation)