janet/doc/intro.md

Dst Language Introduction

Dst is a dynamic, lightweight programming language with strong functional capabilities as well as support for imperative programming. It to be used for short lived scripts as well as for building real programs. It can also be extended with native code (C modules) for better performance and interfacing with existing software. Dst takes ideas from Lua, Scheme, Clojure, Smalltalk, and a whole bunch of other dynamic languages.

Hello, world!

Following tradition, a simple Dst program will simply print "Hello, world!".

(print "Hello, world!")

Put the following code in a file call hello.dst, and run ./dst hello.dst. The words "Hello, world!" should be printed to the console, and then the program should immediately exit. You now have a working dst program!

Alternatively, run the program ./dst without any arguments to enter a REPL, or read eval print loop. This is a mode where Dst functions like a calculator, reading some input from stdin, evaluating it, and printing out the result, all in an inifinte loop. This is a useful mode for exploring or prototyping in Dst.

This is about the simplest program one can write, and consists of precisely three elements. This first element is the print symbol. This is a function that simply prints its arguments to standard out. The second argument is the string literal "Hello, world!", which is the one and only argument to the print function. Lastly, the print symbol and the string literal are wrapped in parentheses, forming a tuple. In Dst, parentheses and brackets are interchangeable, brackets are used mostly when the resulting tuple is not a function call. The tuple above indicates that the function print is to be called with one argument, "Hello, world".

Like all lisps, all operations in Dst are in prefix notation; the name of the operator is the first value in the tuple, and the arguments passed to it are in the rest of the tuple.

A bit more - Arithmetic

Any programming language will have some way to do arithmetic.

# Prints 13
# (1 + (2*2) + (10/5) + 3 + 4 + (5 - 6))
(print (+ 1 (* 2 2) (/ 10 5) 3 4 (- 5 6)))

Just like the print function, all arithmetic operators are entered in prefix notation. Dst also supports the modulo operator, or %, which returns the remainder of integer division. For example, (% 10 3) is 1, and (% 10.5 3) is 1.5. The lines that begin with # are comments.

Dst actually has to flavors of numbers; integers and real numbers. Integers are any integer value between -2,147,483,648 and 2,147,483,647 (32 bit signed integer). Reals are real numbers, and are represented by IEEE-754 double precision floating point numbers. That means that they can represent any number an integer can represent, as well fractions to very high precision.

Although real numbers can represent any value an integer can, try to distinguish between real numbers and integers in your program. If you are using a number to index into a structure, you probably want integers. Otherwise, you may want to use reals (this is only a rule of thumb).

Arithmetic operator will convert integers to real numbers if needed, but real numbers will not be converted to integers, as not all real numbers can be safely convert to integers.

Numeric literals

Numeric literals can be written in many ways. Numbers can be written in base 10, with underscores used to separate digits into groups. A decimal point can be used for floating point numbers. Numbers can also be written in other bases by prefixing the number with the desired base and the character 'r'. For example, 16 can be written as 16, 1_6, 16r10, 4r100, or 0x10. The 0x prefix can be used for hexadecimal as it is so common. The radix must be themselves written in base 10, and can be any integer from 2 to 36. For any radix above 10, use the letters as digits (not case sensitive).

Numbers can also be in scientific notation such as 3e10. A custom radix can be used as well as for scientific notation numbers, (the exponent will share the radix). For numbers in scientific notation with a radix besides 10, use the & symbol to indicate the exponent rather then e.

Functions

Dst is a functional language - that means that one of the basic building blocks of your program will be defining functions (the other is using data structures). Because dst is a Lisp, functions are values just like numbers or strings - they can be passed around and created as needed.

Functions can be defined with the defn macro, like so:

(defn triangle-area [base height]
 (print "calculating area of a triangle...")
 (* base height 0.5))

A function defined with defn has a number of parts. First, it has it's name, triangle-area. This is just a symbol used to access the function later. Next is the list of parameters this function takes, in this case two parameters named base and height. Lastly, a function made with defn has a number of body statements, which get executed each time the function is called. The last form in the body is what the function evaluates to, or returns.

Once a function like the above one is defined, the programmer can use the triangle-area function just like any other, say print or +.

# Prints "calculating area of a triangle..." and then "25"
(print (triangle-area 5 10))

Note that when nesting function calls in other function calls like above (a call to triangle-area is nested inside a call to print), the inner function calls are evaluated first. Also, arguments to a function call are evaluated in order, from first argument to last argument).

Because functions are first-class values like numbers or strings, they can be passed as arguments to other functions as well

(print triangle-area)

Prints the location in memory of the function triangle area. This idea can be used to build some powerful constructs purely out of functions, or closures as they are known in many contexts.

Functions don't need to have names. The fn keyword can be used to introduce function literals without binding them to a symbol.

# Evaluates to 40
((fn [x y] (+ x x y)) 10 20)

The above expression first creates an anonymous function that adds twice the first argument to the second, and then calls that function with arguments 10 and 20. This will return (10 + 10 + 20) = 40.

Defs and Vars

Values can be bound to symbols for later use using the keyword def. Using undefined symbols will raise an error.

(def a 100)
(def b (+ 1 a))
(def c (+ b b))
(def d (- c 100))

Bindings created with def have lexical scoping. Also, bindings created with def are immutable; they cannot be changed after definition. For mutable bindings, like variables in other programming languages, use the var keyword. The assignment special form := can then be used to update a var.

(var myvar 1)
(print myvar)
(:= myvar 10)
(print myvar)