6c93fc6ff1
- Removed links to non-updated code and badges. - Compressed `quickstart.rst` into a few sentences at the very start of the docs. - Added a "Why Hy?" chapter discussing Hy's features and comparing Hy to Python and other Lisps. - Rewrote the tutorial to be more accessible to non-Python programmers and to be greater in breadth but lesser in depth. - Cut down on the self-congratulatory manic tone and exclamation points, while keeping the jokes I liked best.
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344 lines
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========
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Tutorial
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========
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.. image:: _static/cuddles-transparent-small.png
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:alt: Karen Rustard's Cuddles
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This chapter provides a quick introduction to Hy. It assumes a basic background
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in programming, but no specific prior knowledge of Python or Lisp.
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Lisp-stick on a Python
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======================
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Let's start with the classic::
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(print "Hy, world!")
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This program calls the :func:`print` function, which, like all of Python's
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:ref:`built-in functions <py:built-in-funcs>`, is available in Hy.
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All of Python's :ref:`binary and unary operators <py:expressions>` are
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available, too, although ``==`` is spelled ``=`` in deference to Lisp
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tradition. Here's how we'd use the addition operator ``+``::
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(+ 1 3)
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This code returns ``4``. It's equivalent to ``1 + 3`` in Python and many other
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languages. Languages in the `Lisp
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<https://en.wikipedia.org/wiki/Lisp_(programming_language)>`_ family, including
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Hy, use a prefix syntax: ``+``, just like ``print`` or ``sqrt``, appears before
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all of its arguments. The call is delimited by parentheses, but the opening
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parenthesis appears before the operator being called instead of after it, so
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instead of ``sqrt(2)``, we write ``(sqrt 2)``. Multiple arguments, such as the
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two integers in ``(+ 1 3)``, are separated by whitespace. Many operators,
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including ``+``, allow more than two arguments: ``(+ 1 2 3)`` is equivalent to
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``1 + 2 + 3``.
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Here's a more complex example::
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(- (* (+ 1 3 88) 2) 8)
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This code returns ``176``. Why? We can see the infix equivalent with the
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command ``echo "(- (* (+ 1 3 88) 2) 8)" | hy2py``, which returns the Python
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code corresponding to the given Hy code, or by passing the ``--spy`` option to
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Hy when starting the REPL, which shows the Python equivalent of each input line
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before the result. The infix equivalent in this case is:
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.. code-block:: python
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((1 + 3 + 88) * 2) - 8
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To evaluate this infix expression, you'd of course evaluate the innermost
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parenthesized expression first and work your way outwards. The same goes for
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Lisp. Here's what we'd get by evaluating the above Hy code one step at a time::
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(- (* (+ 1 3 88) 2) 8)
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(- (* 92 2) 8)
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(- 184 8)
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176
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The basic unit of Lisp syntax, which is similar to a C or Python expression, is
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the **form**. ``92``, ``*``, and ``(* 92 2)`` are all forms. A Lisp program
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consists of a sequence of forms nested within forms. Forms are typically
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separated from each other by whitespace, but some forms, such as string
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literals (``"Hy, world!"``), can contain whitespace themselves. An
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**expression** is a form enclosed in parentheses; its first child form, called
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the **head**, determines what the expression does, and should generally be a
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function, macro, or special operator. Functions are the most ordinary sort of
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head, whereas macros (described in more detail below) are functions executed at
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compile-time instead and return code to be executed at run-time. Special
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operators are one of :ref:`a fixed set of names <special-forms>` that are
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hard-coded into the compiler, and used to implement everything else.
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Comments start with a ``;`` character and continue till the end of the line. A
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comment is functionally equivalent to whitespace. ::
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(print (** 2 64)) ; Max 64-bit unsigned integer value
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Although ``#`` isn't a comment character in Hy, a Hy program can begin with a
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`shebang line <https://en.wikipedia.org/wiki/Shebang_(Unix)>`_, which Hy itself
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will ignore::
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#!/usr/bin/env hy
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(print "Make me executable, and run me!")
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Literals
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========
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Hy has :ref:`literal syntax <syntax>` for all of the same data types that
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Python does. Here's an example of Hy code for each type and the Python
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equivalent.
