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740 lines
27 KiB
Markdown
740 lines
27 KiB
Markdown
# Hello, world!
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Following tradition, a simple Janet program will print "Hello, world!".
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```
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(print "Hello, world!")
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```
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Put the following code in a file named `hello.janet`, and run `./janet hello.janet`.
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The words "Hello, world!" should be printed to the console, and then the program
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should immediately exit. You now have a working janet program!
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Alternatively, run the program `./janet` without any arguments to enter a REPL,
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or read eval print loop. This is a mode where Janet functions like a calculator,
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reading some input from the user, evaluating it, and printing out the result, all
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in an infinite loop. This is a useful mode for exploring or prototyping in Janet.
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This hello world program is about the simplest program one can write, and consists of only
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a few pieces of syntax. This first element is the `print` symbol. This is a function
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that simply prints its arguments to the console. The second argument is the
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string literal "Hello, world!", which is the one and only argument to the
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print function. Lastly, the print symbol and the string literal are wrapped
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in parentheses, forming a tuple. In Janet, parentheses and brackets are interchangeable,
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brackets are used mostly when the resulting tuple is not a function call. The tuple
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above indicates that the function `print` is to be called with one argument, `"Hello, world"`.
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Like all lisps, all operations in Janet are in prefix notation; the name of the
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operator is the first value in the tuple, and the arguments passed to it are
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in the rest of the tuple.
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# A bit more - Arithmetic
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Any programming language will have some way to do arithmetic. Janet is no exception,
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and supports the basic arithmetic operators
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```
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# Prints 13
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# (1 + (2*2) + (10/5) + 3 + 4 + (5 - 6))
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(print (+ 1 (* 2 2) (/ 10 5) 3 4 (- 5 6)))
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```
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Just like the print function, all arithmetic operators are entered in
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prefix notation. Janet also supports the remainder operator, or `%`, which returns
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the remainder of division. For example, `(% 10 3)` is 1, and `(% 10.5 3)` is
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1.5. The lines that begin with `#` are comments.
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All janet numbers are IEEE 754 floating point numbers. They can be used to represent
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both integers and real numbers to a finite precision.
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## Numeric literals
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Numeric literals can be written in many ways. Numbers can be written in base 10, with
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underscores used to separate digits into groups. A decimal point can be used for floating
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point numbers. Numbers can also be written in other bases by prefixing the number with the desired
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base and the character 'r'. For example, 16 can be written as `16`, `1_6`, `16r10`, `4r100`, or `0x10`. The
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`0x` prefix can be used for hexadecimal as it is so common. The radix must be themselves written in base 10, and
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can be any integer from 2 to 36. For any radix above 10, use the letters as digits (not case sensitive).
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Numbers can also be in scientific notation such as `3e10`. A custom radix can be used as well
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as for scientific notation numbers, (the exponent will share the radix). For numbers in scientific
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notation with a radix besides 10, use the `&` symbol to indicate the exponent rather then `e`.
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## Arithmetic Functions
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Besides the 5 main arithmetic functions, janet also supports a number of math functions
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taken from the C library `<math.h>`, as well as bit-wise operators that behave like they
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do in C or Java. Functions like `math/sin`, `math/cos`, `math/log`, and `math/exp` will
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behave as expected to a C programmer. They all take either 1 or 2 numeric arguments and
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return a real number (never an integer!) Bit-wise functions are all prefixed with b.
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They are `bnot`, `bor`, `bxor`, `band`, `blshift`, `brshift`, and `brushift`. Bit-wise
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functions only work on integers.
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# Strings, Keywords and Symbols
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Janet supports several varieties of types that can be used as labels for things in
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your program. The most useful type for this purpose is the keyword type. A keyword
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begins with a semicolon, and then contains 0 or more alphanumeric or a few other common
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characters. For example, `:hello`, `:my-name`, `::`, and `:ABC123_-*&^%$` are all keywords.
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Keywords, symbols, and strings all behave similarly and can be used as keys for tables and structs.
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Symbols and keywords are optimized for fast equality checks, so are preferred for table keys.
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The difference between symbols and keywords is that keywords evaluate to themselves, while
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symbols evaluate to whatever they are bound to. To have a symbol evaluate to itself, it must be
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quoted.
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```lisp
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# Evaluates to :monday
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:monday
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# Will throw a compile error as monday is not defined
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monday
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# Quote it - evaluates to the symbol monday
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'monday
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# Or first define monday
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(def monday "It is monday")
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# Now the evaluation should work - monday evaluates to "It is monday"
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monday
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```
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The most common thing to do with a keyword is to check it for equality or use it as a key into
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a table or struct. Note that symbols, keywords and strings are all immutable. Besides making your
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code easier to reason about, it allows for many optimizations involving these types.
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```lisp
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# Evaluates to true
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(= :hello :hello)
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# Evaluates to false, everything in janet is case sensitive
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(= :hello :HeLlO)
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# Look up into a table - evaluates to 25
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(get {
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:name "John"
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:age 25
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:occupation "plumber"
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} :age)
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```
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Strings can be used similarly to keywords, but there primary usage is for defining either text
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or arbitrary sequences of bytes. Strings (and symbols) in janet are what is sometimes known as
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"8-bit clean"; they can hold any number of bytes, and are completely unaware of things like character
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encodings. This is completely compatible with ASCII and UTF-8, two of the most common character
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encodings. By being encoding agnostic, janet strings can be very simple, fast, and useful for
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for other uses besides holding text.
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Literal text can be entered inside quotes, as we have seen above.
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```
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"Hello, this is a string."
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# We can also add escape characters for newlines, double quotes, backslash, tabs, etc.
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"Hello\nThis is on line two\n\tThis is indented\n"
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# For long strings where you don't want to type a lot of escape characters,
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# you can use 1 or more backticks (`\``) to delimit a string.
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# To close this string, simply repeat the opening sequence of backticks
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``
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This is a string.
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Line 2
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Indented
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"We can just type quotes here", and backslashes \ no problem.
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``
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```
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# Functions
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Janet is a functional language - that means that one of the basic building blocks of your
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program will be defining functions (the other is using data structures). Because janet
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is a Lisp, functions are values just like numbers or strings - they can be passed around and
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created as needed.
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Functions can be defined with the `defn` macro, like so:
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```lisp
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(defn triangle-area
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"Calculates the area of a triangle."
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[base height]
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(print "calculating area of a triangle...")
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(* base height 0.5))
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```
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A function defined with `defn` consists of a name, a number of optional flags for def, and
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finally a function body. The example above is named triangle-area and takes two parameters named base and height. The body of the function will print a message and then evaluate to the area of the triangle.
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Once a function like the above one is defined, the programmer can use the `triangle-area`
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function just like any other, say `print` or `+`.
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```lisp
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# Prints "calculating area of a triangle..." and then "25"
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(print (triangle-area 5 10))
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```
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Note that when nesting function calls in other function calls like above (a call to triangle-area is
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nested inside a call to print), the inner function calls are evaluated first. Also, arguments to
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a function call are evaluated in order, from first argument to last argument).
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Because functions are first-class values like numbers or strings, they can be passed
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as arguments to other functions as well.
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```lisp
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(print triangle-area)
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```
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This prints the location in memory of the function triangle area.
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Functions don't need to have names. The `fn` keyword can be used to introduce function
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literals without binding them to a symbol.
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```lisp
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# Evaluates to 40
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((fn [x y] (+ x x y)) 10 20)
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# Also evaluates to 40
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((fn [x y &] (+ x x y)) 10 20)
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# Will throw an error about the wrong arity
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((fn [x] x) 1 2)
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# Will not throw an error about the wrong arity
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((fn [x &] x) 1 2)
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```
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The first expression creates an anonymous function that adds twice
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the first argument to the second, and then calls that function with arguments 10 and 20.
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This will return (10 + 10 + 20) = 40.
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There is a common macro `defn` that can be used for creating functions and immediately binding
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them to a name. `defn` works as expected at both the top level and inside another form. There is also
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the corresponding
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Note that putting an ampersand at the end of the argument list inhibits strict arity checking.
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This means that such a function will accept fewer or more arguments than specified.
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```lisp
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(defn myfun [x y]
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(+ x x y))
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# You can think of defn as a shorthand for def and fn together
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(def myfun-same (fn [x y]
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(+ x x Y)))
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(myfun 3 4) # -> 10
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```
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Janet has many macros provided for you (and you can write your own).
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Macros are just functions that take your source code
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and transform it into some other source code, usually automating some repetitive pattern for you.
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# Defs and Vars
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Values can be bound to symbols for later use using the keyword `def`. Using undefined
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symbols will raise an error.
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```lisp
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(def a 100)
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(def b (+ 1 a))
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(def c (+ b b))
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(def d (- c 100))
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```
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Bindings created with def have lexical scoping. Also, bindings created with def are immutable; they
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cannot be changed after definition. For mutable bindings, like variables in other programming
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languages, use the `var` keyword. The assignment special form `set` can then be used to update
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a var.
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```lisp
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(var myvar 1)
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(print myvar)
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(set myvar 10)
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(print myvar)
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```
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In the global scope, you can use the `:private` option on a def or var to prevent it from
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being exported to code that imports your current module. You can also add documentation to
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a function by passing a string the def or var command.
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```lisp
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(def mydef :private "This will have priavte scope. My doc here." 123)
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(var myvar "docstring here" 321)
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```
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## Scopes
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Defs and vars (collectively known as bindings) live inside what is called a scope. A scope is
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simply where the bindings are valid. If a binding is referenced outside of its scope, the compiler
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will throw an error. Scopes are useful for organizing your bindings and my extension your programs.
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There are two main ways to create a scope in Janet.
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The first is to use the `do` special form. `do` executes a series of statements in a scope
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and evaluates to the last statement. Bindings create inside the form do not escape outside
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of its scope.
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```lisp
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(def a :outera)
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(do
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(def a 1)
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(def b 2)
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(def c 3)
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(+ a b c)) # -> 6
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a # -> :outera
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b # -> compile error: "unknown symbol \"b\""
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c # -> compile error: "unknown symbol \"c\""
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```
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Any attempt to reference the bindings from the do form after it has finished
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executing will fail. Also notice who defining `a` inside the do form did not
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overwrite the original definition of `a` for the global scope.
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The second way to create a scope is to create a closure.
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The `fn` special form also introduces a scope just like
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the `do` special form.
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There is another built in macro, `let`, that does multiple defs at once, and then introduces a scope.
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`let` is a wrapper around a combination of defs and dos, and is the most "functional" way of
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creating bindings.
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```lisp
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(let [a 1
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b 2
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c 3]
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(+ a b c)) # -> 6
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```
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The above is equivalent to the example using `do` and `def`.
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This is the preferable form in most cases,
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but using do with multiple defs is fine as well.
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# Data Structures
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Once you have a handle on functions and the primitive value types, you may be wondering how
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to work with collections of things. Janet has a small number of core data structure types
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that are very versatile. Tables, Structs, Arrays, Tuples, Strings, and Buffers, are the 6 main
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built in data structure types. These data structures can be arranged in a useful table describing
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there relationship to each other.
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| | Mutable | Immutable |
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| ---------- | ------- | --------------- |
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| Indexed | Array | Tuple |
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| Dictionary | Table | Struct |
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| Bytes | Buffer | String |
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Indexed types are linear lists of elements than can be accessed in constant time with an integer index.
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Indexed types are backed by a single chunk of memory for fast access, and are indexed from 0 as in C.
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Dictionary types associate keys with values. The difference between dictionaries and indexed types
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is that dictionaries are not limited to integer keys. They are backed by a hashtable and also offer
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constant time lookup (and insertion for the mutable case).
