444 lines
14 KiB
ReStructuredText
444 lines
14 KiB
ReStructuredText
=========================
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Internal Hy Documentation
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=========================
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.. note:: These bits are mostly useful for folks who hack on Hy itself,
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but can also be used for those delving deeper in macro programming.
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.. _models:
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Hy Models
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=========
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Introduction to Hy Models
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-------------------------
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Hy models are a very thin layer on top of regular Python objects,
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representing Hy source code as data. Models only add source position
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information, and a handful of methods to support clean manipulation of
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Hy source code, for instance in macros. To achieve that goal, Hy models
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are mixins of a base Python class and :ref:`HyObject`.
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.. _hyobject:
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HyObject
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~~~~~~~~
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``hy.models.HyObject`` is the base class of Hy models. It only
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implements one method, ``replace``, which replaces the source position
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of the current object with the one passed as argument. This allows us to
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keep track of the original position of expressions that get modified by
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macros, be that in the compiler or in pure hy macros.
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``HyObject`` is not intended to be used directly to instantiate Hy
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models, but only as a mixin for other classes.
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Compound Models
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---------------
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Parenthesized and bracketed lists are parsed as compound models by the
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Hy parser.
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Hy uses pretty-printing reprs for its compound models by default.
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If this is causing issues,
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it can be turned off globally by setting ``hy.models.PRETTY`` to ``False``,
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or temporarily by using the ``hy.models.pretty`` context manager.
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Hy also attempts to color pretty reprs using ``clint.textui.colored``.
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This module has a flag to disable coloring,
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and a method ``clean`` to strip colored strings of their color tags.
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.. _hysequence:
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HySequence
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~~~~~~~~~~
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``hy.models.HySequence`` is the abstract base class of "iterable" Hy
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models, such as HyExpression and HyList.
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Adding a HySequence to another iterable object reuses the class of the
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left-hand-side object, a useful behavior when you want to concatenate Hy
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objects in a macro, for instance.
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HySequences are (mostly) immutable: you can't add, modify, or remove
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elements. You can still append to a variable containing a HySequence with
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``+=`` and otherwise construct new HySequences out of old ones.
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.. _hylist:
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HyList
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~~~~~~
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``hy.models.HyList`` is a :ref:`HySequence` for bracketed ``[]``
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lists, which, when used as a top-level expression, translate to Python
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list literals in the compilation phase.
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.. _hyexpression:
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HyExpression
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~~~~~~~~~~~~
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``hy.models.HyExpression`` inherits :ref:`HySequence` for
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parenthesized ``()`` expressions. The compilation result of those
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expressions depends on the first element of the list: the compiler
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dispatches expressions between compiler special-forms, user-defined
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macros, and regular Python function calls.
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.. _hydict:
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HyDict
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~~~~~~
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``hy.models.HyDict`` inherits :ref:`HySequence` for curly-bracketed
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``{}`` expressions, which compile down to a Python dictionary literal.
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Atomic Models
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-------------
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In the input stream, double-quoted strings, respecting the Python
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notation for strings, are parsed as a single token, which is directly
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parsed as a :ref:`HyString`.
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An uninterrupted string of characters, excluding spaces, brackets,
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quotes, double-quotes and comments, is parsed as an identifier.
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Identifiers are resolved to atomic models during the parsing phase in
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the following order:
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- :ref:`HyInteger <hy_numeric_models>`
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- :ref:`HyFloat <hy_numeric_models>`
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- :ref:`HyComplex <hy_numeric_models>` (if the atom isn't a bare ``j``)
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- :ref:`HyKeyword` (if the atom starts with ``:``)
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- :ref:`HySymbol`
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.. _hystring:
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HyString
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~~~~~~~~
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``hy.models.HyString`` represents string literals (including bracket strings),
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which compile down to unicode string literals (``str``) in Python.
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``HyString``\s are immutable.
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Hy literal strings can span multiple lines, and are considered by the
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parser as a single unit, respecting the Python escapes for unicode
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strings.
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``HyString``\s have an attribute ``brackets`` that stores the custom
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delimiter used for a bracket string (e.g., ``"=="`` for ``#[==[hello
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world]==]`` and the empty string for ``#[[hello world]]``).
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``HyString``\s that are not produced by bracket strings have their
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``brackets`` set to ``None``.
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HyBytes
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~~~~~~~
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``hy.models.HyBytes`` is like ``HyString``, but for sequences of bytes.
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It inherits from ``bytes``.
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.. _hy_numeric_models:
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Numeric Models
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~~~~~~~~~~~~~~
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``hy.models.HyInteger`` represents integer literals, using the ``int``
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type.
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``hy.models.HyFloat`` represents floating-point literals.
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``hy.models.HyComplex`` represents complex literals.
