| [/============================================================================== |
| Copyright (C) 2001-2010 Joel de Guzman |
| Copyright (C) 2001-2010 Hartmut Kaiser |
| |
| Distributed under the Boost Software License, Version 1.0. (See accompanying |
| file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) |
| ===============================================================================/] |
| |
| [section:lexer_introduction Introduction to __lex__] |
| |
| Lexical scanning is the process of analyzing the stream of input characters and |
| separating it into strings called tokens, separated by whitespace. |
| Most compiler texts start here, and devote several chapters to discussing |
| various ways to build scanners. __lex__ is a library built to take care of the |
| complexities of creating a lexer for your grammar (in this documentation we |
| will use the terms 'lexical analyzer', 'lexer' and 'scanner' interchangeably). |
| All that is needed to create a lexer is to know the set of patterns describing |
| the different tokens you want to recognize in the input. To make this a bit more |
| formal, here are some definitions: |
| |
| * A token is a sequence of consecutive characters having a collective meaning. |
| Tokens may have attributes specific to the token type, carrying additional |
| information about the matched character sequence. |
| * A pattern is a rule expressed as a regular expression and describing how a |
| particular token can be formed. For example, [^\[A-Za-z\]\[A-Za-z_0-9\]*] is |
| a pattern for a rule matching C++ identifiers. |
| * Characters between tokens are called whitespace; these include spaces, tabs, |
| newlines, and formfeeds. Many people also count comments as whitespace, |
| though since some tools such as lint look at comments, this method is not |
| perfect. |
| |
| [heading Why Use a Separate Lexer?] |
| |
| Typically, lexical scanning is done in a separate module from the parser, |
| feeding the parser with a stream of input tokens only. Theoretically it is |
| not necessary implement this separation as in the end there is only one set of |
| syntactical rules defining the language, so in theory we could write the whole |
| parser in one module. In fact, __qi__ allows you to write parsers without using a |
| lexer, parsing the input character stream directly, and for the most part this |
| is the way __spirit__ has been used since its invention. |
| |
| However, this separation has both practical and theoretical basis, and proves to |
| be very useful in practical applications. In 1956, Noam Chomsky defined the |
| "Chomsky Hierarchy" of grammars: |
| |
| * Type 0: Unrestricted grammars (e.g., natural languages) |
| * Type 1: Context-Sensitive grammars |
| * Type 2: Context-Free grammars |
| * Type 3: Regular grammars |
| |
| The complexity of these grammars increases from regular grammars being the |
| simplest to unrestricted grammars being the most complex. Similarly, the |
| complexity of pattern recognition for these grammars increases. Although, a few |
| features of some programming languages (such as C++) are Type 1, fortunately |
| for the most part programming languages can be described using only the Types 2 |
| and 3. The neat part about these two types is that they are well known and the |
| ways to parse them are well understood. It has been shown that any regular |
| grammar can be parsed using a state machine (finite automaton). Similarly, |
| context-free grammars can always be parsed using a push-down automaton |
| (essentially a state machine augmented by a stack). |
| |
| In real programming languages and practical grammars, the parts that can be |
| handled as regular expressions tend to be the lower-level pieces, such as the |
| definition of an identifier or of an integer value: |
| |
| letter := [a-zA-Z] |
| digit := [0-9] |
| |
| identifier := letter [ letter | digit ]* |
| integer := digit+ |
| |
| Higher level parts of practical grammars tend to be more complex and can't be |
| implemented using plain regular expressions. We need to store |
| information on the built-in hardware stack while recursing the grammar |
| hierarchy, and that is the preferred approach used for top-down |
| parsing. Since it takes a different kind of abstract machine to parse the two |
| types of grammars, it proved to be efficient to separate the lexical scanner |
| into a separate module which is built around the idea of a state machine. The |
| goal here is to use the simplest parsing technique needed for the job. |
| |
| Another, more practical, reason for separating the scanner from the parser is |
| the need for backtracking during parsing. The input data is a stream of |
