docs/tutorial/OCamlLangImpl1.rst - llvm - Git at Google

 =================================================
 Kaleidoscope: Tutorial Introduction and the Lexer
 =================================================

 .. contents::
    :local:

 Tutorial Introduction
 =====================

 Welcome to the "Implementing a language with LLVM" tutorial. This
 tutorial runs through the implementation of a simple language, showing
 how fun and easy it can be. This tutorial will get you up and started as
 well as help to build a framework you can extend to other languages. The
 code in this tutorial can also be used as a playground to hack on other
 LLVM specific things.

 The goal of this tutorial is to progressively unveil our language,
 describing how it is built up over time. This will let us cover a fairly
 broad range of language design and LLVM-specific usage issues, showing
 and explaining the code for it all along the way, without overwhelming
 you with tons of details up front.

 It is useful to point out ahead of time that this tutorial is really
 about teaching compiler techniques and LLVM specifically, *not* about
 teaching modern and sane software engineering principles. In practice,
 this means that we'll take a number of shortcuts to simplify the
 exposition. For example, the code leaks memory, uses global variables
 all over the place, doesn't use nice design patterns like
 `visitors <http://en.wikipedia.org/wiki/Visitor_pattern>`_, etc... but
 it is very simple. If you dig in and use the code as a basis for future
 projects, fixing these deficiencies shouldn't be hard.

 I've tried to put this tutorial together in a way that makes chapters
 easy to skip over if you are already familiar with or are uninterested
 in the various pieces. The structure of the tutorial is:

 -  `Chapter #1 <#language>`_: Introduction to the Kaleidoscope
    language, and the definition of its Lexer - This shows where we are
    going and the basic functionality that we want it to do. In order to
    make this tutorial maximally understandable and hackable, we choose
    to implement everything in Objective Caml instead of using lexer and
    parser generators. LLVM obviously works just fine with such tools,
    feel free to use one if you prefer.
 -  `Chapter #2 <OCamlLangImpl2.html>`_: Implementing a Parser and
    AST - With the lexer in place, we can talk about parsing techniques
    and basic AST construction. This tutorial describes recursive descent
    parsing and operator precedence parsing. Nothing in Chapters 1 or 2
    is LLVM-specific, the code doesn't even link in LLVM at this point.
    :)
 -  `Chapter #3 <OCamlLangImpl3.html>`_: Code generation to LLVM IR -
    With the AST ready, we can show off how easy generation of LLVM IR
    really is.
 -  `Chapter #4 <OCamlLangImpl4.html>`_: Adding JIT and Optimizer
    Support - Because a lot of people are interested in using LLVM as a
    JIT, we'll dive right into it and show you the 3 lines it takes to
    add JIT support. LLVM is also useful in many other ways, but this is
    one simple and "sexy" way to shows off its power. :)
 -  `Chapter #5 <OCamlLangImpl5.html>`_: Extending the Language:
    Control Flow - With the language up and running, we show how to
    extend it with control flow operations (if/then/else and a 'for'
    loop). This gives us a chance to talk about simple SSA construction
    and control flow.
 -  `Chapter #6 <OCamlLangImpl6.html>`_: Extending the Language:
    User-defined Operators - This is a silly but fun chapter that talks
    about extending the language to let the user program define their own
    arbitrary unary and binary operators (with assignable precedence!).
    This lets us build a significant piece of the "language" as library
    routines.
 -  `Chapter #7 <OCamlLangImpl7.html>`_: Extending the Language:
    Mutable Variables - This chapter talks about adding user-defined
    local variables along with an assignment operator. The interesting
    part about this is how easy and trivial it is to construct SSA form
    in LLVM: no, LLVM does *not* require your front-end to construct SSA
    form!
 -  `Chapter #8 <OCamlLangImpl8.html>`_: Conclusion and other useful
    LLVM tidbits - This chapter wraps up the series by talking about
    potential ways to extend the language, but also includes a bunch of
    pointers to info about "special topics" like adding garbage
    collection support, exceptions, debugging, support for "spaghetti
    stacks", and a bunch of other tips and tricks.

 By the end of the tutorial, we'll have written a bit less than 700 lines
 of non-comment, non-blank, lines of code. With this small amount of
 code, we'll have built up a very reasonable compiler for a non-trivial
 language including a hand-written lexer, parser, AST, as well as code
 generation support with a JIT compiler. While other systems may have
 interesting "hello world" tutorials, I think the breadth of this
 tutorial is a great testament to the strengths of LLVM and why you
 should consider it if you're interested in language or compiler design.