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Numeric models are parsed using the corresponding Python routine, and
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valid numeric python literals will be turned into their Hy counterpart.
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.. _hysymbol:
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HySymbol
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~~~~~~~~
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``hy.models.HySymbol`` is the model used to represent symbols in the Hy
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language. Like ``HyString``, it inherits from ``str`` (or ``unicode`` on Python
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2).
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Symbols are :ref:`mangled <mangling>` when they are compiled
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to Python variable names.
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.. _hykeyword:
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HyKeyword
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~~~~~~~~~
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``hy.models.HyKeyword`` represents keywords in Hy. Keywords are
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symbols starting with a ``:``. See :ref:`syntax-keywords`.
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Hy Internal Theory
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==================
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.. _overview:
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Overview
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--------
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The Hy internals work by acting as a front-end to Python bytecode, so
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that Hy itself compiles down to Python Bytecode, allowing an unmodified
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Python runtime to run Hy code, without even noticing it.
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The way we do this is by translating Hy into an internal Python AST
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datastructure, and building that AST down into Python bytecode using
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modules from the Python standard library, so that we don't have to
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duplicate all the work of the Python internals for every single Python
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release.
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Hy works in four stages. The following sections will cover each step of Hy
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from source to runtime.
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.. _lexing:
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Steps 1 and 2: Tokenizing and Parsing
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-------------------------------------
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The first stage of compiling Hy is to lex the source into tokens that we can
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deal with. We use a project called rply, which is a really nice (and fast)
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parser, written in a subset of Python called rpython.
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The lexing code is all defined in ``hy.lex.lexer``. This code is mostly just
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defining the Hy grammar, and all the actual hard parts are taken care of by
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rply -- we just define "callbacks" for rply in ``hy.lex.parser``, which takes
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the tokens generated, and returns the Hy models.
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You can think of the Hy models as the "AST" for Hy, it's what Macros operate
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on (directly), and it's what the compiler uses when it compiles Hy down.
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.. seealso::
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Section :ref:`models` for more information on Hy models and what they mean.
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.. _compiling:
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Step 3: Hy Compilation to Python AST
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------------------------------------
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This is where most of the magic in Hy happens. This is where we take Hy AST
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(the models), and compile them into Python AST. A couple of funky things happen
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here to work past a few problems in AST, and working in the compiler is some
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of the most important work we do have.
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The compiler is a bit complex, so don't feel bad if you don't grok it on the
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first shot, it may take a bit of time to get right.
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The main entry-point to the Compiler is ``HyASTCompiler.compile``. This method
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is invoked, and the only real "public" method on the class (that is to say,
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we don't really promise the API beyond that method).
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In fact, even internally, we don't recurse directly hardly ever, we almost
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always force the Hy tree through ``compile``, and will often do this with
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sub-elements of an expression that we have. It's up to the Type-based dispatcher
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to properly dispatch sub-elements.
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All methods that preform a compilation are marked with the ``@builds()``
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decorator. You can either pass the class of the Hy model that it compiles,
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or you can use a string for expressions. I'll clear this up in a second.
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First Stage Type-Dispatch
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~~~~~~~~~~~~~~~~~~~~~~~~~
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Let's start in the ``compile`` method. The first thing we do is check the
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Type of the thing we're building. We look up to see if we have a method that
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can build the ``type()`` that we have, and dispatch to the method that can
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handle it. If we don't have any methods that can build that type, we raise
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an internal ``Exception``.
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For instance, if we have a ``HyString``, we have an almost 1-to-1 mapping of
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Hy AST to Python AST. The ``compile_string`` method takes the ``HyString``, and
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returns an ``ast.Str()`` that's populated with the correct line-numbers and
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content.
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Macro-Expand
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~~~~~~~~~~~~
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If we get a ``HyExpression``, we'll attempt to see if this is a known
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Macro, and push to have it expanded by invoking ``hy.macros.macroexpand``, then
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push the result back into ``HyASTCompiler.compile``.
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Second Stage Expression-Dispatch
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The only special case is the ``HyExpression``, since we need to create different
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AST depending on the special form in question. For instance, when we hit an
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``(if True True False)``, we need to generate a ``ast.If``, and properly
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compile the sub-nodes. This is where the ``@builds()`` with a String as an
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argument comes in.
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For the ``compile_expression`` (which is defined with an
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``@builds(HyExpression)``) will dispatch based on the string of the first
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argument. If, for some reason, the first argument is not a string, it will
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properly handle that case as well (most likely by raising an ``Exception``).
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If the String isn't known to Hy, it will default to create an ``ast.Call``,
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which will try to do a runtime call (in Python, something like ``foo()``).
