@c -*-texinfo-*- @c This is part of the GNU Guile Reference Manual. @c Copyright (C) 1996, 1997, 2000, 2001, 2002, 2003, 2004, 2006, 2010, 2011, 2013 @c Free Software Foundation, Inc. @c See the file guile.texi for copying conditions. @node Introduction @chapter Introduction Guile is an implementation of the Scheme programming language. Scheme (@url{http://schemers.org/}) is an elegant and conceptually simple dialect of Lisp, originated by Guy Steele and Gerald Sussman, and since evolved by the series of reports known as RnRS (the @tex Revised$^n$ @end tex @ifnottex Revised^n @end ifnottex Reports on Scheme). Unlike, for example, Python or Perl, Scheme has no benevolent dictator. There are many Scheme implementations, with different characteristics and with communities and academic activities around them, and the language develops as a result of the interplay between these. Guile's particular characteristics are that @itemize @item it is easy to combine with other code written in C @item it has a historical and continuing connection with the GNU Project @item it emphasizes interactive and incremental programming @item it actually supports several languages, not just Scheme. @end itemize @noindent The next few sections explain what we mean by these points. The sections after that cover how you can obtain and install Guile, and the typographical conventions that we use in this manual. @menu * Guile and Scheme:: * Combining with C:: * Guile and the GNU Project:: * Interactive Programming:: * Supporting Multiple Languages:: * Obtaining and Installing Guile:: * Organisation of this Manual:: * Typographical Conventions:: @end menu @node Guile and Scheme @section Guile and Scheme Guile implements Scheme as described in the @tex Revised$^5$ @end tex @ifnottex Revised^5 @end ifnottex Report on the Algorithmic Language Scheme (usually known as @acronym{R5RS}), providing clean and general data and control structures. Guile goes beyond the rather austere language presented in @acronym{R5RS}, extending it with a module system, full access to @acronym{POSIX} system calls, networking support, multiple threads, dynamic linking, a foreign function call interface, powerful string processing, and many other features needed for programming in the real world. The Scheme community has recently agreed and published R6RS, the latest installment in the RnRS series. R6RS significantly expands the core Scheme language, and standardises many non-core functions that implementations---including Guile---have previously done in different ways. Guile has been updated to incorporate some of the features of R6RS, and to adjust some existing features to conform to the R6RS specification, but it is by no means a complete R6RS implementation. @xref{R6RS Support}. Between R5RS and R6RS, the SRFI process (@url{http://srfi.schemers.org/}) standardised interfaces for many practical needs, such as multithreaded programming and multidimensional arrays. Guile supports many SRFIs, as documented in detail in @ref{SRFI Support}. In summary, so far as relationship to the Scheme standards is concerned, Guile is an R5RS implementation with many extensions, some of which conform to SRFIs or to the relevant parts of R6RS. @node Combining with C @section Combining with C Code Like a shell, Guile can run interactively---reading expressions from the user, evaluating them, and displaying the results---or as a script interpreter, reading and executing Scheme code from a file. Guile also provides an object library, @dfn{libguile}, that allows other applications to easily incorporate a complete Scheme interpreter. An application can then use Guile as an extension language, a clean and powerful configuration language, or as multi-purpose ``glue'', connecting primitives provided by the application. It is easy to call Scheme code from C code and vice versa, giving the application designer full control of how and when to invoke the interpreter. Applications can add new functions, data types, control structures, and even syntax to Guile, creating a domain-specific language tailored to the task at hand, but based on a robust language design. This kind of combination is helped by four aspects of Guile's design and history. First is that Guile has always been targeted as an extension language. Hence its C API has always been of great importance, and has been developed accordingly. Second and third are rather technical points---that Guile uses conservative garbage collection, and that it implements the Scheme concept of continuations by copying and reinstating the C stack---but whose practical consequence is that most existing C code can be glued into Guile as is, without needing modifications to cope with strange Scheme execution flows. Last is the module system, which helps extensions to coexist without stepping on each others' toes. Guile's module system allows one to break up a large program into manageable sections with well-defined interfaces between them. Modules may contain a mixture of interpreted and compiled code; Guile can use either static or dynamic linking to incorporate compiled code. Modules also encourage developers to package up useful collections of routines for general distribution; as of this writing, one can find Emacs interfaces, database access routines, compilers, @acronym{GUI} toolkit interfaces, and @acronym{HTTP} client functions, among others. @node Guile and the GNU Project @section Guile and the GNU Project Guile was conceived by the GNU Project following the fantastic success of Emacs Lisp as an extension language within Emacs. Just as Emacs Lisp allowed complete and unanticipated applications to be written within the Emacs environment, the idea was that Guile should do the same for other GNU Project applications. This remains true today. The idea of extensibility is closely related to the GNU project's primary goal, that of promoting software freedom. Software freedom means that people receiving a software package can modify or enhance it to their own desires, including in ways that may not have occurred at all to the software's original developers. For programs written in a compiled language like C, this freedom covers modifying and rebuilding the C code; but if the program also provides an extension language, that is usually a much friendlier and lower-barrier-of-entry way for the user to start