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Finally, the 'bytes' abstraction is any type that contains a sequence of bytes. A 'bytes' value or byteseq associates
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integer keys (the indices) with integer values between 0 and 255 (the byte values). In this way,
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they behave much like Arrays and Tuples. However, one cannot put non integer values into a byteseq
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```lisp
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(def mytuple (tuple 1 2 3))
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(def myarray @(1 2 3))
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(def myarray (array 1 2 3))
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(def mystruct {
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:key "value"
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:key2 "another"
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1 2
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4 3})
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(def another-struct
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(struct :a 1 :b 2))
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(def my-table @{
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:a :b
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:c :d
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:A :qwerty})
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(def another-table
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(table 1 2 3 4))
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(def my-buffer @"thisismutable")
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(def my-buffer2 @```
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This is also mutable ":)"
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```)
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```
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To read the values in a data structure, use the get function. The first parameter is the data structure
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itself, and the second parameter is the key.
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```lisp
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(get @{:a 1} :a) # -> 1
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(get {:a 1} :a) # -> 1
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(get @[:a :b :c] 2) # -> :c
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(get (tuple "a" "b" "c") 1) # -> "b"
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(get @"hello, world" 1) # -> 101
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(get "hello, world" 0) # -> 104
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```
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### Destructuring
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In many cases, however, you do not need the `get` function at all. Janet supports destructuring, which
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means both the `def` and `var` special forms can extract values from inside structures themselves.
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```lisp
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# Before, we might do
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(def my-array @[:mary :had :a :little :lamb])
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(def lamb (get my-array 4))
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(print lamb) # Prints :lamb
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# Now, with destructuring,
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(def [_ _ _ _ lamb] my-array)
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(print lamb) # Again, prints :lamb
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# Destructuring works with tables as well
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(def person @{:name "Bob Dylan" :age 77}
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(def
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{:name person-name
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:age person-age} person)
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```
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To update a mutable data structure, use the `put` function. It takes 3 arguments, the data structure,
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the key, and the value, and returns the data structure. The allowed types keys and values
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depend on what data structure is passed in.
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```lisp
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(put @[] 100 :a)
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(put @{} :key "value")
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(put @"" 100 92)
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```
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Note that for Arrays and Buffers, putting an index that is outside the length of the data structure
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will extend the data structure and fill it with nils in the case of the Array,
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or 0s in the case of the Buffer.
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The last generic function for all data structures is the `length` function. This returns the number of
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values in a data structure (the number of keys in a dictionary type).
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# Flow Control
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Janet has only two built in primitives to change flow while inside a function. The first is the
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`if` special form, which behaves as expected in most functional languages. It takes two or three parameters:
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a condition, an expression to evaluate to if the condition is true (not nil or false),
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and an optional condition to evaluate to when the condition is nil or false. If the optional parameter
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is omitted, the if form evaluates to nil.
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```lisp
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(if (> 4 3)
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"4 is greater than 3"
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"4 is not greater then three") # Evaluates to the first statement
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(if true
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(print "Hey")) # Will print
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(if false
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(print "Oy!")) # Will not print
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```
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The second primitive control flow construct is the while loop. The while behaves much the same
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as in many other programming languages, including C, Java, and Python. The while loop takes
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two or more parameters: the first is a condition (like in the `if` statement), that is checked before
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every iteration of the loop. If it is nil or false, the while loop ends and evaluates to nil. Otherwise,
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the rest of the parameters will be evaluated sequentially and then the program will return to the beginning
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of the loop.
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```lisp
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# Loop from 100 down to 1 and print each time
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(var i 100)
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(while (pos? i)
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(print "the number is " i)
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(-- i))
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# Print ... until a random number in range [0, 1) is >= 0.9
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# (math/random evaluates to a value between 0 and 1)
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(while (> 0.9 (math/random))
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(print "..."))
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```
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Besides these special forms, Janet has many macros for both conditional testing and looping
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that are much better for the majority of cases. For conditional testing, the `cond`, `switch`, and
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`when` macros can be used to great effect. `cond` can be used for making an if-else chain, where using
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just raw if forms would result in many parentheses. `case` For looping, the `loop`, `seq`, and `generate`
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implement janet's form of list comprehension, as in Python or Clojure.