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============== ================ =================
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Hy Python Type
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============== ================ =================
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``1`` ``1`` :class:`int`
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``1.2`` ``1.2`` :class:`float`
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``4j`` ``4j`` :class:`complex`
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``True`` ``True`` :class:`bool`
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``None`` ``None`` :class:`NoneType`
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``"hy"`` ``'hy'`` :class:`str`
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``b"hy"`` ``b'hy'`` :class:`bytes`
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``(, 1 2 3)`` ``(1, 2, 3)`` :class:`tuple`
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``[1 2 3]`` ``[1, 2, 3]`` :class:`list`
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``#{1 2 3}`` ``{1, 2, 3}`` :class:`set`
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``{1 2 3 4}`` ``{1: 2, 3: 4}`` :class:`dict`
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============== ================ =================
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In addition, Hy has a Clojure-style literal syntax for
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:class:`fractions.Fraction`: ``1/3`` is equivalent to ``fractions.Fraction(1,
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3)``.
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The Hy REPL prints output in Python syntax by default::
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=> [1 2 3]
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[1, 2, 3]
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But if you start Hy like this (a shell alias might be helpful)::
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$ hy --repl-output-fn=hy.contrib.hy-repr.hy-repr
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the interactive mode will use :ref:`hy-repr-fn` instead of Python's native
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``repr`` function to print out values, so you'll see values in Hy syntax::
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=> [1 2 3]
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[1 2 3]
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Basic operations
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================
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Set variables with :ref:`setv`::
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(setv zone-plane 8)
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Access the elements of a list, dictionary, or other data structure with
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:ref:`get`::
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(setv fruit ["apple" "banana" "cantaloupe"])
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(print (get fruit 0)) ; => apple
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(setv (get fruit 1) "durian")
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(print (get fruit 1)) ; => durian
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Access a range of elements in an ordered structure with :ref:`cut`::
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(print (cut "abcdef" 1 4)) ; => bcd
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Conditional logic can be built with :ref:`if`::
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(if (= 1 1)
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(print "Math works. The universe is safe.")
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(print "Math has failed. The universe is doomed."))
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As in this example, ``if`` is called like ``(if CONDITION THEN ELSE)``. It
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executes and returns the form ``THEN`` if ``CONDITION`` is true (according to
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:class:`bool`) and ``ELSE`` otherwise. If ``ELSE`` is omitted, ``None`` is used
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in its place.
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What if you want to use more than form in place of the ``THEN`` or ``ELSE``
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clauses, or in place of ``CONDITION``, for that matter? Use the special
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operator :ref:`do` (known more traditionally in Lisp as ``progn``), which
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combines several forms into one, returning the last::
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(if (do (print "Let's check.") (= 1 1))
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(do
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(print "Math works.")
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(print "The universe is safe."))
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(do
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(print "Math has failed.")
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(print "The universe is doomed.")))
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For branching on more than one case, try :ref:`cond`::
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(setv somevar 33)
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(cond
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[(> somevar 50)
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(print "That variable is too big!")]
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[(< somevar 10)
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(print "That variable is too small!")]
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[True
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(print "That variable is jussssst right!")])
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The macro ``(when CONDITION THEN-1 THEN-2 …)`` is shorthand for ``(if CONDITION
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(do THEN-1 THEN-2 …))``. ``unless`` works the same as ``when``, but inverts the
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condition with ``not``.
