\input texinfo @c -*-texinfo-*- @comment $Id@w{$} @documentlanguage en @comment %**start of header @include version.texi @settitle Demanding Interoperability to Strengthen the Free (Libre) Web: Introducing Disfluid @syncodeindex pg cp @syncodeindex fn cp @syncodeindex vr cp @syncodeindex tp cp @comment %**end of header @copying This is the manual of disfluid (version @value{VERSION}, @value{UPDATED}), an implementation of the Solid authentication protocol for guile, client and server. Copyright @copyright{} 2020, 2021 Vivien Kraus @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, with no Front-Cover Texts, and with 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 * disfluid: (disfluid)Interoperability on the web @end direntry @titlepage @title Demanding Interoperability to Strengthen the Free (Libre) Web: Introducing Disfluid @subtitle for version @value{VERSION}, @value{UPDATED} @author Vivien Kraus (@email{vivien@@planete-kraus.eu}) @page @vskip 0pt plus 1fill @insertcopying @end titlepage @contents @ifnottex @node Top @top Disfluid @end ifnottex @menu * Decentralized Authentication on the Web:: * Invoking disfluid:: * Running disfluid with GNU Guix:: * The Json Web Token:: * Caching on server side:: * Content negociation:: * Running an Identity Provider:: * Running a Resource Server:: * Running a client:: * Exceptional conditions:: * GNU Free Documentation License:: * Index:: @end menu @node Decentralized Authentication on the Web @chapter Decentralized Authentication on the Web Authentication on the web is currently handled in the following way: anyone can install a server that will authenticate users on the web. The problem is interoperability. If a client (an application) wants to authenticate a user, it has to be approved by the authentication server. In other words, if @var{useful-program} wants to authenticate @var{MegaCorp} users, then @var{useful-program} has to register to @var{MegaCorp} first, and get approved. This goes against the principle of permission-less innovation, which is at the heart of the web. In the decentralized authentication web, the best attempt so far is that of ActivityPub. All servers are interoperable with respect to authentication: if user A emits an activity, it is forwarded by A's server to its recipients, and A's server is responsible for A's identity. The problem with that approach is that the data is tied to the application. It is not possible to use another application to process the data differently, or to use multiple data sources, in an interoperable way (without the ActivityPub server knowing). This means that on Activitypub, microblogging applications will not present different activities correctly. This also means that it is difficult to write a free replacement to a non-free application program, because it would need to manage the data. In the Solid ecosystem, there is a clear distinction between servers and applications. An application is free to read data from all places at the same time, using a permission-less authentication system. Since the applications do not need to store data, the cost of having users is neglectible, so users do not need prior approval before using them (making captchas and the like a thing of the past). Servers do not have a say in which applications the user uses. The authentication used is a slight modification of the well-established OpenID Connect. It is intended to work in a web browser, but this package demonstrates that it also works without a web browser. @node Invoking disfluid @chapter Invoking disfluid The @samp{disfluid} program provides different modes of operations: @table @samp @item reverse-proxy Run an authenticating reverse proxy. With this command, you specify a backend server. When an authenticated user makes a request, you receive an additional header containing the user’s identity. @item identity-provider Run the identity provider only. @item client-service The client applications must serve some resources: namely, the client manifest and the redirect URI. @item server Run both an identity provider and a resource server. @end table The server is configured with command-line arguments, and environment variables. @menu * General options:: * General server configuration:: * Configuration for the resource server:: * Configuration for the identity provider:: * Configuration for the client service:: @end menu @node General options @section General options The server will respond to @samp{-h} and @samp{-v} commands, to get the help output and the version information. The server output (command-line, logs) are localized for the system administrator. You can control it with the @samp{LANG} environment variable. So if your locale is not English, you can have the same commands as in this manual by running with @code{LANG=C}. The programs respect the @samp{XDG_DATA_HOME} and @samp{XDG_CACHE_HOME} to store persistent data and disposable data. The cache directory can be deleted at any time. If one of these variables is not set, its value is computed from the @samp{HOME} environment variable. @node General server configuration @section General server configuration All servers are published under the Affero GPL, which means that the service provider needs to publish all changes made to the program to users over the network. The @samp{disfluid} command provides a @samp{--complete-corresponding-source} option so that the system administrator can specify a means to download the source. The servers will add a @samp{Source:} header in each response, containing the value of this configuration option. The servers can be configured to redirect output and errors to a log file and an error file, with the @samp{--log-file} and @samp{--error-file} options. The server will listen to port 8080 by default, but this may be configured with @samp{--port}. Since the servers do not support TLS, and they only support HTTP/1.1, they are intended to run behind a reverse proxy (even for the authenticating reverse proxy). Finally, the servers are required to know their public name. This is configured with the @samp{--server-name} option. The server will make requests on the world-wide web, for instance to download client manifests. The requests can be redirected with XML Catalog, by setting the @samp{XML_CATALOG_FILES} to a space-separated list of URIs (can be @code{file:} URIs). The requests cannot be directed to the file system. @node Configuration for the resource server @section Configuration for the resource server The reverse proxy sets an identity header to authenticated requests. By default, it is @samp{XXX-Agent}, but it can be configured with @samp{--header}. The reverse proxy is configured to contact a backend URI with @samp{--backend-uri}. This backend URI should not be directly exposed, because a malicious user could set the identity header. @node Configuration for the identity provider @section Configuration for the identity provider The identity provider can only handle one user. If you want to handle multiple users, it is highly advised to use a different host name for each user, in case the server is accessed from a web browser. You can set the identity of the user with @samp{--subject}, and write the user’s password in a file. Pass the file name with @samp{--encrypted-password-file}. You can pass the encrypted password directly with @samp{--encrypted-password}, but the encrypted password will be public. The encrypted password format is defined by the crypt function in the C library. For glibc, it looks like this: @code{$@var{N}$@var{salt}$@var{hash}}, where @var{N} is the algorithm identifier, @var{salt} is the password salt annd @var{hash} is its hash. The server uses a key, which is not the same thing as the TLS certificate of the server (remember, the servers don’t support TLS). It is in the JWK format. You set its file name with @samp{--key-file}. If the key file does not exist, it will be generated. Finally, the public openid configuration requires you to set the JWKS URI (@samp{--jwks-uri}), authorization endpoint URI (@samp{--authorization-endpoint-uri}) and token endpoint URI (@samp{--token-endpoint-uri}). The identity provider will publish the full URIs, but will respond to their path, regardless of the host. @node Configuration for the client service @section Configuration for the client service The client will serve a stupid page for the redirect URI that will only display the authorization code. The redirect URI is set with @samp{--redirect-uri}. The client ID is set with @samp{--client-id}. This is the URI under which the client registrationn is served. Finally, you can set some cosmetic options, but since it can confuse the user, they are hidden by default by the identity provider. @table @samp @item --client-name set the name of the application. @item --client-uri set an URI where to find more information about the client. @end table @node Running disfluid with GNU Guix @chapter Running disfluid with GNU Guix The channel at @url{https://labo.planete-kraus.eu/webid-oidc-channel.git} can be used with guix. It defines the package at the latest commit, and a service definition in @emph{(vkraus services disfluid)}. @defvr {service type} disfluid-service-type This service runs a bunch of disfluid servers with the @emph{disfluid} system user, each with a unique name. The value it takes is an alist of service configurations: the keys are unique names (to differenciate the generated shepherd services), and the values are configuration records for an issuer, reverse proxy, server, or client service. @end defvr @deftp {configuration record} [@var{disfluid}] @var{complete-corresponding-source} @var{issuer} @var{key-file} @var{subject} @var{encrypted-password-file} @var{jwks-uri} @var{authorization-endpoint-uri} @var{token-endpoint-uri} @var{port} [@var{extra-options}] The configuration for the identity provider. The optional @var{disfluid} argument is the package containing the binary to run, if you want to apply some patches, and @var{extra-options} is an empty list by default. @end deftp @deftp {configuration record} [@var{disfluid}] @var{complete-corresponding-source} @var{port} @var{inbound-uri} @var{outbound-uri} @var{header} [@var{extra-options}] This record configures an authenticating reverse proxy. @end deftp @deftp {configuration record} [@var{disfluid}] @var{complete-corresponding-source} @var{client-id} @var{redirect-uri} [@var{client-name}] [@var{client-uri}] @var{port} [@var{extra-options}] This record configures a server to serve public application pages. @end deftp @deftp {configuration record} [@var{disfluid}] @var{complete-corresponding-source} @var{server-name} @var{key-file} @var{subject} @var{encrypted-password-file} @var{jwks-uri} @var{authorization-endpoint-uri} @var{token-endpoint-uri} @var{port} [@var{extra-options}] The configuration for the full server. @end deftp @node The Json Web Token @chapter The Json Web Token The Json Web Token, or @dfn{JWT}, is a terse representation of a pair of JSON objects: the @dfn{header}, and the @dfn{payload}. The JWT can be @dfn{encoded} as a Json Web Signature (@dfn{JWS}), in which case the header is encoded to base64 with the URL alphabet, and without padding characters, the payload is also encoded to base64, and the concatenation of the encoding of the header, a dot, and the encoding of the payload is signed with some cryptography algorithm. In the following, we will only be interested by public-key cryptography. The concatenation of header, dot, payload, dot and signature in base64 is the encoding of the JWT. Decoded JWT are represented as a pair. The car of the pair is the header, and the cdr is the payload. Both the header and the payload use the JSON representation from srfi-180: objects are alists of @strong{symbols} to values, arrays are vectors. It is unfortunate that guile-json has a slightly different representation, where alist keys are @emph{strings}, but we hope that in the future SRFI-180 will be more closely respected. @menu * The ID token:: * The access token:: * The DPoP proof:: * Generic JWTs:: @end menu @node The ID token @section The ID token The ID token is a special JWT that the application keeps for itself. It is signed by the identity provider, and contains the following claims: @table @emph @item webid the URI of the user’s webid; @item iss the URI of the identity provider (issuer); @item sub the username (the webid-oidc issuer puts the webid again here, but it could be any string); @item aud the ID of the client application that is intended to receive the ID token; @item nonce some random data to change the signature; @item exp an UTC time (in seconds) for when the token expires; @item iat the time when it was issued. @end table There are functions to work with ID tokens in @emph{(webid-oidc oidc-id-token)}. @deffn function id-token? @var{object} Check that @var{object} is a decoded ID token. @end deffn The following helper functions convert URIs to the URIs from @emph{(web uri)} and times to @emph{(srfi srfi-19)} dates. @deffn function id-token-webid @var{token} @deffnx function id-token-iss @var{token} @deffnx function id-token-sub @var{token} @deffnx function id-token-aud @var{token} @deffnx function id-token-nonce @var{token} @deffnx function id-token-exp @var{token} @deffnx function id-token-iat @var{token} Get the suitable field from the payload of @var{token}. @end deffn ID tokens can be signed and encoded as a string, or decoded. @deffn function id-token-decode @var{token} @var{[#http-get]} Decode @var{token}, as a string, into a decoded token. The signature verification will need to fetch the oidc configuration of the claimed issuer, and check the signature against the published keys. The @code{http-get} optional keyword argument can set a different implementation of @code{http-get} from @emph{(web client)}. Return @code{#f} if it failed, or the decoded token otherwise. @end deffn @deffn function id-token-encode @var{token} @var{key} Encode @var{token} and sign it with the issuer’s @var{key}. @end deffn @deffn function issue-id-token @var{issuer-key} @var{#:alg} @var{#:webid} @var{#:iss} @var{#:sub} @var{#:aud} @var{#:validity} Create an ID token that is valid for @var{#:validity} seconds, and encode it with @var{issuer-key}. @end deffn @node The access token @section The access token The access token is obtained by the client through a token request, and is presented to