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# The Core Library
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Janet has a built in core library of over 300 functions and macros at the time of writing.
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While some of these functions may be refactored into separate modules, it is useful to get to know
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the core to avoid rewriting provided functions.
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For any given function, use the `doc` macro to view the documentation for it in the repl.
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```lisp
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(doc defn) -> Prints the documentation for "defn"
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```
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To see a list of all global functions in the repl, type the command
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```lisp
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(table/getproto *env*)
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# Or
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(all-symbols)
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```
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Which will print out every built-in global binding
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(it will not show your global bindings). To print all
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of your global bindings, just use \*env\*, which is a var
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that is bound to the current environment.
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The convention of surrounding a symbol in stars is taken from lisp
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and Clojure, and indicates a global dynamic variable rather than a normal
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definition. To get the static environment at the time of compilation, use the
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`_env` symbol.
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# Prototypes
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To support basic generic programming, Janet tables support a prototype
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table. A prototype table contains default values for a table if certain keys
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are not found in the original table. This allows many similar tables to share
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contents without duplicating memory.
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|
|
|
```lisp
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# One of many Object Oriented schemes that can
|
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# be implented in janet.
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(def proto1 @{:type :custom1
|
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:behave (fn [self x] (print "behaving " x))})
|
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(def proto2 @{:type :custom2
|
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:behave (fn [self x] (print "behaving 2 " x))})
|
|
|
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(def thing1 (table/setproto @{} proto1))
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(def thing2 (table/setproto @{} proto2))
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|
|
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(print thing1:type) # prints :custom1
|
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(print thing2:type) # prints :custom2
|
|
|
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(thing1:behave thing1 :a) # prints "behaving :a"
|
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(thing2:behave thing2 :b) # prints "behaving 2 :b"
|
|
```
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|
|
|
Looking up in a table with a prototype can be summed up with the following algorithm.
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|
|
|
1. `(get my-table my-key)` is called.
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2. my-table is checked for the key if my-key. If there is a value for the key, it is returned.
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3. if there is a prototype table for my-table, set `my-table = my-table's prototype` and got to 2.
|
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4. Return nil as the key was not found.
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|
|
|
Janet will check up to about a 1000 prototypes recursively by default before giving up and returning nil. This
|
|
is to prevent an infinite loop. This value can be changed by adjusting the `JANET_RECURSION_GUARD` value
|
|
in janet.h.
|
|
|
|
Note that Janet prototypes are not as expressive as metatables in Lua and many other languages.
|
|
This is by design, as adding Lua or Python like capabilities would not be technically difficult.
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|
Users should prefer plain data and functions that operate on them rather than mutable objects
|
|
with methods.
|
|
|
|
# Fibers
|
|
|
|
Janet has support for single-core asynchronous programming via coroutines, or fibers.
|
|
Fibers allow a process to stop and resume execution later, essentially enabling
|
|
multiple returns from a function. This allows many patterns such a schedules, generators,
|
|
iterators, live debugging, and robust error handling. Janet's error handling is actually built on
|
|
top of fibers (when an error is thrown, the parent fiber will handle the error).
|
|
|
|
A temporary return from a fiber is called a yield, and can be invoked with the `yield` function.
|
|
To resume a fiber that has been yielded, use the `resume` function. When resume is called on a fiber,
|
|
it will only return when that fiber either returns, yields, throws an error, or otherwise emits
|
|
a signal.
|
|
|
|
Different from traditional coroutines, Janet's fibers implement a signaling mechanism, which
|
|
is used to differentiate different kinds of returns. When a fiber yields or throws an error,
|
|
control is returned to the calling fiber. The parent fiber must then check what kind of state the
|
|
fiber is in to differentiate errors from return values from user defined signals.
|
|
|
|
To create a fiber, user the `fiber/new` function. The fiber constructor take one or two arguments.
|
|
The first, necessary argument is the function that the fiber will execute. This function must accept
|
|
an arity of zero. The next optional argument is a collection of flags checking what kinds of
|
|
signals to trap and return via `resume`. This is useful so
|
|
the programmer does not need to handle all different kinds of signals from a fiber. Any un-trapped signals
|
|
are simply propagated to the next fiber.
|
|
|
|
```lisp
|
|
(def f (fiber/new (fn []
|
|
(yield 1)
|
|
(yield 2)
|
|
(yield 3)
|
|
(yield 4)
|
|
5)))
|
|
|
|
# Get the status of the fiber (:alive, :dead, :debug, :new, :pending, or :user0-:user9)
|
|
(print (fiber/status f)) # -> :new
|
|
|
|
(print (resume f)) # -> prints 1
|
|
(print (resume f)) # -> prints 2
|
|
(print (resume f)) # -> prints 3
|
|
(print (resume f)) # -> prints 4
|
|
(print (fiber/status f)) # -> print :pending
|
|
(print (resume f)) # -> prints 5
|
|
(print (fiber/status f)) # -> print :dead
|
|
(print (resume f)) # -> throws an error because the fiber is dead
|
|
```
|
|
|
|
## Using Fibers to Capture Errors
|
|
|
|
Besides being used as coroutines, fibers can be used to implement error handling (exceptions).
|
|
|
|
```lisp
|
|
(defn my-function-that-errors [x]
|
|
(print "start function with " x)
|
|
(error "oops!")
|
|
(print "never gets here"))
|
|
|
|
# Use the :e flag to only trap errors.
|
|
(def f (fiber/new my-function-that-errors :e))
|
|
(def result (resume f))
|
|
(if (= (fiber/status f) :error)
|
|
(print "result contains the error")
|
|
(print "result contains the good result"))
|
|
```
|
|
|
|
# Macros
|
|
|
|
Janet supports macros like most lisps. A macro is like a function, but transforms
|
|
the code itself rather than data. They let you extend the syntax of the language itself.
|
|
|
|
You have seen some macros already. The `let`, `loop`, and `defn` forms are macros. When the compiler
|
|
sees a macro, it evaluates the macro and then compiles the result. We say the macro has been
|
|
*expanded* after the compiler evaluates it. A simple version of the `defn` macro can
|
|
be thought of as transforming code of the form
|
|
|
|
```lisp
|
|
(defn1 myfun [x] body)
|
|
```
|
|
into
|
|
```lisp
|
|
(def myfun (fn myfun [x] body))
|
|
```
|
|
|
|
We could write such a macro like so:
|
|
|
|
```lisp
|
|
(defmacro defn1 [name args body]
|
|
(tuple 'def name (tuple 'fn name args body)))
|
|
```
|
|
|
|
There are a couple of issues with this macro, but it will work for simple functions
|
|
quite well.
|
|
|
|
The first issue is that our defn2 macro can't define functions with multiple expressions
|
|
in the body. We can make the macro variadic, just like a function. Here is a second version
|
|
of this macro.
|
|
|
|
```lisp
|
|
(defmacro defn2 [name args & body]
|
|
(tuple 'def name (apply tuple 'fn name args body)))
|
|
```
|
|
|
|
Great! Now we can define functions with multiple elements in the body. We can still improve this
|
|
macro even more though. First, we can add a docstring to it. If someone is using the function later,
|
|
they can use `(doc defn3)` to get a description of the function. Next, we can rewrite the macro
|
|
using janet's builtin quasiquoting facilities.
|
|
|
|
```lisp
|
|
(defmacro defn3
|
|
"Defines a new function."
|
|
[name args & body]
|
|
~(def ,name (fn ,name ,args ,;body)))
|
|
```
|
|
|
|
This is functionally identical to our previous version `defn2`, but written in such
|
|
a way that the macro output is more clear. The leading tilde `~` is shorthand for the
|
|
`(quasiquote x)` special form, which is like `(quote x)` except we can unquote
|
|
expressions inside it. The comma in front of `name` and `args` is an unquote, which
|
|
allows us to put a value in the quasiquote. Without the unquote, the symbol \'name\'
|
|
would be put in the returned tuple. Without the unquote, every function we defined
|
|
would be called \'name\'!.