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Hy's basic loops are :ref:`while` and :ref:`for`::
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(setv x 3)
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(while (> x 0)
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(print x)
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(setv x (- x 1))) ; => 3 2 1
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(for [x [1 2 3]]
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(print x)) ; => 1 2 3
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A more functional way to iterate is provided by the comprehension forms such as
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:ref:`lfor`. Whereas ``for`` always returns ``None``, ``lfor`` returns a list
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with one element per iteration. ::
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(print (lfor x [1 2 3] (* x 2))) ; => [2, 4, 6]
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Functions, classes, and modules
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===============================
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Define named functions with :ref:`defn`::
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(defn fib [n]
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(if (< n 2)
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n
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(+ (fib (- n 1)) (fib (- n 2)))))
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(print (fib 8)) ; => 21
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Define anonymous functions with :ref:`fn`::
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(print (list (filter (fn [x] (% x 2)) (range 10))))
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; => [1, 3, 5, 7, 9]
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Special symbols in the parameter list of ``defn`` or ``fn`` allow you to
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indicate optional arguments, provide default values, and collect unlisted
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arguments::
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(defn test [a b &optional c [d "x"] &rest e]
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[a b c d e])
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(print (test 1 2)) ; => [1, 2, None, 'x', ()]
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(print (test 1 2 3 4 5 6 7)) ; => [1, 2, 3, 4, (5, 6, 7)]
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Set a function parameter by name with a ``:keyword``::
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(test 1 2 :d "y") ; => [1, 2, None, 'y', ()]
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Define classes with :ref:`defclass`::
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(defclass FooBar []
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(defn __init__ [self x]
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(setv self.x x))
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(defn get-x [self]
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self.x))
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Here we create a new instance ``fb`` of ``FooBar`` and access its attributes by
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various means::
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(setv fb (FooBar 15))
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(print fb.x) ; => 15
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(print (. fb x)) ; => 15
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(print (.get-x fb)) ; => 15
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(print (fb.get-x)) ; => 15
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Note that syntax like ``fb.x`` and ``fb.get-x`` only works when the object
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being invoked (``fb``, in this case) is a simple variable name. To get an
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attribute or call a method of an arbitrary form ``FORM``, you must use the
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syntax ``(. FORM x)`` or ``(.get-x FORM)``.
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Access an external module, whether written in Python or Hy, with
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:ref:`import`::
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(import math)
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(print (math.sqrt 2)) ; => 1.4142135623730951
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Python can import a Hy module like any other module so long as Hy itself has
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been imported first, which, of course, must have already happened if you're
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running a Hy program.
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Macros
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======
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Macros are the basic metaprogramming tool of Lisp. A macro is a function that
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is called at compile time (i.e., when a Hy program is being translated to
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Python :mod:`ast` objects) and returns code, which becomes part of the final
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program. Here's a simple example::
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(print "Executing")
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(defmacro m []
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(print "Now for a slow computation")
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(setv x (% (** 10 10 7) 3))
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(print "Done computing")
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x)
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(print "Value:" (m))
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(print "Done executing")
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If you run this program twice in a row, you'll see this::
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$ hy example.hy
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Now for a slow computation
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Done computing
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Executing
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Value: 1
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Done executing
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$ hy example.hy
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Executing
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Value: 1
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Done executing
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The slow computation is performed while compiling the program on its first
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invocation. Only after the whole program is compiled does normal execution
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begin from the top, printing "Executing". When the program is called a second
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time, it is run from the previously compiled bytecode, which is equivalent to
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simply::
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(print "Executing")
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(print "Value:" 1)
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(print "Done executing")
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Our macro ``m`` has an especially simple return value, an integer, which at
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compile-time is converted to an integer literal. In general, macros can return
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arbitrary Hy forms to be executed as code. There are several special operators
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and macros that make it easy to construct forms programmatically, such as
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:ref:`quote` (``'``), :ref:`quasiquote` (`````), :ref:`unquote` (``~``), and
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:ref:`defmacro!`. The previous chapter has :ref:`a simple example <do-while>`
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of using ````` and ``~`` to define a new control construct ``do-while``.
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Sometimes it's nice to be able to call a one-parameter macro without
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parentheses. Tag macros allow this. The name of a tag macro is often just one
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character long, but since Hy allows most Unicode characters in the name of a
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macro (or ordinary variable), you won't out of characters soon. ::
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=> (deftag ↻ [code]
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... (setv op (last code) params (list (butlast code)))
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... `(~op ~@params))
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=> #↻(1 2 3 +)
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6
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What if you want to use a macro that's defined in a different module?
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``import`` won't help, because it merely translates to a Python ``import``
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statement that's executed at run-time, and macros are expanded at compile-time,
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that is, during the translation from Hy to Python. Instead, use :ref:`require`,
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which imports the module and makes macros available at compile-time.
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``require`` uses the same syntax as ``import``. ::
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=> (require tutorial.macros)
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=> (tutorial.macros.rev (1 2 3 +))
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6
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Next steps
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==========
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You now know enough to be dangerous with Hy. You may now smile villainously and
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sneak off to your Hydeaway to do unspeakable things.
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Refer to Python's documention for the details of Python semantics, and the rest
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of this manual for Hy-specific features. Like Hy itself, the manual is
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incomplete, but :ref:`contributions <hacking>` are always welcome.
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