the server on each authenticated request. It is signed by the identity provider, and it contains enough information so that the server knows who the user is and who the agent is, and most importantly the fingerprint of the key that the client should use in a DPoP proof. The API is defined in @emph{(webid-oidc access-token)}. @deffn function access-token? @var{object} Check that @var{object} is a decoded access token. @end deffn There are field getters for the access token: @deffn function access-token-webid @var{token} @deffnx function access-token-iss @var{token} @deffnx function access-token-aud @var{token} @deffnx function access-token-exp @var{token} @deffnx function access-token-iat @var{token} @deffnx function access-token-cnf/jkt @var{token} @deffnx function access-token-client-id @var{token} Get the suitable field from the payload of @var{token}. @end deffn Access tokens can be signed and encoded as a string, or decoded. @deffn function access-token-decode @var{token} @var{[#http-get]} Decode @var{token}, as a string, into a decoded token. As with the ID token, the signature verification will need to fetch the oidc configuration of the claimed issuer, and check the signature against the published keys. The @code{http-get} optional keyword argument can set a different implementation of @code{http-get} from @emph{(web client)}, for instance to re-use the what has been obtained by the ID token validation. Return @code{#f} if it failed, or the decoded token otherwise. @end deffn @deffn function access-token-encode @var{token} @var{key} Encode @var{token} and sign it with the issuer’s @var{key}. @end deffn @deffn function issue-access-token @var{issuer-key} @var{#alg} @var{#webid} @var{#iss} @var{#:validity} @var{[#client-key} @var{|} @var{#cnf/jkt]} @var{#client-id} Create an access token for @var{#:validity} seconds, and encode it with @var{issuer-key}. You can either set the @code{#:cnf/jkt} keyword argument with the fingerprint of the client key, or set @code{#:client-key} directly, in which case the fingerprint will be computed for you. @end deffn @node The DPoP proof @section The DPoP proof This is a special JWT, that is signed by a key controlled by the application. The access token certifies that the key used to sign the proof is approved by the identity provider. @deffn function dpop-proof? @var{proof} Check that the @var{proof} is a decoded DPoP proof. The validity of the proof is not checked by this function. @end deffn @deffn function dpop-proof-alg @var{proof} @deffnx function dpop-proof-jwk @var{proof} @deffnx function dpop-proof-jti @var{proof} @deffnx function dpop-proof-htm @var{proof} @deffnx function dpop-proof-htu @var{proof} @deffnx function dpop-proof-iat @var{proof} @deffnx function dpop-proof-ath @var{proof} Get the corresponding field of the proof. @end deffn @deffn function dpop-proof-decode @var{method} @var{uri} @var{str} @var{cnf/check} @var{[#:access-token]} Check and decode a DPoP proof encoded as @var{str}. In order to prevent replay attacks, each proof has a unique random string that is remembered in @var{jti-list} until its expiration date is reached. See the @code{make-jti-list} function. The proof is limited to the scope of one @var{uri} and one @var{method} (@code{'GET}, @code{'POST} and so on). The key that is used to sign the proof should be confirmed by the identity provider. To this end, the @var{cnf/check} function is called with the fingerprint of the key. The function should check that the fingerprint is OK (return a boolean). Finally, when the DPoP proof is tied to an access token (so, for all uses except requesting an access token or a refresh token), it must be bound to an @var{access-token}. @end deffn The DPoP proof algorithm is sensitive to the current time, because the proofs have a limited time validity. By default, the time is the system time when the proof is decoded. @deffn parameter current-date This parameter overrides the current time. It is a thunk returning a date, so you need to put two parenthesis to get the time. However, you can set it to a date, a time, a number of seconds, or a thunk returning any of these. @example (use-module ((webid-oidc parameters) #:prefix p:)) ;; This is the current date: ((p:current-date)) ;; You can override it with a thunk, or a fixed date: (parameterize ((p:current-date 0)) ;; Jan 1st 1970 ((p:current-date))) @end example @end deffn @deffn function dpop-proof-encode @var{proof} @var{key} Encode the proof and sign it with @var{key}. To generate valid proofs, @var{key} should be the private key corresponding to the @code{jwk} field of the proof. @end deffn @deffn function issue-dpop-proof @var{client-key} @var{#alg} @var{#htm} @var{#htu} {[#:@var{access-token}=#f]} Create a proof, sign it and encode it with @var{client-key}. @var{client-key} should contain both the private and public key, because the public part is written in the proof and the private part is used to sign it. For most uses, the DPoP proof should be encoded for a specific access token. Only token requests should omit the @samp{access-token} field. The @samp{iat} field of the DPoP proof is read from the @var{current-date} parameter. @end deffn @node Generic JWTs @section Generic JWTs You can parse generic JWTs signed with JWS with the following functions from @emph{(webid-oidc jws)}. @deffn function jws? @var{jwt} Check that @var{jwt} is a decoded JWT signed with JWS. @end deffn @deffn function jws-alg @var{jwt} Get the algorithm used to sign @var{jwt}. @end deffn @deffn function jws-decode @var{str} @var{lookup-keys} Check and decode a JWT signed with JWS and encoded as @var{str}. Since the decoding and signature verification happen at the same time (for user friendliness), the @var{lookup-keys} function is used. It is passed as arguments the decoded JWT (but the signature is not checked yet), and it should return a public key, a public key set or a list of public keys. If the key lookup failed, this function should raise an exception. @end deffn @deffn function jws-encode @var{jwt} @var{key} Encode the JWT and sign it with @var{key}. @end deffn @node Caching on server side @chapter Caching on server side Both the identity provider and the resource server need to cache things. The identity provider will cache application webids, and the resource server will cache the identity provider keys, for instance. The solution is to use a file-system cache. Every response (except those that have a cache-control policy of no-store) are stored to a sub-directory of @emph{XDG_CACHE_HOME}. Each store has a 5% chance of triggering a cleanup of the cache. When a cleanup occurs, each cached response has a 5% chance of being dropped, including responses that are indicated as valid. This way, a malicious cache response that has a maliciously long validity will not stay too long in the cache. A log line will indicate which items are dropped. The @emph{(webid-oidc cache)} module exports two functions to deal with the cache. @deffn function clean-cache @var{[#percents]} Drop @var{percents}% of the cache right now. @end deffn @deffn function with-cache @var{[#http-get]} Return a function acting as @emph{http-get} from @emph{(web client)} (takes an URI as the first parameter, and an optional @var{#:headers} set, and returns 2 values, the response and its body). The cache will be read and written in the @samp{web-cache} subdirectory of the cache home. To check the time window validity, the @var{current-date} parameter is used. The back-end function, @var{http-get}, defaults to that of @emph{(web client)}. @end deffn @deffn parameter cache-home This parameters sets the cache directory. By default, it is @emph{XDG_CACHE_HOME}. @end deffn @node Content negociation @chapter Content negociation There are a number of different available syntaxes for RDF, some being simple and human readable like @emph{turtle}, and others more adapted to the JavaScript ecosystem like @emph{json-ld}. To help clients both from and outside of the JS ecosystem, the server needs to perform @dfn{content negociation}, i.e. convert from one content-type to another. @deffn {function from @code{(webid-oidc serve)}} convert @var{client-accepts} @var{server-name} @var{path} @var{content-type} @var{content} Convert the resource representation under @var{path} on @var{server-name}, which has a given @var{content-type} and @var{content}, to a content-type that the @var{client accepts}. Return 2 values: @enumerate @item the accepted content-type; @item the content in the given content-type. @end enumerate Currently, the only conversions are from and to @emph{Turtle} and @emph{N-Quads}. @end deffn @node Running an Identity Provider @chapter Running an Identity Provider This project is packaged with a barebones identity provider. It has an authorization endpoint and a token endpoint (and it serves its public keys), but it is only intended for one specific person. You can start it by invoking the @code{webid-oidc} program with the @code{issuer} command, with the following options: @table @asis @item @code{-h}, or @code{--help} prints a summary of options and exit. @item @code{-v}, or @code{--version} prints the version of the program and exits. @item @code{-n @var{URI}}, or @code{--server-name=@var{URI}} sets the global server name of the identity provider. It should have an empty path. @item @code{-k @var{FILE.jwk}}, or @code{--key-file=@var{FILE.jwk}} sets the file name where to read or generate a key for the identity provider. This file should be JSON, containing the representation of a JWK key pair. @item @code{-s @var{WEBID}}, or @code{--subject=@var{WEBID}} sets the webid of the only user of the identity provider. This is an URI, pointing to a RDF node corresponding to the user’s profile. @item @code{-w @var{PASSWORD}}, or @code{--password=@var{PASSWORD}} sets the password that the user must enter to authorize an application. @item @code{-j @var{URI}}, or @code{--jwks-uri=@var{URI}} tells the server that requests to @var{URI} should be responded with the public key used to sign the tokens. @item @code{-a @var{URI}}, or @code{--authorization-endpoint-uri=@var{URI}} tells the server that requests to @var{URI} should be treated as authorization requests. @item @code{-t @var{URI}}, or @code{--token-endpoint-uri=@var{URI}} tells the server that requests to @var{URI} should be treated as token negociation requests. @item @code{-p @var{PORT}}, or @code{--port=@var{PORT}} change the port number used by the server. By default, it is set to 8080. @item @code{-l @var{FILE.log}}, or @code{--log-file=@var{FILE.log}} let the server dump all its output to @var{FILE.log}. Since I don’t know how to deal with syslog, this is the only way to keep logs with a shepherd service. @item @code{-e @var{FILE.err}}, or @code{--error-file=@var{FILE.err}} let the server dump all its errors to @var{FILE.err}. @end table The program is sensitive to the environment variables. The most important one is @emph{LANG}, which influences how the program is internationalized to the server administrator (the pages served to the user use the user agent’s locale). This changes the long form of the options, and the language in the log files. The @emph{XDG_DATA_HOME} should point to some place where the program will store refresh tokens, under the @code{webid-oidc} directory. For a system service, you might want to define that environment to @code{/var/lib}, for instance. The @emph{XDG_CACHE_HOME} should point to a directory where to store the seed of the random number generator (under a @code{webid-oidc} directory, again). Changing the seed only happens when a program starts to require the random number generator. You can safely delete this directory, but you need to restart the program to actually change the seed. @node Running a Resource Server @chapter Running a Resource Server @menu * The authenticator:: * The full server:: * Resources stored on the server:: @end menu A Solid server is the server that manages your data. It needs to check that the proofs of possession are correct, and the possessed key is signed by the identity provider. @node The authenticator @section The authenticator In @emph{(webid-oidc resource-server)}, the following function gives a simple API for a web server: @deffn function make-authenticator @var{jti-list} @var{[#server-uri]} @var{[#current-time]} @var{[#http-get]} Create an authenticator, i.e. a function that takes a request and request body and returns the webid of the authenticated user, or @code{#f} if it is not authenticated. To prevent replay attacks, each request is signed by the client with a different unique padding value. If such a value has already been seen, then the request must fail. The authenticator expects the client to demonstrate the possession of a key that the identity provider knows. So the client creates a DPoP proof, targetted to a specific URI. In order to check that the URI is correct, the authenticator needs the public URI of the service. The JTIs are checked within a small time frame. By default, the system time will be used. Otherwise, you can customize the @code{current-time} optional keyword argument, to pass a thunk returning a time from @emph{(srfi srfi-19)}. You may want to customize the @var{http-get} optional keyword argument to pass a function to replace @code{http-get} from @emph{(http client)}. This function takes an URI and optional @code{#:headers} arguments, makes the request, and return two values: the response, and the response body. This function, in @emph{(webid-oidc resource-server)}, returns a web request handler, taking the request and request body, and returning the subject of the access token. If an error happens, it is thrown; the function always returns a valid URI. @end deffn @node The full server @section The full server @deffn {function from @emph{(webid-oidc resource-server)}} make-server @var{[#:server-uri]} @var{[#:owner]} @var{[#:authenticator]} @var{[#:current-time]} @var{[#:http-get]} Return a server handler, a function taking 2 values, a request and a request body, and returning 2 values, the response and response body. The optional @var{[#:authenticator]} argument defaults to the webid-oidc authenticator, @var{[#:current-time]} defaults to a thunk returning the system time and @var{[#:http-get]} to the web client from @emph{(web client)}. @end deffn @node Resources stored on the server @section Resources stored on the server To store and serve resources, the server has two distinct mechanisms. A @dfn{content} is a read-only possible value for a resource, indexed by etags, and a @dfn{path} is a mutable value that indicates the etag of the resource, and of the auxiliary resources (description and ACL). With this separation, it is possible to atomically delete a resource and all associated auxiliary resources, by unlinking the corresponding @emph{path}. It is also possible to mutate separately the ACL and the resource itself without writing a copy for both. The @emph{content} API is contained in the @code{(webid-oidc server resource content)} module. @deffn function with-session @var{f} Call @var{f} with 5 arguments: @itemize @item a function to get the content-type of a given etag; @item a function to list the paths contained within the resource; @item a function to load the content of a given etag; @item a function to create a new content; @item a function to remove a content from the file system. It is still possible to query it with the first 3 functions, but new sessions will not see it. @end itemize Since the contents are read-only, it is possible to cache the value of the content in memory. This is why @var{f} should run within a session with memoization. Resources only store @emph{static} content, because the membership triples for containers is considered dynamic and not included in the representation. The first 3 functions as well as the last one are called with an etag, and the function to create a content is called with the content-type, list of contained paths, and (static) content. The contents are searched in the @emph{server/content} subdirectory of @var{data-home}. @end deffn @deffn parameter data-home Defines the directory where to store persistent data. Defaults to @emph{XDG_DATA_HOME}. @end deffn The @emph{path} API is defined in @code{(webid-oidc server resource path)}. @deffn function read-path @var{path} Read the resource at @var{path}, and return 2 values: @enumerate @item the ETag of the main resource; @item an alist where keys are auxiliary resource type URIs (the type is from @code{(web uri)}), and the values are ETags of the corresponding resource. @end enumerate If the resource is not found, raise an exception with type @code{&path-not-found}, and maybe @code{&uri-slash-semantics-error} if a resource with a different ending-in-slash exists. This function is safe to call when the path is being modified, either by another thread, process or else, as the returned values will always be consistent. However, once the function returns, an updating process may have deleted the returned ETags. If this is the case, then you must call this function again to read the updated path. @end deffn @deffn function update-path @var{path} @var{f} @var{content-type} @var{contained} @var{static-content} @var{create} @var{delete} [@var{#:create-intermediate-containers?}=@code{#f}] Read @var{path}, call @var{f} with two values: the ETag and the auxiliary ETags (as returned by @var{read-path}), and update the path accordingly. If @var{path} does not exist, then the first argument is @code{#f} and the second one is the empty list. If @var{f} returns @code{#f}, then the resource is deleted. If @var{f} returns an ETag as the first returned value and an alist of auxiliary resource ETags as the second value, then the resource is updated. The last functions are from the content API. Since creating or deleting children requires updating the parent, we need them. Some operations should create the intermediate containers for a given path, this is the case for the @code{PUT} HTTP verb. For @code{POST}, the parent should exist. The @var{#:create-intermediate-containers?} switch lets you change the behavior. In any case, it is an error to delete a non-empty container. The update is atomic, meaning that at any point in time the file is fully written out. Concurrent access to the same resource is performed by locking the lock file named @var{X}/.lock, where @var{X} is the first character of the base64-url sha-256 hash of the path. @strong{The lock file is not meant to be removed} when the resource is unlocked. It should be locked with @code{flock} instead. @strong{Like other forms of lock-based synchronization, this function is not composable}. This means that you cannot call this function within @var{f}, otherwise a deadlock may ensue. If the resource is created or deleted, then the parent resource is updated as well. To avoid deadlocks with other processes, please follow the following rules: lock the path, then lock the parent path, then update the parent, then unlock the parent, and finally unlock the child path. @end deffn The Web Access Control specification defines an RDF vocabulary to check whether a given user is allowed to perform some operations. The @code{(webid-oidc server resource wac)} helps you do that. @deffn function wac-get-modes @var{server-name} @var{path} @var{user} @var{[#:http-get]} Return the list of modes that are allowed for @var{user} accessing @var{path}. The @var{server-name} URI is required to find the relevant triples in the ACL. If @var{user} is unauthenticated, pass @code{#f}. Please note that in any case, the data owner should have all rights whatsoever, bypassing WAC. Otherwise, it is possible to steal control away from the data owner. @end deffn @deffn function check-acl-can-read @var{server-name} @var{path} @var{owner} @var{user} @var{[#:http-get]} @deffnx function check-acl-can-write @var{server-name} @var{path} @var{owner} @var{user} @var{[#:http-get]} @deffnx function check-acl-can-append @var{server-name} @var{path} @var{owner} @var{user} @var{[#:http-get]} @deffnx function check-acl-can-control @var{server-name} @var{path} @var{owner} @var{user} @var{[#:http-get]} Assert that the resource at @var{path} on @var{server-name} is owned by @var{owner}, and check that @var{user} has the proper authorization. Otherwise, raise an exception of type @code{&forbidden}. @end deffn @node Running a client @chapter Running a client To run a client, you need to proceed in two steps. First, acquire an OIDC ID token and an access token from the identity provider, and then present the access token and a proof of possession of the linked key in each request, in a DPoP HTTP header. The first operation is performed by the @emph{(webid-oidc client)} module. @deffn function authorize @var{host/webid} @var{#client-id} @var{#redirect-uri} @var{[#state]} @var{[#http-get]} The user enters a valid webid or a host name, and then this function will query it (with the @var{http-get} parameter, by default the web client from @emph{(web client)}) to determine the authorization endpoint. The function will return an alist of authorization URIs, indexed by approved identity provider URIs, that the user should browse with a traditional web browser. Each application should have its own webid, or in that case @var{client-id}, that can be dereferenced by the identity provider. Once the user has given authorization, the user’s agent will be redirected to @var{redirect-uri}, with the authorization code as a GET parameter. It is possible to pass a @var{state}, but this is optional. @end deffn Once