This document tries to describe the software layout and design of nss-pam-ldapd. It should provide some help for contributing code to this package. CONTRIBUTING TO NSS-PAM-LDAPD ============================= Contributions to nss-pam-ldapd are most welcome. Integrating contributions will be done on a best-effort basis and can be made easier if the following are considered: * for large changes it is a good idea to send an email first * send your patches in unified diff (diff -u) format, Git patches or Git pull requests * try to use the Git version of the software to develop the patch * clearly state which problem you're trying to solve and how this is accomplished * please follow the existing coding conventions * please test the patch and include information on tested platforms, etc. * add a copyright statement with the patch if you feel the contribution is significant enough (e.g. more than a few lines) * ensure that the code you contribute can be integrated in the project under the LGPL (when including third-party code, retain copyright information license, you have permission to distribute the code, etc.) Please email nss-pam-ldapd-users@lists.arthurdejong.org if you want to contribute. All contributions will be acknowledged in the AUTHORS file. BUILD DEPENDENCIES ================== For building Git snapshots the following tools are needed: * autoconf (2.65 is currently used but 2.61 is minimal) * automake (1.14 is currently used but older versions may also work) * OpenLDAP libraries (2.4 is generally used) * PAM libraries * optionally a Kerberos library (MIT Kerberos is tested) * optionally a SASL library (only Cyrus SASL is tested) * docbook2x for generating the manual pages To build the Git snapshot run the autogen.sh shell script to build the configure script. When developing patches please use --enable-warnings with configure and avoid introducing new warnings. RELEASE VERSIONING ================== The versioning scheme of nss-pam-ldapd is a simple major.minor.micro numbering. The idea is to keep a stable (x.y) branch that only gets bug fixes and small enhancements while development goes in another branch. Backwards incompatible changes should be announced clearly. GENERAL DESIGN ============== The basic design splits the functionality in three parts. The NSS part interfaces with libc and translates the NSS requests into simple generic requests (e.g. "get user with name test", "get group with gid 101" or "get all shadow entries"). Another part is the PAM module which handles authentication requests from the system. The PAM operations are also translated into atomic, stateless requests. Both these parts translate the queries in a simple protocol used to communicate with the nslcd daemon. This daemon translates the requests into LDAP searches. As a result, the NSS and PAM modules don't need to known anything about LDAP (in fact replacing it with another lookup method should be very simple) and don't have to link with the LDAP libraries. libc NSS -> libnss_ldap.so \ |-> nslcd -> OpenLDAP -> LDAP server / PAM stack -> pam_ldap.so An alternative implementation of nslcd in Python is provided as pynslcd. This implementation is less mature but it easier to add advanced features there. A collection of utilities is also provided that communicate with nslcd that can provide additional functions. design goals ------------ * make it as simple as possible * simpler configuration and semantics * simpler, clearer and completer documentation * split source code into manageable parts * get rid of unneeded code and complexity * have a stable, easily maintainable piece of high quality software NSS MODULE ========== The NSS module is implemented in the nss directory. The functions are split into files according to the database they support. The files support multiple NSS implementations. The NSS interface is specific to the C library that is used. The original implementation was for the GNU C Library but now also includes an implementation for Solaris' C Library and has some support for FreeBSD. GNU C Library notes ------------------- Function definitions for glibc look like: _nss_ldap_FUNCTION_r(...) This function opens the connection to the nslcd (with a time-out), builds the correct data structures and does a request (write()) to the nslcd waiting for an answer (again with a time-out) The complete list of exported functions can be found in exports.linux and prototypes.h. Currently a number of macros are used to build most of the function bodies for these functions. Part of this is defined in the common/nslcd-prot.h file and the NSS-specific stuff is in nss/common.h. For memory management, the general mechanism that is expected to be used is to return NSS_STATUS_TRYAGAIN and set errno to ERANGE. This causes glibc to retry the request with a larger buffer. Some useful links: http://www.gnu.org/software/libc/manual/html_node/index.html Solaris C Library notes ----------------------- The Solaris C library uses a different mechanism. For each map a back-end object is allocated per thread which is used to do queries. The object is created with a constructor (e.g. _nss_ldap_passwd_constr()) that returns a back-end that contains a list of function