|
|
|
|
Similar to name, we must also unquote body. However, a normal unquote doesn't work.
|
|
See what happens if we use a normal unquote for body as well.
|
|
|
|
```lisp
|
|
(def name 'myfunction)
|
|
(def args '[x y z])
|
|
(defn body '[(print x) (print y) (print z)])
|
|
|
|
~(def ,name (fn ,name ,args ,body))
|
|
# -> (def myfunction (fn myfunction (x y z) ((print x) (print y) (print z))))
|
|
```
|
|
|
|
There is an extra set of parentheses around the body of our function! We don't
|
|
want to put the body *inside* the form `(fn args ...)`, we want to *splice* it
|
|
into the form. Luckily, janet has the `(splice x)` special form for this purpose,
|
|
and a shorthand for it, the ; character.
|
|
When combined with the unquote special, we get the desired output.
|
|
|
|
```lisp
|
|
~(def ,name (fn ,name ,args ,;body))
|
|
# -> (def myfunction (fn myfunction (x y z) (print x) (print y) (print z)))
|
|
```
|
|
|
|
## Hygiene
|
|
|
|
Sometime when we write macros, we must generate symbols for local bindings. Ignoring that
|
|
it could be written as a function, consider
|
|
the following macro
|
|
|
|
```lisp
|
|
(defmacro max1
|
|
"Get the max of two values."
|
|
[x y]
|
|
~(if (> ,x ,y) ,x ,y))
|
|
```
|
|
|
|
This almost works, but will evaluate both x and y twice. This is because both show up
|
|
in the macro twice. For example, `(max1 (do (print 1) 1) (do (print 2) 2))` will
|
|
print both 1 and 2 twice, which is surprising to a user of this macro.
|
|
|
|
We can do better:
|
|
|
|
```lisp
|
|
(defmacro max2
|
|
"Get the max of two values."
|
|
[x y]
|
|
~(let [x ,x
|
|
y ,y]
|
|
(if (> x y) x y)))
|
|
```
|
|
|
|
Now we have no double evaluation problem! But we now have an even more subtle problem.
|
|
What happens in the following code?
|
|
|
|
```lisp
|
|
(def x 10)
|
|
(max2 8 (+ x 4))
|
|
```
|
|
|
|
We want the max to be 14, but this will actually evaluate to 12! This can be understood
|
|
if we expand the macro. You can expand macro once in janet using the `(macex1 x)` function.
|
|
(To expand macros until there are no macros left to expand, use `(macex x)`. Be careful,
|
|
janet has many macros, so the full expansion may be almost unreadable).
|
|
|
|
```lisp
|
|
(macex1 '(max2 8 (+ x 4)))
|
|
# -> (let (x 8 y (+ x 4)) (if (> x y) x y))
|
|
```
|
|
|
|
After expansion, y wrongly refers to the x inside the macro (which is bound to 8) rather than the x defined
|
|
to be 10. The problem is the reuse of the symbol x inside the macro, which overshadowed the original
|
|
binding.
|
|
|
|
Janet provides a general solution to this problem in terms of the `(gensym)` function, which returns
|
|
a symbol which is guaranteed to be unique and not collide with any symbols defined previously. We can define
|
|
our macro once more for a fully correct macro.
|
|
|
|
```lisp
|
|
(defmacro max3
|
|
"Get the max of two values."
|
|
[x y]
|
|
(def $x (gensym))
|
|
(def $y (gensym))
|
|
~(let [,$x ,x
|
|
,$y ,y]
|
|
(if (> ,$x ,$y) ,$x ,$y)))
|
|
```
|
|
|
|
As you can see, macros are very powerful but also are prone to subtle bugs. You must remember that
|
|
at their core, macros are just functions that output code, and the code that they return must
|
|
work in many contexts!
|