the client gets the authorization code, it is necessary to create an access token and ID token. @deffn function token @var{host} @var{client-key} @var{[#authorization-code]} @var{[#refresh-token]} @var{[#http-get]} @var{[#http-post]} @var{[#current-time]} Trade an @var{authorization-code}, or a @var{refresh-token}, for an ID token and an access token bound to the @var{client-key} issued by @var{host}, the identity provider. You can override the HTTP client used (@var{http-get} and @var{http-post}), and how to compute the time (@var{current-time}). @end deffn In an application, you would have a list of profiles in XDG_DATA_HOME, consisting of triples (webid, issuer, refresh token). @deffn function list-profiles @var{[#dir]} Read the list of available profiles. Returns a list of triples, webid, issuer, reresh token. By default, this function will look for the profiles file in @var{XDG_DATA_HOME}. You can bypass it by providing the @var{#dir} optional keyword argument. @end deffn @deffn function setup @var{get-host/webid} @var{choose-provider} @var{browse-authorization-uri} @var{#client-id} @var{#redirect-uri} @var{[#dir]} @var{[#http-get]} @var{[#http-post]} @var{[#current-time]} Negociate a refresh token, and save it. The function returns 3 values: the decoded ID token pyload, the encoded access token and the key pair. The @var{get-host/webid} thunk should ask the user’s webid or identity provider, and return it. @var{choose-provider} is called with a list of possible identity providers as host names (strings), and the user should choose one. The chosen one is returned. Finally, @var{browse-authorization-uri} should ask or let the user browse an URI as its argument, and return the authorization code taken from the redirect URI. The refresh token is saved to disk, as a profile, in XDG_DATA_HOME. Pass the optional @var{#dir} keyword argument to override the location. You need to set @var{client-id} to the public webid of the app, and @var{redirect-uri} to one of the approved redirection URIs for the application ID. @end deffn @deffn function login @var{webid} @var{issuer} @var{refresh-token} @var{key} @var{[#dir]} @var{[#http-get]} @var{[#http-post]} @var{[#current-time]} If you have already a known profile, you can use it to automatically log in. This function might update the refresh token if it changed, so you can again set @var{#dir}. Please note that the @var{refresh-token} is bound to the client @var{key} on server side, so you must always use the same @var{key}. @end deffn @deffn function refresh @var{id-token} @var{key} @var{[#dir]} @var{[#http-get]} @var{[#http-post]} @var{[#current-time]} If you have an ID token bound to a known profile, this helper function will look up the associated refresh token and log in. @end deffn @deffn function make-client @var{id-token} @var{access-token} @var{key} @var{[#dir]} @var{[#http-get]} @var{[#http-post]} @var{[#http-request]} @var{[#current-time]} Return a replacement of @code{http-request} from @emph{(web client)}, that automatically signs requests and refresh the tokens when needed. @var{#http-get} and @var{#http-post} are only used to refresh the tokens, while @var{#http-request} is used as a back-end for the requests. @var{#current-time} is set to a thunk that returns the time. It is used to issue DPoP proofs. @end deffn An example application is provided as the @code{disfluid-example-app} program. It demonstrates how authentication is done. It should help you understand how Solid-OIDC works. The identity provider needs to call the application on the web. So, your client should have a public endpoint on the web. @deffn function serve-application @var{id} @var{redirect-uri} @var{[#client-name]} @var{[#client-uri]} Return a handler for web requests to serve the application manifest and the redirection to transmit the authorization code. You should set the @var{client-name} to your application name and @var{client-uri} to point to where to a presentation of your application. @end deffn @node Exceptional conditions @chapter Exceptional conditions The library will raise an exception whenever something fishy occurs. For instance, if a signature is invalid, or the expiration date has passed. All exception types are defined in @code{(webid-oidc errors)}. @deffn function error->str @var{error} @var{[#depth]} Return a string explaining the @var{error}. You can limit the @var{depth} of the explanation as an integer. @end deffn @menu * Invalid data format:: * Invalid JWT:: * Cannot fetch data on the web:: * Other errors in the protocol or from a reasonable implementation:: * Server-side errors:: @end menu @node Invalid data format @section Invalid data format There are a few JSON objects with required fields. This exceptions usually occur as the cause of a higher-level exception. @deftp {exception type} ¬-base64 @var{value} @var{cause} This exception is raised when the base64 decoding function failed. @var{value} is the incorrect input, and @var{cause} is a low-level error. @end deftp @deftp {exception type} ¬-json @var{value} @var{cause} Cannot decode @var{value} to a JSON object. @end deftp @deftp {exception type} ¬-turtle @var{value} @var{cause} Cannot decode @var{value} to a RDF graph. @end deftp @deftp {exception type} &incorrect-webid-field @var{value} The @var{value} of the webid field in the JWT is missing (if @code{#f}), or not an acceptable value. @end deftp @deftp {exception type} &incorrect-iss-field @var{value} The @var{value} of the iss field is incorrect. @end deftp @deftp {exception type} &incorrect-aud-field @var{value} The @var{value} of the aud field is incorrect. @end deftp @deftp {exception type} &incorrect-iat-field @var{value} The @var{value} of the iat field is incorrect. @end deftp @deftp {exception type} &incorrect-exp-field @var{value} The @var{value} of the exp field is incorrect. @end deftp @deftp {exception type} &incorrect-cnf/jkt-field @var{value} The @var{value} of the cnf/jkt field is incorrect. @end deftp @deftp {exception type} &incorrect-client-id-field @var{value} The @var{value} of the client-id field is incorrect. @end deftp @deftp {exception type} &incorrect-typ-field @var{value} The @var{value} of the typ field in the DPoP proof header is incorrect. @end deftp @deftp {exception type} &incorrect-jwk-field @var{value} @var{cause} The @var{value} of the jwk field in the DPoP proof header is incorrect. @end deftp @deftp {exception type} &incorrect-jti-field @var{value} The @var{value} of the jti field in the DPoP proof is incorrect. @end deftp @deftp {exception type} &incorrect-htm-field @var{value} The @var{value} of the htm field in the DPoP proof is incorrect. @end deftp @deftp {exception type} &incorrect-htu-field @var{value} The @var{value} of the htu field in the DPoP proof is incorrect. @end deftp @deftp {exception type} &incorrect-ath-field @var{value} The @var{value} of the ath field is not the hash of the access token. @end deftp @deftp {exception type} &incorrect-redirect-uris-field @var{value} The @var{value} of the redirect-uris field of a client manifest is incorrect. @end deftp @deftp {exception type} &incorrect-typ-field @var{value} The @var{value} of the typ field in the DPoP proof header is