| characters, which is often thought to be processed left to right without any |
| backtracking. Unfortunately, in practice most of the time that isn't possible. |
| Almost every language has certain keywords such as IF, FOR, and WHILE. The |
| decision if a certain character sequence actually comprises a keyword or just |
| an identifier often can be made only after seeing the first delimiter /after/ |
| it. In fact, this makes the process backtracking, since we need to store the |
| string long enough to be able to make the decision. The same is true for more |
| coarse grained language features such as nested IF/ELSE statements, where the |
| decision about to which IF belongs the last ELSE statement can be made only |
| after seeing the whole construct. |
| |
| So the structure of a conventional compiler often involves splitting up the |
| functions of the lower-level and higher-level parsing. The lexical scanner |
| deals with things at the character level, collecting characters into strings, |
| converting character sequence into different representations as integers, etc., |
| and passing them along to the parser proper as indivisible tokens. It's also |
| considered normal to let the scanner do additional jobs, such as identifying |
| keywords, storing identifiers in tables, etc. |
| |
| Now, __spirit__ follows this structure, where __lex__ can be used to implement |
| state machine based recognizers, while __qi__ can be used to build recognizers |
| for context free grammars. Since both modules are seamlessly integrated with |
| each other and with the C++ target language it is even possible to use the |
| provided functionality to build more complex grammar recognizers. |
| |
| [heading Advantages of using __lex__] |
| |
| The advantage of using __lex__ to create the lexical analyzer over using more |
| traditional tools such as __flex__ is its carefully crafted integration with |
| the __spirit__ library and the C++ host language. You don't need any external |
| tools to generate the code, your lexer will be perfectly integrated with the |
| rest of your program, making it possible to freely access any context |
| information and data structure. Since the C++ compiler sees all the code, it |
| will generate optimal code no matter what configuration options have been chosen |
| by the user. __lex__ gives you the vast majority of features you could get from |
| a similar __flex__ program without the need to leave C++ as a host language: |
| |
| * The definition of tokens is done using regular expressions (patterns) |
| * The token definitions can refer to special substitution strings (pattern |
| macros) simplifying pattern definitions |
| * The generated lexical scanner may have multiple start states |
| * It is possible to attach code to any of the token definitions; this code gets |
| executed whenever the corresponding token pattern has been matched |
| |
| Even if it is possible to use __lex__ to generate C++ code representing |
| the lexical analyzer (we will refer to that as the /static/ model, described in |
| more detail in the section __sec_lex_static_model__) - a model |
| very similar to the way __flex__ operates - we will mainly focus on the |
| opposite, the /dynamic/ model. You can directly integrate the token definitions |
| into your C++ program, building the lexical analyzer dynamically at runtime. The |
| dynamic model is something not supported by __flex__ or other lexical scanner |
| generators (such as __re2c__, __ragel__, etc.). This dynamic flexibility allows |
| you to speed up the development of your application. |
| |
| [heading The Library Structure of __lex__] |
| |
| The [link spirit.lexerflow figure] below shows a high level overview of how the |
| __lex__ library might be used in an application. __lex__ allows to create |
| lexical analyzers based on patterns. These patterns are regular expression |
| based rules used to define the different tokens to be recognized in the |
| character input sequence. The input sequence is expected to be provided to the |
| lexical analyzer as an arbitrary standard forward iterator. The lexical |
| analyzer itself exposes a standard forward iterator as well. The difference |
| here is that the exposed iterator provides access to the token sequence instead |
| of to the character sequence. The tokens in this sequence are constructed on |
| the fly by analyzing the underlying character sequence and matching this to the |
| patterns as defined by the application. |
| |
| [fig lexerflow.png..The Library structure and Common Flow of Information while using __lex__ in an application..spirit.lexerflow] |
| |
| |
| [endsect] |