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Issues Hit with Python AST
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~~~~~~~~~~~~~~~~~~~~~~~~~~
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Python AST is great; it's what's enabled us to write such a powerful project
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on top of Python without having to fight Python too hard. Like anything, we've
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had our fair share of issues, and here's a short list of the common ones you
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might run into.
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*Python differentiates between Statements and Expressions*.
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This might not sound like a big deal -- in fact, to most Python programmers,
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this will shortly become a "Well, yeah" moment.
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In Python, doing something like:
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``print for x in range(10): pass``, because ``print`` prints expressions, and
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``for`` isn't an expression, it's a control flow statement. Things like
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``1 + 1`` are Expressions, as is ``lambda x: 1 + x``, but other language
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features, such as ``if``, ``for``, or ``while`` are statements.
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Since they have no "value" to Python, this makes working in Hy hard, since
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doing something like ``(print (if True True False))`` is not just common, it's
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expected.
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As a result, we reconfigure things using a ``Result`` object, where we offer
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up any ``ast.stmt`` that need to get run, and a single ``ast.expr`` that can
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be used to get the value of whatever was just run. Hy does this by forcing
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assignment to things while running.
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As example, the Hy::
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(print (if True True False))
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Will turn into::
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if True:
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_temp_name_here = True
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else:
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_temp_name_here = False
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print(_temp_name_here)
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OK, that was a bit of a lie, since we actually turn that statement
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into::
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print(True if True else False)
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By forcing things into an ``ast.expr`` if we can, but the general idea holds.
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Step 4: Python Bytecode Output and Runtime
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------------------------------------------
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After we have a Python AST tree that's complete, we can try and compile it to
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Python bytecode by pushing it through ``eval``. From here on out, we're no
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longer in control, and Python is taking care of everything. This is why things
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like Python tracebacks, pdb and django apps work.
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Hy Macros
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=========
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.. _using-gensym:
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Using gensym for Safer Macros
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-----------------------------
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When writing macros, one must be careful to avoid capturing external variables
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or using variable names that might conflict with user code.
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We will use an example macro ``nif`` (see http://letoverlambda.com/index.cl/guest/chap3.html#sec_5
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for a more complete description.) ``nif`` is an example, something like a numeric ``if``,
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where based on the expression, one of the 3 forms is called depending on if the
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expression is positive, zero or negative.
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A first pass might be something like:
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.. code-block:: hy
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(defmacro nif [expr pos-form zero-form neg-form]
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`(do
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(setv obscure-name ~expr)
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(cond [(pos? obscure-name) ~pos-form]
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[(zero? obscure-name) ~zero-form]
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[(neg? obscure-name) ~neg-form])))
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where ``obscure-name`` is an attempt to pick some variable name as not to
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conflict with other code. But of course, while well-intentioned,
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this is no guarantee.
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The method :ref:`gensym` is designed to generate a new, unique symbol for just
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such an occasion. A much better version of ``nif`` would be:
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.. code-block:: hy
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(defmacro nif [expr pos-form zero-form neg-form]
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(setv g (gensym))
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`(do
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(setv ~g ~expr)
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(cond [(pos? ~g) ~pos-form]
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[(zero? ~g) ~zero-form]
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[(neg? ~g) ~neg-form])))
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This is an easy case, since there is only one symbol. But if there is
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a need for several gensym's there is a second macro :ref:`with-gensyms` that
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basically expands to a ``setv`` form:
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.. code-block:: hy
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(with-gensyms [a b c]
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...)
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expands to:
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.. code-block:: hy
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(do
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(setv a (gensym)
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b (gensym)
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c (gensym))
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...)
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so our re-written ``nif`` would look like:
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.. code-block:: hy
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(defmacro nif [expr pos-form zero-form neg-form]
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(with-gensyms [g]
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`(do
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(setv ~g ~expr)
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(cond [(pos? ~g) ~pos-form]
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[(zero? ~g) ~zero-form]
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[(neg? ~g) ~neg-form]))))
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Finally, though we can make a new macro that does all this for us. :ref:`defmacro/g!`
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will take all symbols that begin with ``g!`` and automatically call ``gensym`` with the
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remainder of the symbol. So ``g!a`` would become ``(gensym "a")``.
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Our final version of ``nif``, built with ``defmacro/g!`` becomes:
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.. code-block:: hy
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(defmacro/g! nif [expr pos-form zero-form neg-form]
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`(do
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(setv ~g!res ~expr)
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(cond [(pos? ~g!res) ~pos-form]
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[(zero? ~g!res) ~zero-form]
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[(neg? ~g!res) ~neg-form])))
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Checking Macro Arguments and Raising Exceptions
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-----------------------------------------------
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Hy Compiler Built-Ins
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=====================
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.. TODO: Write this.
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