incorrect. @end deftp @deftp {exception type} &incorrect-sub-field @var{value} The @var{value} of the sub field is incorrect. @end deftp @deftp {exception type} &incorrect-iss-field @var{value} The @var{value} of the iss field is incorrect. @end deftp @deftp {exception type} &incorrect-nonce-field @var{value} The @var{value} of the nonce field in the DPoP proof is incorrect. @end deftp @deftp {exception type} &incorrect-htm-field @var{value} The @var{value} of the htm field in the DPoP proof is incorrect. @end deftp @deftp {exception type} ¬-a-client-manifest @var{value} @var{cause} The @var{client-manifest} is incorrect. @end deftp @node Invalid JWT @section Invalid JWT Each JWT type – access token, DPoP proof, ID token, authorization code (this is internal to the identity provider) has different validation rules, and can fail in different ways. @deftp {exception type} &unsupported-crv @var{crv} The identifier @var{crv} does not identify an elliptic curve. @end deftp @deftp {exception type} ¬-a-jwk @var{value} @var{cause} @var{value} does not identify a JWK. @end deftp @deftp {exception type} ¬-a-public-jwk @var{value} @var{cause} @var{value} does not identify a public JWK. @end deftp @deftp {exception type} ¬-a-private-jwk @var{value} @var{cause} @var{value} does not identify a private JWK. @end deftp @deftp {exception type} ¬-a-jwks @var{value} @var{cause} @var{value} does not identify a set of public keys. @end deftp @deftp {exception type} &unsupported-alg @var{value} @var{value} does not identify a valid hash algorithm. @end deftp @deftp {exception type} &invalid-signature @var{key} @var{payload} @var{signature} @var{key} has not signed @var{payload} with @var{signature}. @end deftp @deftp {exception type} &missing-alist-key @var{value} @var{key} @var{value} isn’t an alist, or is missing a value with @var{key}. @end deftp @deftp {exception type} ¬-a-jws-header @var{value} @var{cause} @var{value} does not identify a decoded JWS header. @end deftp @deftp {exception type} ¬-a-jws-payload @var{value} @var{cause} @var{value} does not identify a decoded JWS payload. @end deftp @deftp {exception type} ¬-a-jws @var{value} @var{cause} @var{value} does not identify a decoded JWS. @end deftp @deftp {exception type} ¬-in-3-parts @var{string} @var{separator} @var{string} cannot be split into 3 parts with @var{separator}. @end deftp @deftp {exception type} &no-matching-key @var{candidates} @var{alg} @var{payload} @var{signature} No key among @var{candidates} could verify @var{signature} signed with @var{alg} for @var{payload}, because the signature mismatched for all keys. @end deftp @deftp {exception type} &cannot-decode-jws @var{value} @var{cause} The @var{value} string is not an encoding of a valid JWS. @end deftp @deftp {exception type} &cannot-encode-jws @var{jws} @var{key} @var{cause} The @var{jws} cannot be signed. @end deftp @deftp {exception type} ¬-an-access-token @var{value} @var{cause} The @var{value} is not an access token. @end deftp @deftp {exception type} ¬-an-access-token-header @var{value} @var{cause} The @var{value} is not an access token header. @end deftp @deftp {exception type} ¬-an-access-token-payload @var{value} @var{cause} The @var{value} is not an access token payload. @end deftp @deftp {exception type} &cannot-decode-access-token @var{value} @var{cause} The @var{value} string is not an encoding of a valid access token. @end deftp @deftp {exception type} &cannot-encode-access-token @var{access-token} @var{key} @var{cause} The @var{access-token} cannot be signed. @end deftp @deftp {exception type} ¬-a-dpop-proof @var{value} @var{cause} The @var{value} is not a DPoP proof. @end deftp @deftp {exception type} ¬-a-dpop-proof-header @var{value} @var{cause} The @var{value} is not a DPoP proof header. @end deftp @deftp {exception type} ¬-a-dpop-proof-payload @var{value} @var{cause} The @var{value} is not a DPoP proof payload. @end deftp @deftp {exception type} &cannot-decode-dpop-proof @var{value} @var{cause} The @var{value} string is not an encoding of a valid DPoP proof. @end deftp @deftp {exception type} &cannot-encode-dpop-proof @var{dpop-proof} @var{key} @var{cause} The @var{dpop-proof} cannot be signed. @end deftp @deftp {exception type} ¬-an-authorization-code @var{value} @var{cause} The @var{value} is not an authorization code. @end deftp @deftp {exception type} ¬-an-authorization-code-header @var{value} @var{cause} The @var{value} is not an authorization code header. @end deftp @deftp {exception type} ¬-an-authorization-code-payload @var{value} @var{cause} The @var{value} is not an authorization code payload. @end deftp @deftp {exception type} &cannot-decode-authorization-code @var{value} @var{cause} The @var{value} string is not an encoding of a valid authorization code. @end deftp @deftp {exception type} &cannot-encode-authorization-code @var{authorization-code} @var{key} @var{cause} The @var{authorization-code} cannot be signed. @end deftp @deftp {exception type} ¬-an-id-token @var{value} @var{cause} The @var{value} is not an ID token. @end deftp @deftp {exception type} ¬-an-id-token-header @var{value} @var{cause} The @var{value} is not an ID token header. @end deftp @deftp {exception type} ¬-an-id-token-payload @var{value} @var{cause} The @var{value} is not an ID token payload. @end deftp @deftp {exception type} &cannot-decode-id-token @var{value} @var{cause} The @var{value} string is not an encoding of a valid ID token. @end deftp @deftp {exception type} &cannot-encode-id-token @var{id-token} @var{key} @var{cause} The @var{id-token} cannot be signed. @end deftp @node Cannot fetch data on the web @section Cannot fetch data on the web In the client (local and public parts), resource server and identity provider, the protocol requires to fetch data on the web. @deftp {exception type} &request-failed-unexpectedly @var{response-code} @var{response-reason-phrase} We expected the request to succeed, but the server sent a non-OK @var{response-code}. @end deftp @deftp {exception type} &unexpected-header-value @var{header} @var{value} We did not expect the server to respond with @var{header} set to @var{value}. @end deftp @deftp {exception type} &unexpected-response @var{response} @var{cause} The @var{response} (from @emph{(web response)}) is not appropriate. @end deftp @deftp {exception type} ¬-an-oidc-configuration @var{value} @var{cause} The @var{value} is not appropriate an OIDC configuration. @end deftp @deftp {exception type} &cannot-fetch-issuer-configuration @var{issuer} @var{cause} It is impossible to fetch the configuration of @var{issuer}. @end deftp @deftp {exception type} &cannot-fetch-jwks @var{issuer} @var{uri} @var{cause} It is impossible to fetch the keys of @var{issuer} at @var{uri}. @end deftp @deftp {exception type} &cannot-fetch-linked-data @var{uri} @var{cause} Could not fetch the graph referenced by @var{uri}. @end deftp @deftp {exception type} &cannot-fetch-client-manifest @var{id} @var{cause} Could not fetch a client manifest at @var{id}. @end deftp @node Other errors in the protocol or from a reasonable implementation @section Other errors in the protocol or from a reasonable implementation The protocol does not rely solely on JWT validation, so these errors may happen too. @deftp {exception type} &dpop-method-mismatch @var{signed} @var{requested} The method value @var{signed} in the DPoP proof does not match the method that is @var{requested} on the server. @end deftp @deftp {exception type} &dpop-uri-mismatch @var{signed} @var{requested} The URI value @var{signed} in the DPoP proof does not match the URI that is @var{requested} on the server. @end deftp @deftp {exception type} &dpop-signed-in-future @var{signed} @var{current} The proof is @var{signed} for a date which is too much ahead of the @var{current} time. @end deftp @deftp {exception type} &dpop-too-old @var{signed} @var{current} The proof was @var{signed} at a past date of @var{current}. @end deftp @deftp {exception type} &dpop-unconfirmed-key @var{key} @var{expected} @var{cause} The confirmation of @var{key} is not what is @var{expected}, or (if a function was passed as @var{cnf/check}) the @var{cause} exception occurred while confirming. @end deftp @deftp {exception type} &dpop-invalid-access-token-hash @var{hash} @var{access-token} The @var{access-token} passed to the resource server does not match the @var{hash} provided in the DPoP proof. @end deftp @deftp {exception type} &jti-found @var{jti} @var{cause} The @var{jti} of the proof has already been issued in a recent past. @end deftp @deftp {exception type} &unauthorized-redirection-uri @var{manifest} @var{uri} The authorization @var{uri} is not advertised in @var{manifest}. @end deftp @deftp {exception type} &cannot-serve-public-manifest You cannot serve the public client manifest. @end deftp @deftp {exception type} &no-client-manifest-registration @var{id} The @var{id} client manifest does not have a registration triple in its document. @end deftp @deftp {exception type} &inconsistent-client-manifest-id @var{id} @var{advertised-id} The client @var{manifest} is being fetched at @var{id}, but it is valid for another client @var{advertised-id}. @end deftp @deftp {exception type} &authorization-code-expired @var{exp} @var{current-time} The authorization code has expired at @var{exp}, it is now @var{current-time}. @end deftp @deftp {exception type} &invalid-refresh-token @var{refresh-token} The @var{refresh-token} is unknown to the identity provider. @end deftp @deftp {exception type} &invalid-key-for-refresh-token @var{key} @var{jkt} The refresh token was issued for @var{jkt}, but it is used with @var{key}. @end deftp @deftp {exception type} &unknown-client-locale @var{web-locale} @var{c-locale} The @var{web-locale} of the client, translated to C as @var{c-locale}, cannot be set. This exception is always continuable; if the handler returns, then the page will be served in the english locale. @end deftp @deftp {exception type} &unsupported-grant-type @var{value} The token request failed to indicate a @var{value} for the grant type, or indicated an unsupported grant type. @end deftp @deftp {exception type} &no-authorization-code The token request forgot to put an authorization code. @end deftp @deftp {exception type} &no-refresh-token The token request forgot to put a refresh token with the request. @end deftp @deftp {exception type} &unconfirmed-provider @var{subject} @var{provider} @var{provider} is not confirmed by @var{subject} as an identity provider. @end deftp @deftp {exception type} &no-provider-candidates @var{webid} @var{causes} The @var{webid} cannot be certified by any identity providers. The @var{causes} alist indicates an error for each candidates. @end deftp @deftp {exception type} &neither-identity-provider-nor-webid @var{uri} @var{why-not-identity-provider} @var{why-not-webid} The @var{uri} you passed to get an authorization code is neither an identity provider (because @var{why-not-identity-provider}) nor a webid (because @var{why-not-webid}). @end deftp @deftp {exception type} &token-request-failed @var{cause} The token request failed on the server. @end deftp @deftp {exception type} &profile-not-found @var{webid} @var{iss} @var{dir} The @var{webid}, as certified by @var{iss}, cannot be refreshed because we don’t have a refresh token stored in @var{dir}. @end deftp @node Server-side errors @section Server-side errors The resource server implementation may encounter some more exceptional conditions. @deftp {exception type} &path-not-found @var{path} There is no registered resource at @var{path}. @end deftp @deftp {exception type} &auxiliary-resource-absent @var{path} @var{kind} The auxiliary resource of given @var{kind} is not instanciated on the server for the base resource @var{path}. @end deftp @deftp {exception type} &uri-slash-semantics-error @var{path} @var{expected-path} While the resource at @var{path} does not exist, the resource at @var{expected-path} does, and @var{path} and @var{expected-path} differ only by a trailing slash. This exception may be raised along with @code{&path-not-found}. Beware that even if it is true at the time when the exception is created, maybe the resource has been created by the time it is handled. @end deftp @deftp {exception type} &cannot-delete-root There was a request to delete the root storage, which is an error. @end deftp @deftp {exception type} &container-not-empty @var{path} There was a request to delete a non-empty container. @end deftp @deftp {exception type} &cannot-fetch-group @var{group-uri} @var{cause} The access control could not fetch the group @var{group-uri} (with a known @var{cause}). This warning is continuable every time it is raised. If the handler returns, then the group will be considered empty. @end deftp @deftp {exception type} &incorrect-containment-triples @var{path} The client wanted to create or update a resource, and by that it tried to change the containment triples at @var{path}. @end deftp @deftp {exception type} &unsupported-media-type @var{content-type} The client wanted to create a resource with the given @var{content-type}, but it is not accepted, because @var{content-type} is not recognized as an RDF content type. @end deftp @deftp {exception type} &path-is-auxiliary @var{path} The client wanted to create a resource that targets an auxiliary resource, at @var{path}. @end deftp @deftp {exception type} &forbidden @var{path} @var{user} @var{owner} @var{mode} The @var{user} wanted to do something under @var{path} requiring @var{mode}, but it is not the @var{owner} and it is forbidden by WAC. @end deftp @deftp {exception type} &precondition-failed @var{path} @var{if-match} @var{if-none-match} @var{real-etag} The resource under @var{path} has a @var{real-etag} that does not match the request headers @var{if-match} and @var{if-none-match}. If the resource does not exist, @var{real-etag} is set to @code{#f}. In this case, an exception of type @code{&path-not-found} is also thrown. @end deftp @deftp {exception type} ¬-acceptable @var{client-accepts} @var{path} @var{content-type} The client wanted a response with a specific set of @var{client-accept}ed content-types, but the real @var{content-type} of the resource under @var{path} cannot be converted to one of them. @end deftp @node GNU Free Documentation License @appendix GNU Free Documentation License @include fdl.texi @node Index @unnumbered Index @printindex cp @bye