making their own changes. Guile is now used by GNU project applications such as AutoGen, Lilypond, Denemo, Mailutils, TeXmacs and Gnucash, and we hope that there will be many more in future. @node Interactive Programming @section Interactive Programming Non-free software has no interest in its users being able to see how it works. They are supposed to just accept it, or to report problems and hope that the source code owners will choose to work on them. Free software aims to work reliably just as much as non-free software does, but it should also empower its users by making its workings available. This is useful for many reasons, including education, auditing and enhancements, as well as for debugging problems. The ideal free software system achieves this by making it easy for interested users to see the source code for a feature that they are using, and to follow through that source code step-by-step, as it runs. In Emacs, good examples of this are the source code hyperlinks in the help system, and @code{edebug}. Then, for bonus points and maximising the ability for the user to experiment quickly with code changes, the system should allow parts of the source code to be modified and reloaded into the running program, to take immediate effect. Guile is designed for this kind of interactive programming, and this distinguishes it from many Scheme implementations that instead prioritise running a fixed Scheme program as fast as possible---because there are tradeoffs between performance and the ability to modify parts of an already running program. There are faster Schemes than Guile, but Guile is a GNU project and so prioritises the GNU vision of programming freedom and experimentation. @node Supporting Multiple Languages @section Supporting Multiple Languages Since the 2.0 release, Guile's architecture supports compiling any language to its core virtual machine bytecode, and Scheme is just one of the supported languages. Other supported languages are Emacs Lisp, ECMAScript (commonly known as Javascript) and Brainfuck, and work is under discussion for Lua, Ruby and Python. This means that users can program applications which use Guile in the language of their choice, rather than having the tastes of the application's author imposed on them. @node Obtaining and Installing Guile @section Obtaining and Installing Guile Guile can be obtained from the main GNU archive site @url{ftp://ftp.gnu.org} or any of its mirrors. The file will be named guile-@var{version}.tar.gz. The current version is @value{VERSION}, so the file you should grab is: @url{ftp://ftp.gnu.org/gnu/guile/guile-@value{VERSION}.tar.gz} To unbundle Guile use the instruction @example zcat guile-@value{VERSION}.tar.gz | tar xvf - @end example @noindent which will create a directory called @file{guile-@value{VERSION}} with all the sources. You can look at the file @file{INSTALL} for detailed instructions on how to build and install Guile, but you should be able to just do @example cd guile-@value{VERSION} ./configure make make install @end example This will install the Guile executable @file{guile}, the Guile library @file{libguile} and various associated header files and support libraries. It will also install the Guile reference manual. @c [[include instructions for getting R5RS]] Since this manual frequently refers to the Scheme ``standard'', also known as R5RS, or the @tex ``Revised$^5$ Report on the Algorithmic Language Scheme'', @end tex @ifnottex ``Revised^5 Report on the Algorithmic Language Scheme'', @end ifnottex we have included the report in the Guile distribution; see @ref{Top, , Introduction, r5rs, Revised(5) Report on the Algorithmic Language Scheme}. This will also be installed in your info directory. @node Organisation of this Manual @section Organisation of this Manual The rest of this manual is organised into the following chapters. @table @strong @item Chapter 2: Hello Guile! A whirlwind tour shows how Guile can be used interactively and as a script interpreter, how to link Guile into your own applications, and how to write modules of interpreted and compiled code for use with Guile. Everything introduced here is documented again and in full by the later parts of the manual. @item Chapter 3: Hello Scheme! For readers new to Scheme, this chapter provides an introduction to the basic ideas of the Scheme language. This material would apply to any Scheme implementation and so does not make reference to anything Guile-specific. @item Chapter 4: Programming in Scheme Provides an overview of programming in Scheme with Guile. It covers how to invoke the @code{guile} program from the command-line and how to write scripts in Scheme. It also introduces the extensions that Guile offers beyond standard Scheme. @item Chapter 5: Programming in C Provides an overview of how to use Guile in a C program. It discusses the fundamental concepts that you need to understand to access the features of Guile, such as dynamic types and the garbage collector. It explains in a tutorial like manner how to define new data types and functions for the use by Scheme programs. @item Chapter 6: Guile API Reference This part of the manual documents the Guile @acronym{API} in functionality-based groups with the Scheme and C interfaces presented side by side. @item Chapter 7: Guile Modules Describes some important modules, distributed as part of the Guile distribution, that extend the functionality provided by the Guile Scheme core. @item Chapter 8: GOOPS Describes GOOPS, an object oriented extension to Guile that provides classes, multiple inheritance and generic functions. @end table @node Typographical Conventions @section Typographical Conventions In examples and procedure descriptions and all other places where the evaluation of Scheme expression is shown, we use some notation for denoting the output and evaluation results of expressions. The symbol @samp{@result{}} is used to tell which value is returned by an evaluation: @lisp (+ 1 2) @result{} 3 @end lisp Some procedures produce some output besides returning a value. This is denoted by the symbol @samp{@print{}}. @lisp (begin (display 1) (newline) 'hooray) @print{} 1 @result{} hooray @end lisp As you can see, this code prints @samp{1} (denoted by @samp{@print{}}), and returns @code{hooray} (denoted by @samp{@result{}}). @c Local Variables: @c TeX-master: "guile.texi" @c End: