\input texinfo @c -*-texinfo-*- @comment %**start of header @setfilename gnutls-guile.info @include version-guile.texi @settitle GnuTLS-Guile @value{VERSION} @c don't indent the paragraphs. @paragraphindent 0 @c Unify some of the indices. @syncodeindex tp fn @syncodeindex pg cp @comment %**end of header @finalout @copying This manual is last updated @value{UPDATED} for version @value{VERSION} of GnuTLS. Copyright @copyright{} 2001-2012, 2014 Free Software Foundation, Inc. @quotation Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.3 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license is included in the section entitled ``GNU Free Documentation License''. @end quotation @end copying @dircategory Software libraries @direntry * GnuTLS-Guile: (gnutls-guile). GNU Transport Layer Security Library. Guile bindings. @end direntry @titlepage @title GnuTLS-Guile @subtitle Guile binding for GNU TLS @subtitle for version @value{VERSION}, @value{UPDATED} @sp 7 @image{gnutls-logo,6cm,6cm} @page @vskip 0pt plus 1filll @insertcopying @end titlepage @macro xcite{ref} [\ref\] (@pxref{Bibliography}) @end macro @contents @node Top @top GnuTLS-Guile @insertcopying @menu * Preface:: Preface. * Guile Preparations:: Note on installation and environment. * Guile API Conventions:: Naming conventions and other idiosyncrasies. * Guile Examples:: Quick start. * Guile Reference:: The Scheme GnuTLS programming interface. * Copying Information:: You can copy and modify this manual. * Procedure Index:: * Concept Index:: @end menu @node Preface @chapter Preface This manual describes the @uref{http://www.gnu.org/software/guile/, GNU Guile} Scheme programming interface to GnuTLS, which is distributed as part of @uref{http://gnutls.org,GnuTLS}. The reader is assumed to have basic knowledge of the protocol and library. Details missing from this chapter may be found in Function reference, of the C API reference. At this stage, not all the C functions are available from Scheme, but a large subset thereof is available. @c ********************************************************************* @node Guile Preparations @chapter Guile Preparations The GnuTLS Guile bindings are available for both the 1.8 and 2.0 stable series of Guile. By default they are installed under the GnuTLS installation directory, typically @file{/usr/local/share/guile/site/}). Normally Guile will not find the module there without help. You may experience something like this: @example $ guile guile> (use-modules (gnutls)) : no code for module (gnutls) guile> @end example There are two ways to solve this. The first is to make sure that when building GnuTLS, the Guile bindings will be installed in the same place where Guile looks. You may do this by using the @code{--with-guile-site-dir} parameter as follows: @example $ ./configure --with-guile-site-dir=no @end example This will instruct GnuTLS to attempt to install the Guile bindings where Guile will look for them. It will use @code{guile-config info pkgdatadir} to learn the path to use. If Guile was installed into @code{/usr}, you may also install GnuTLS using the same prefix: @example $ ./configure --prefix=/usr @end example If you want to specify the path to install the Guile bindings you can also specify the path directly: @example $ ./configure --with-guile-site-dir=/opt/guile/share/guile/site @end example The second solution requires some more work but may be easier to use if you do not have system administrator rights to your machine. You need to instruct Guile so that it finds the GnuTLS Guile bindings. Either use the @code{GUILE_LOAD_PATH} environment variable as follows: @example $ GUILE_LOAD_PATH="/usr/local/share/guile/site:$GUILE_LOAD_PATH" guile guile> (use-modules (gnutls)) guile> @end example Alternatively, you can modify Guile's @code{%load-path} variable (@pxref{Build Config, Guile's run-time options,, guile, The GNU Guile Reference Manual}). At this point, you might get an error regarding @file{libguile-gnutls-v-0} similar to: @example gnutls.scm:361:1: In procedure dynamic-link in expression (load-extension "libguile-gnutls-v-0" "scm_init_gnutls"): gnutls.scm:361:1: file: "libguile-gnutls-v-0", message: "libguile-gnutls-v-0.so: cannot open shared object file: No such file or directory" @end example In this case, you will need to modify the run-time linker path, for example as follows: @example $ LD_LIBRARY_PATH=/usr/local/lib GUILE_LOAD_PATH=/usr/local/share/guile/site guile guile> (use-modules (gnutls)) guile> @end example To check that you got the intended GnuTLS library version, you may print the version number of the loaded library as follows: @example $ guile guile> (use-modules (gnutls)) guile> (gnutls-version) "@value{VERSION}" guile> @end example @c ********************************************************************* @node Guile API Conventions @chapter Guile API Conventions This chapter details the conventions used by Guile API, as well as specificities of the mapping of the C API to Scheme. @menu * Enumerates and Constants:: Representation of C-side constants. * Procedure Names:: Naming conventions. * Representation of Binary Data:: Binary data buffers. * Input and Output:: Input and output. * Exception Handling:: Exceptions. @end menu @node Enumerates and Constants @section Enumerates and Constants @cindex enumerate @cindex constant Lots of enumerates and constants are used in the GnuTLS C API. For each C enumerate type, a disjoint Scheme type is used---thus, enumerate values and constants are not represented by Scheme symbols nor by integers. This makes it impossible to use an enumerate value of the wrong type on the Scheme side: such errors are automatically detected by type-checking. The enumerate values are bound to variables exported by the @code{(gnutls)} module. These variables are named according to the following convention: @itemize @item All variable names are lower-case; the underscore @code{_} character used in the C API is replaced by hyphen @code{-}. @item All variable names are prepended by the name of the enumerate type and the slash @code{/} character. @item In some cases, the variable name is made more explicit than the one of the C API, e.g., by avoid abbreviations. @end itemize Consider for instance this C-side enumerate: @example typedef enum @{ GNUTLS_CRD_CERTIFICATE = 1, GNUTLS_CRD_ANON, GNUTLS_CRD_SRP, GNUTLS_CRD_PSK @} gnutls_credentials_type_t; @end example The corresponding Scheme values are bound to the following variables exported by the @code{(gnutls)} module: @example credentials/certificate credentials/anonymous credentials/srp credentials/psk @end example Hopefully, most variable names can be deduced from this convention. Scheme-side ``enumerate'' values can be compared using @code{eq?} (@pxref{Equality, equality predicates,, guile, The GNU Guile Reference Manual}). Consider the following example: @findex session-cipher @example (let ((session (make-session connection-end/client))) ;; ;; ... ;; ;; Check the ciphering algorithm currently used by SESSION. (if (eq? cipher/arcfour (session-cipher session)) (format #t "We're using the ARCFOUR algorithm"))) @end example In addition, all enumerate values can be converted to a human-readable string, in a type-specific way. For instance, @code{(cipher->string cipher/arcfour)} yields @code{"ARCFOUR 128"}, while @code{(key-usage->string key-usage/digital-signature)} yields @code{"digital-signature"}. Note that these strings may not be sufficient for use in a user interface since they are fairly concise and not internationalized. @node Procedure Names @section Procedure Names Unlike C functions in GnuTLS, the corresponding Scheme procedures are named in a way that is close to natural English. Abbreviations are also avoided. For instance, the Scheme procedure corresponding to @code{gnutls_certificate_set_dh_params} is named @code{set-certificate-credentials-dh-parameters!}. The @code{gnutls_} prefix is always omitted from variable names since a similar effect can be achieved using Guile's nifty binding renaming facilities, should it be needed (@pxref{Using Guile Modules,,, guile, The GNU Guile Reference Manual}). Often Scheme procedure names differ from C function names in a way that makes it clearer what objects they operate on. For example, the Scheme procedure named @code{set-session-transport-port!} corresponds to @code{gnutls_transport_set_ptr}, making it clear that this procedure applies to session. @node Representation of Binary Data @section Representation of Binary Data Many procedures operate on binary data. For instance, @code{pkcs3-import-dh-parameters} expects binary data as input. @cindex SRFI-4 @cindex homogeneous vector Binary data is represented on the Scheme side using SRFI-4 homogeneous vectors (@pxref{SRFI-4,,, guile, The GNU Guile Reference Manual}). Although any type of homogeneous vector may be used, @code{u8vector}s (i.e., vectors of bytes) are highly recommended. As an example, generating and then exporting Diffie-Hellman parameters in the PEM format can be done as follows: @findex make-dh-parameters @findex pkcs3-export-dh-parameters @vindex x509-certificate-format/pem @example (let* ((dh (make-dh-parameters 1024)) (pem (pkcs3-export-dh-parameters dh x509-certificate-format/pem))) (call-with-output-file "some-file.pem" (lambda (port) (uniform-vector-write pem port)))) @end example For an example of OpenPGP key import from a file, see @ref{Importing OpenPGP Keys Guile Example}. @node Input and Output @section Input and Output @findex set-session-transport-port! @findex set-session-transport-fd! The underlying transport of a TLS session can be any Scheme input/output port (@pxref{Ports and File Descriptors,,, guile, The GNU Guile Reference Manual}). This has to be specified using @code{set-session-transport-port!}. However, for better performance, a raw file descriptor can be specified, using @code{set-session-transport-fd!}. For instance, if the transport layer is a socket port over an OS-provided socket, you can use the @code{port->fdes} or @code{fileno} procedure to obtain the underlying file descriptor and pass it to @code{set-session-transport-fd!} (@pxref{Ports and File Descriptors, @code{port->fdes} and @code{fileno},, guile, The GNU Guile Reference Manual}). This would work as follows: @example (let ((socket (socket PF_INET SOCK_STREAM 0)) (session (make-session connection-end/client))) ;; ;; Establish a TCP connection... ;; ;; Use the file descriptor that underlies SOCKET. (set-session-transport-fd! session (fileno socket))) @end example @findex session-record-port Once a TLS session is established, data can be communicated through it (i.e., @emph{via} the TLS record layer) using the port returned by @code{session-record-port}: @example (let ((session (make-session connection-end/client))) ;; ;; Initialize the various parameters of SESSION, set up ;; a network connection, etc... ;; (let ((i/o (session-record-port session))) (write "Hello peer!" i/o) (let ((greetings (read i/o))) ;; ... (bye session close-request/rdwr)))) @end example @findex record-send @findex record-receive! A lower-level I/O API is provided by @code{record-send} and @code{record-receive!} which take an SRFI-4 vector to represent the data sent or received. While it might improve performance, it is much less convenient than the above and should rarely be needed. @node Exception Handling @section Exception Handling @cindex exceptions @cindex errors @cindex @code{gnutls-error} @findex error->string GnuTLS errors are implemented as Scheme exceptions (@pxref{Exceptions, exceptions in Guile,, guile, The GNU Guile Reference Manual}). Each time a GnuTLS function returns an error, an exception with key @code{gnutls-error} is raised. The additional arguments that are thrown include an error code and the name of the GnuTLS procedure that raised the exception. The error code is pretty much like an enumerate value: it is one of the @code{error/} variables exported by the @code{(gnutls)} module (@pxref{Enumerates and Constants}). Exceptions can be turned into error messages using the @code{error->string} procedure. The following examples illustrates how GnuTLS exceptions can be handled: @example (let ((session (make-session connection-end/server))) ;; ;; ... ;; (catch 'gnutls-error (lambda () (handshake session)) (lambda (key err function . currently-unused) (format (current-error-port) "a GnuTLS error was raised by `~a': ~a~%" function (error->string err))))) @end example Again, error values can be compared using @code{eq?}: @example ;; `gnutls-error' handler. (lambda (key err function . currently-unused) (if (eq? err error/fatal-alert-received) (format (current-error-port) "a fatal alert was caught!~%") (format (current-error-port) "something bad happened: ~a~%" (error->string err)))) @end example Note that the @code{catch} handler is currently passed only 3 arguments but future versions might provide it with additional arguments. Thus, it must be prepared to handle more than 3 arguments, as in this example. @c ********************************************************************* @node Guile Examples @chapter Guile Examples This chapter provides examples that illustrate common use cases. @menu * Anonymous Authentication Guile Example:: Simplest client and server. * OpenPGP Authentication Guile Example:: Using OpenPGP-based authentication. * Importing OpenPGP Keys Guile Example:: Importing keys from files. @end menu @node Anonymous Authentication Guile Example @section Anonymous Authentication Guile Example @dfn{Anonymous authentication} is very easy to use. No certificates are needed by the communicating parties. Yet, it allows them to benefit from end-to-end encryption and integrity checks. The client-side code would look like this (assuming @var{some-socket} is bound to an open socket port): @vindex connection-end/client @vindex kx/anon-dh @vindex close-request/rdwr @example ;; Client-side. (let ((client (make-session connection-end/client))) ;; Use the default settings. (set-session-default-priority! client) ;; Don't use certificate-based authentication. (set-session-certificate-type-priority! client '()) ;; Request the "anonymous Diffie-Hellman" key exchange method. (set-session-kx-priority! client (list kx/anon-dh)) ;; Specify the underlying socket. (set-session-transport-fd! client (fileno some-socket)) ;; Create anonymous credentials. (set-session-credentials! client (make-anonymous-client-credentials)) ;; Perform the TLS handshake with the server. (handshake client) ;; Send data over the TLS record layer. (write "hello, world!" (session-record-port client)) ;; Terminate the TLS session. (bye client close-request/rdwr)) @end example The corresponding server would look like this (again, assuming @var{some-socket} is bound to a socket port): @vindex connection-end/server @example ;; Server-side. (let ((server (make-session connection-end/server))) (set-session-default-priority! server) (set-session-certificate-type-priority! server '()) (set-session-kx-priority! server (list kx/anon-dh)) ;; Specify the underlying transport socket. (set-session-transport-fd! server (fileno some-socket)) ;; Create anonymous credentials. (let ((cred (make-anonymous-server-credentials)) (dh-params (make-dh-parameters 1024))) ;; Note: DH parameter generation can take some time. (set-anonymous-server-dh-parameters! cred dh-params) (set-session-credentials! server cred)) ;; Perform the TLS handshake with the client. (handshake server) ;; Receive data over the TLS record layer. (let ((message (read (session-record-port server)))) (format #t "received the following message: ~a~%" message) (bye server close-request/rdwr))) @end example This is it! @node OpenPGP Authentication Guile Example @section OpenPGP Authentication Guile Example GnuTLS allows users to authenticate using OpenPGP certificates. Using OpenPGP-based authentication is not more complicated than using anonymous authentication. It requires a bit of extra work, though, to import the OpenPGP public and private key of the client/server. Key import is omitted here and is left as an exercise to the reader (@pxref{Importing OpenPGP Keys Guile Example}). Assuming @var{some-socket} is bound to an open socket port and @var{pub} and @var{sec} are bound to the client's OpenPGP public and secret key, respectively, client-side code would look like this: @vindex certificate-type/openpgp @example ;; Client-side. (define %certs (list certificate-type/openpgp)) (let ((client (make-session connection-end/client)) (cred (make-certificate-credentials))) (set-session-default-priority! client) ;; Choose OpenPGP certificates. (set-session-certificate-type-priority! client %certs) ;; Prepare appropriate client credentials. (set-certificate-credentials-openpgp-keys! cred pub sec) (set-session-credentials! client cred) ;; Specify the underlying transport socket. (set-session-transport-fd! client (fileno some-socket)) (handshake client) (write "hello, world!" (session-record-port client)) (bye client close-request/rdwr)) @end example Similarly, server-side code would be along these lines: @example ;; Server-side. (define %certs (list certificate-type/openpgp)) (let ((server (make-session connection-end/server)) (dh (make-dh-parameters 1024))) (set-session-default-priority! server) ;; Choose OpenPGP certificates. (set-session-certificate-type-priority! server %certs) (let ((cred (make-certificate-credentials))) ;; Prepare credentials with Diffie-Hellman parameters. (set-certificate-credentials-dh-parameters! cred dh) (set-certificate-credentials-openpgp-keys! cred pub sec) (set-session-credentials! server cred)) (set-session-transport-fd! server (fileno some-socket)) (handshake server) (let ((msg (read (session-record-port server)))) (format #t "received: ~a~%" msg) (bye server close-request/rdwr))) @end example @node Importing OpenPGP Keys Guile Example @section Importing OpenPGP Keys Guile Example The following example provides a simple way of importing ``ASCII-armored'' OpenPGP keys from files, using the @code{import-openpgp-certificate} and @code{import-openpgp-private-key} procedures. @vindex openpgp-certificate-format/base64 @vindex openpgp-certificate-format/raw @example (use-modules (srfi srfi-4) (gnutls)) (define (import-key-from-file import-proc file) ;; Import OpenPGP key from FILE using IMPORT-PROC. ;; Prepare a u8vector large enough to hold the raw ;; key contents. (let* ((size (stat:size (stat path))) (raw (make-u8vector size))) ;; Fill in the u8vector with the contents of FILE. (uniform-vector-read! raw (open-input-file file)) ;; Pass the u8vector to the import procedure. (import-proc raw openpgp-certificate-format/base64))) (define (import-public-key-from-file file) (import-key-from-file import-openpgp-certificate file)) (define (import-private-key-from-file file) (import-key-from-file import-openpgp-private-key file)) @end example The procedures @code{import-public-key-from-file} and @code{import-private-key-from-file} can be passed a file name. They return an OpenPGP public key and private key object, respectively (@pxref{Guile Reference, OpenPGP key objects}). @c ********************************************************************* @node Guile Reference @chapter Guile Reference This chapter lists the GnuTLS Scheme procedures exported by the @code{(gnutls)} module (@pxref{The Guile module system,,, guile, The GNU Guile Reference Manual}). @include core.c.texi @c Local Variables: @c ispell-local-dictionary: "american" @c End: @include cha-copying.texi @node Procedure Index @unnumbered Procedure Index @printindex fn @node Concept Index @unnumbered Concept Index @printindex cp @bye