 A note about this tutorial: we expect you to extend the language and
 play with it on your own. Take the code and go crazy hacking away at it,
 compilers don't need to be scary creatures - it can be a lot of fun to
 play with languages!

 The Basic Language
 ==================

 This tutorial will be illustrated with a toy language that we'll call
 "`Kaleidoscope <http://en.wikipedia.org/wiki/Kaleidoscope>`_" (derived
 from "meaning beautiful, form, and view"). Kaleidoscope is a procedural
 language that allows you to define functions, use conditionals, math,
 etc. Over the course of the tutorial, we'll extend Kaleidoscope to
 support the if/then/else construct, a for loop, user defined operators,
 JIT compilation with a simple command line interface, etc.

 Because we want to keep things simple, the only datatype in Kaleidoscope
 is a 64-bit floating point type (aka 'float' in OCaml parlance). As
 such, all values are implicitly double precision and the language
 doesn't require type declarations. This gives the language a very nice
 and simple syntax. For example, the following simple example computes
 `Fibonacci numbers: <http://en.wikipedia.org/wiki/Fibonacci_number>`_

 ::

     # Compute the x'th fibonacci number.
     def fib(x)
       if x < 3 then
         1
       else
         fib(x-1)+fib(x-2)

     # This expression will compute the 40th number.
     fib(40)

 We also allow Kaleidoscope to call into standard library functions (the
 LLVM JIT makes this completely trivial). This means that you can use the
 'extern' keyword to define a function before you use it (this is also
 useful for mutually recursive functions). For example:

 ::

     extern sin(arg);
     extern cos(arg);
     extern atan2(arg1 arg2);

     atan2(sin(.4), cos(42))

 A more interesting example is included in Chapter 6 where we write a
 little Kaleidoscope application that `displays a Mandelbrot
 Set <OCamlLangImpl6.html#kicking-the-tires>`_ at various levels of magnification.

 Lets dive into the implementation of this language!

 The Lexer
 =========

 When it comes to implementing a language, the first thing needed is the
 ability to process a text file and recognize what it says. The
 traditional way to do this is to use a
 "`lexer <http://en.wikipedia.org/wiki/Lexical_analysis>`_" (aka
 'scanner') to break the input up into "tokens". Each token returned by
 the lexer includes a token code and potentially some metadata (e.g. the
 numeric value of a number). First, we define the possibilities:

 .. code-block:: ocaml

     (* The lexer returns these 'Kwd' if it is an unknown character, otherwise one of
      * these others for known things. *)
     type token =
       (* commands *)
       | Def | Extern

       (* primary *)
       | Ident of string | Number of float

       (* unknown *)
       | Kwd of char

 Each token returned by our lexer will be one of the token variant
 values. An unknown character like '+' will be returned as
 ``Token.Kwd '+'``. If the curr token is an identifier, the value will be
 ``Token.Ident s``. If the current token is a numeric literal (like 1.0),
 the value will be ``Token.Number 1.0``.

 The actual implementation of the lexer is a collection of functions
 driven by a function named ``Lexer.lex``. The ``Lexer.lex`` function is
 called to return the next token from standard input. We will use
 `Camlp4 <http://caml.inria.fr/pub/docs/manual-camlp4/index.html>`_ to
 simplify the tokenization of the standard input. Its definition starts
 as:

 .. code-block:: ocaml

     (*===----------------------------------------------------------------------===
      * Lexer
      *===----------------------------------------------------------------------===*)

     let rec lex = parser
       (* Skip any whitespace. *)
       | [< ' (' ' | '\n' | '\r' | '\t'); stream >] -> lex stream

 ``Lexer.lex`` works by recursing over a ``char Stream.t`` to read
 characters one at a time from the standard input. It eats them as it
 recognizes them and stores them in a ``Token.token`` variant. The
 first thing that it has to do is ignore whitespace between tokens. This
 is accomplished with the recursive call above.

 The next thing ``Lexer.lex`` needs to do is recognize identifiers and
 specific keywords like "def". Kaleidoscope does this with a pattern
 match and a helper function.

 .. code-block:: ocaml

       (* identifier: [a-zA-Z][a-zA-Z0-9] *)
       | [< ' ('A' .. 'Z' | 'a' .. 'z' as c); stream >] ->
           let buffer = Buffer.create 1 in
           Buffer.add_char buffer c;
           lex_ident buffer stream

     ...

     and lex_ident buffer = parser
       | [< ' ('A' .. 'Z' | 'a' .. 'z' | '0' .. '9' as c); stream >] ->
           Buffer.add_char buffer c;
           lex_ident buffer stream
       | [< stream=lex >] ->
           match Buffer.contents buffer with
           | "def" -> [< 'Token.Def; stream >]
           | "extern" -> [< 'Token.Extern; stream >]
           | id -> [< 'Token.Ident id; stream >]

 Numeric values are similar:

 .. code-block:: ocaml

       (* number: [0-9.]+ *)
       | [< ' ('0' .. '9' as c); stream >] ->
           let buffer = Buffer.create 1 in
           Buffer.add_char buffer c;
           lex_number buffer stream

     ...

     and lex_number buffer = parser
       | [< ' ('0' .. '9' | '.' as c); stream >] ->
           Buffer.add_char buffer c;
           lex_number buffer stream
       | [< stream=lex >] ->
           [< 'Token.Number (float_of_string (Buffer.contents buffer)); stream >]

 This is all pretty straight-forward code for processing input. When
 reading a numeric value from input, we use the ocaml ``float_of_string``
 function to convert it to a numeric value that we store in
 ``Token.Number``. Note that this isn't doing sufficient error checking:
 it will raise ``Failure`` if the string "1.23.45.67". Feel free to
 extend it :). Next we handle comments:

 .. code-block:: ocaml

       (* Comment until end of line. *)
       | [< ' ('#'); stream >] ->
           lex_comment stream

     ...

     and lex_comment = parser
       | [< ' ('\n'); stream=lex >] -> stream
       | [< 'c; e=lex_comment >] -> e
       | [< >] -> [< >]

 We handle comments by skipping to the end of the line and then return
 the next token. Finally, if the input doesn't match one of the above
 cases, it is either an operator character like '+' or the end of the
 file. These are handled with this code:

 .. code-block:: ocaml

       (* Otherwise, just return the character as its ascii value. *)
       | [< 'c; stream >] ->
           [< 'Token.Kwd c; lex stream >]

       (* end of stream. *)
       | [< >] -> [< >]

 With this, we have the complete lexer for the basic Kaleidoscope
 language (the `full code listing <OCamlLangImpl2.html#full-code-listing>`_ for the
 Lexer is available in the `next chapter <OCamlLangImpl2.html>`_ of the
 tutorial). Next we'll `build a simple parser that uses this to build an
 Abstract Syntax Tree <OCamlLangImpl2.html>`_. When we have that, we'll
 include a driver so that you can use the lexer and parser together.

 `Next: Implementing a Parser and AST <OCamlLangImpl2.html>`_
	=================================================
	Kaleidoscope: Tutorial Introduction and the Lexer
	=================================================

	.. contents::
	:local:

	Tutorial Introduction
	=====================

	Welcome to the "Implementing a language with LLVM" tutorial. This
	tutorial runs through the implementation of a simple language, showing
	how fun and easy it can be. This tutorial will get you up and started as
	well as help to build a framework you can extend to other languages. The
	code in this tutorial can also be used as a playground to hack on other
	LLVM specific things.

	The goal of this tutorial is to progressively unveil our language,
	describing how it is built up over time. This will let us cover a fairly
	broad range of language design and LLVM-specific usage issues, showing
	and explaining the code for it all along the way, without overwhelming
	you with tons of details up front.

	It is useful to point out ahead of time that this tutorial is really
	about teaching compiler techniques and LLVM specifically, not about
	teaching modern and sane software engineering principles. In practice,
	this means that we'll take a number of shortcuts to simplify the
	exposition. For example, the code leaks memory, uses global variables
	all over the place, doesn't use nice design patterns like
	`visitors <http://en.wikipedia.org/wiki/Visitor_pattern>`_, etc... but
	it is very simple. If you dig in and use the code as a basis for future
	projects, fixing these deficiencies shouldn't be hard.

	I've tried to put this tutorial together in a way that makes chapters
	easy to skip over if you are already familiar with or are uninterested
	in the various pieces. The structure of the tutorial is:

	- `Chapter #1 <#language>`_: Introduction to the Kaleidoscope
	language, and the definition of its Lexer - This shows where we are
	going and the basic functionality that we want it to do. In order to
	make this tutorial maximally understandable and hackable, we choose
	to implement everything in Objective Caml instead of using lexer and
	parser generators. LLVM obviously works just fine with such tools,
	feel free to use one if you prefer.
	- `Chapter #2 <OCamlLangImpl2.html>`_: Implementing a Parser and
	AST - With the lexer in place, we can talk about parsing techniques
	and basic AST construction. This tutorial describes recursive descent
	parsing and operator precedence parsing. Nothing in Chapters 1 or 2
	is LLVM-specific, the code doesn't even link in LLVM at this point.
	:)
	- `Chapter #3 <OCamlLangImpl3.html>`_: Code generation to LLVM IR -
	With the AST ready, we can show off how easy generation of LLVM IR
	really is.
	- `Chapter #4 <OCamlLangImpl4.html>`_: Adding JIT and Optimizer
	Support - Because a lot of people are interested in using LLVM as a
	JIT, we'll dive right into it and show you the 3 lines it takes to
	add JIT support. LLVM is also useful in many other ways, but this is
	one simple and "sexy" way to shows off its power. :)
	- `Chapter #5 <OCamlLangImpl5.html>`_: Extending the Language:
	Control Flow - With the language up and running, we show how to
	extend it with control flow operations (if/then/else and a 'for'
	loop). This gives us a chance to talk about simple SSA construction
	and control flow.
	- `Chapter #6 <OCamlLangImpl6.html>`_: Extending the Language:
	User-defined Operators - This is a silly but fun chapter that talks
	about extending the language to let the user program define their own
	arbitrary unary and binary operators (with assignable precedence!).
	This lets us build a significant piece of the "language" as library
	routines.
	- `Chapter #7 <OCamlLangImpl7.html>`_: Extending the Language:
	Mutable Variables - This chapter talks about adding user-defined
	local variables along with an assignment operator. The interesting
	part about this is how easy and trivial it is to construct SSA form
	in LLVM: no, LLVM does not require your front-end to construct SSA
	form!
	- `Chapter #8 <OCamlLangImpl8.html>`_: Conclusion and other useful
	LLVM tidbits - This chapter wraps up the series by talking about
	potential ways to extend the language, but also includes a bunch of
	pointers to info about "special topics" like adding garbage
	collection support, exceptions, debugging, support for "spaghetti
	stacks", and a bunch of other tips and tricks.

	By the end of the tutorial, we'll have written a bit less than 700 lines
	of non-comment, non-blank, lines of code. With this small amount of
	code, we'll have built up a very reasonable compiler for a non-trivial
	language including a hand-written lexer, parser, AST, as well as code
	generation support with a JIT compiler. While other systems may have
	interesting "hello world" tutorials, I think the breadth of this
	tutorial is a great testament to the strengths of LLVM and why you
	should consider it if you're interested in language or compiler design.

	A note about this tutorial: we expect you to extend the language and
	play with it on your own. Take the code and go crazy hacking away at it,
	compilers don't need to be scary creatures - it can be a lot of fun to
	play with languages!

	The Basic Language
	==================

	This tutorial will be illustrated with a toy language that we'll call
	"`Kaleidoscope <http://en.wikipedia.org/wiki/Kaleidoscope>`_" (derived
	from "meaning beautiful, form, and view"). Kaleidoscope is a procedural
	language that allows you to define functions, use conditionals, math,
	etc. Over the course of the tutorial, we'll extend Kaleidoscope to
	support the if/then/else construct, a for loop, user defined operators,
	JIT compilation with a simple command line interface, etc.

	Because we want to keep things simple, the only datatype in Kaleidoscope
	is a 64-bit floating point type (aka 'float' in OCaml parlance). As
	such, all values are implicitly double precision and the language
	doesn't require type declarations. This gives the language a very nice
	and simple syntax. For example, the following simple example computes
	`Fibonacci numbers: <http://en.wikipedia.org/wiki/Fibonacci_number>`_

	::

	# Compute the x'th fibonacci number.
	def fib(x)
	if x < 3 then
	1
	else
	fib(x-1)+fib(x-2)

	# This expression will compute the 40th number.
	fib(40)

	We also allow Kaleidoscope to call into standard library functions (the
	LLVM JIT makes this completely trivial). This means that you can use the
	'extern' keyword to define a function before you use it (this is also
	useful for mutually recursive functions). For example:

	::

	extern sin(arg);
	extern cos(arg);
	extern atan2(arg1 arg2);

	atan2(sin(.4), cos(42))

	A more interesting example is included in Chapter 6 where we write a
	little Kaleidoscope application that `displays a Mandelbrot
	Set <OCamlLangImpl6.html#kicking-the-tires>`_ at various levels of magnification.

	Lets dive into the implementation of this language!

	The Lexer
	=========

	When it comes to implementing a language, the first thing needed is the
	ability to process a text file and recognize what it says. The
	traditional way to do this is to use a
	"`lexer <http://en.wikipedia.org/wiki/Lexical_analysis>`_" (aka
	'scanner') to break the input up into "tokens". Each token returned by
	the lexer includes a token code and potentially some metadata (e.g. the
	numeric value of a number). First, we define the possibilities:

	.. code-block:: ocaml

	(* The lexer returns these 'Kwd' if it is an unknown character, otherwise one of
	* these others for known things. *)
	type token =
	(* commands *)
	\| Def \| Extern

	(* primary *)
	\| Ident of string \| Number of float

	(* unknown *)
	\| Kwd of char

	Each token returned by our lexer will be one of the token variant
	values. An unknown character like '+' will be returned as
	``Token.Kwd '+'``. If the curr token is an identifier, the value will be
	``Token.Ident s``. If the current token is a numeric literal (like 1.0),
	the value will be ``Token.Number 1.0``.

	The actual implementation of the lexer is a collection of functions
	driven by a function named ``Lexer.lex``. The ``Lexer.lex`` function is
	called to return the next token from standard input. We will use
	`Camlp4 <http://caml.inria.fr/pub/docs/manual-camlp4/index.html>`_ to
	simplify the tokenization of the standard input. Its definition starts
	as:

	.. code-block:: ocaml

	(*===----------------------------------------------------------------------===
	* Lexer
	===----------------------------------------------------------------------===)

	let rec lex = parser
	(* Skip any whitespace. *)
	\| [< ' (' ' \| '\n' \| '\r' \| '\t'); stream >] -> lex stream

	``Lexer.lex`` works by recursing over a ``char Stream.t`` to read
	characters one at a time from the standard input. It eats them as it
	recognizes them and stores them in a ``Token.token`` variant. The
	first thing that it has to do is ignore whitespace between tokens. This
	is accomplished with the recursive call above.

	The next thing ``Lexer.lex`` needs to do is recognize identifiers and
	specific keywords like "def". Kaleidoscope does this with a pattern
	match and a helper function.

	.. code-block:: ocaml

	(* identifier: [a-zA-Z][a-zA-Z0-9] *)
	\| [< ' ('A' .. 'Z' \| 'a' .. 'z' as c); stream >] ->
	let buffer = Buffer.create 1 in
	Buffer.add_char buffer c;
	lex_ident buffer stream

	...

	and lex_ident buffer = parser
	\| [< ' ('A' .. 'Z' \| 'a' .. 'z' \| '0' .. '9' as c); stream >] ->
	Buffer.add_char buffer c;
	lex_ident buffer stream
	\| [< stream=lex >] ->
	match Buffer.contents buffer with
	\| "def" -> [< 'Token.Def; stream >]
	\| "extern" -> [< 'Token.Extern; stream >]
	\| id -> [< 'Token.Ident id; stream >]

	Numeric values are similar:

	.. code-block:: ocaml

	(* number: [0-9.]+ *)
	\| [< ' ('0' .. '9' as c); stream >] ->
	let buffer = Buffer.create 1 in
	Buffer.add_char buffer c;
	lex_number buffer stream

	...

	and lex_number buffer = parser
	\| [< ' ('0' .. '9' \| '.' as c); stream >] ->
	Buffer.add_char buffer c;
	lex_number buffer stream
	\| [< stream=lex >] ->
	[< 'Token.Number (float_of_string (Buffer.contents buffer)); stream >]

	This is all pretty straight-forward code for processing input. When
	reading a numeric value from input, we use the ocaml ``float_of_string``
	function to convert it to a numeric value that we store in
	``Token.Number``. Note that this isn't doing sufficient error checking:
	it will raise ``Failure`` if the string "1.23.45.67". Feel free to
	extend it :). Next we handle comments:

	.. code-block:: ocaml

	(* Comment until end of line. *)
	\| [< ' ('#'); stream >] ->
	lex_comment stream

	...

	and lex_comment = parser
	\| [< ' ('\n'); stream=lex >] -> stream
	\| [< 'c; e=lex_comment >] -> e
	\| [< >] -> [< >]

	We handle comments by skipping to the end of the line and then return
	the next token. Finally, if the input doesn't match one of the above
	cases, it is either an operator character like '+' or the end of the
	file. These are handled with this code:

	.. code-block:: ocaml

	(* Otherwise, just return the character as its ascii value. *)
	\| [< 'c; stream >] ->
	[< 'Token.Kwd c; lex stream >]

	(* end of stream. *)
	\| [< >] -> [< >]

	With this, we have the complete lexer for the basic Kaleidoscope
	language (the `full code listing <OCamlLangImpl2.html#full-code-listing>`_ for the
	Lexer is available in the `next chapter <OCamlLangImpl2.html>`_ of the
	tutorial). Next we'll `build a simple parser that uses this to build an
	Abstract Syntax Tree <OCamlLangImpl2.html>`_. When we have that, we'll
	include a driver so that you can use the lexer and parser together.

	`Next: Implementing a Parser and AST <OCamlLangImpl2.html>`_