pointer to lookup methods and a destructor. A buffer is passed with every request but a local buffer that is stored in the back-end can presumably also be created. Earlier versions of Solaris expected the NSS functions to return the binary representation of the lookups (e.g. struct passwd) but later versions expect a string representation of the data to be returned (just like a single line out of /etc/passwd was read) but only if running from nscd. If args->buf.result is NULL a string representation is requested (except for ether by address lookup which is special). Source and documentation pointers for Solaris NSS: https://java.net/projects/solaris/sources/on-src/show/usr/src/lib/nsswitch https://java.net/projects/solaris/sources/on-src/content/usr/src/head/nss_common.h https://java.net/projects/solaris/sources/on-src/content/usr/src/head/nss_dbdefs.h https://hg.openindiana.org/upstream/illumos/illumos-gate/file/tip/usr/src/lib/nsswitch https://hg.openindiana.org/upstream/illumos/illumos-gate/file/tip/usr/src/head/nss_common.h https://hg.openindiana.org/upstream/illumos/illumos-gate/file/tip/usr/src/head/nss_dbdefs.h FreeBSD C Libarary notes ------------------------ The FreeBSD C library seems to have support for exposing GNU C Library NSS module functions through a wrapper function. This makes it very easy to implement NSS support on FreeBSD. Pointers for more documentation on this is welcome. Some information is available here: http://www.freebsd.org/cgi/man.cgi?query=nsdispatch https://github.com/freebsd/freebsd/blob/master/include/nss.h PAM MODULE ========== The PAM module is implemented in the pam directory. Implementation is fairly straight-forward. The PAM module stores some state between calls to nslcd in a struct. The calls to nslcd are however stateless. The PAM module may supply some information that help lookups (most notably DNs of user entries). Care must be taken with the communication because the nslcd requests are not authenticated (e.g. changing passwords requests should include all credentials). The PAM requests may result in state changes on the LDAP server and this is where they are most notably different from the NSS requests. Some useful links: http://www.kernel.org/pub/linux/libs/pam/ http://www.opengroup.org/tech/rfc/rfc86.0.html THE COMMUNICATIONS PROTOCOL =========================== The protocol used for communicating between the NSS library and PAM module on one end and the nslcd daemon on the other is very simple and almost fully described in the nslcd.h header file. The common/nslcd-prot.h header file defines some macros that are used for reading and writing protocol entities (strings, 32-bit integers, etc). Every NSS database has a corresponding source file in the nss and the nslcd directory. The PAM module is built up of a single file in both the pam and nslcd directories. If the protocol is changed in an incompatible way the protocol version should be incremented in nslcd.h. There is currently no versioning scheme available for this. A communications module (common/tio.c) was made so we can define simpler semantics for time-out values and buffer sizes. All components use this module which means that it includes functionality that is needed for both (e.g. large write buffers for the server part and large resettable read buffers for the NSS part). Maybe building two modules from the same source with different features in them is an option (e.g. the NSS part needs the read buffers and handling of SIGPIPE and the nslcd part needs the write buffers and possibly flushing in the background). The common directory also contains some other generally useful modules that are used in some components. SERVER PART =========== At the server end a dispatcher picks up the request and delegates it to one of the database specific functions. nslcd_FUNCION(...) This functions fills in the correct parameters from the request. This function should write responses to the stream. Big parts of the request handling functions are generated by macros because the structure is very similar across the different NSS requests. SECURITY NOTES ============== This design does open up the system to more potential security issues (relative to nss_ldap) because there is now a local interface to a daemon with privileges. With nss_ldad, processes could only potentially exploit bugs in the library and gain the privileges of the process that was doing the name lookups. In this case the privileges of the daemon are potentially exposed. Extra care should be taken with processes that normally require extra privileges (getting shadow entries, authentication, updating session information, etc). Any user on the system can perform nslcd queries so either the nslcd daemon needs to check the userid of the caller or the request needs to contain the needed credentials itself. On the other hand the design also offers some security improvements. It is much easier to handle security updates of the LDAP, SSL or related libraries and access to privileged LDAP configuration information can be much better constrained. TEST SET-UP =========== In the test directory there are a number of tests available. See the file README in the test directory for more details.