Postfix Overview - Global Architecture


Note: this web page is no longer maintained. It exists only to avoid breaking links in web pages that describe earlier versions of the Postfix mail system.

Up one level | Introduction | Goals and features | Global architecture | Queue Management | Security

Introduction

Some mail systems such as Sendmail are implemented as one large monolithic program that does everything. One large program certainly makes it easy to share data between different parts of the system. Unfortunately, one large program also makes it easy to make fatal mistakes. Other mailers such as qmail use a rigid hierarchy of programs that run other programs in a fixed order and throw them away after use. This approach gives better insulation, at the cost of some process creation overhead and inter-process communication. The additional cost can be kept within acceptable limits by partitioning the work in a sensible manner.

Postfix architecture

Postfix is based on semi-resident, mutually-cooperating, processes that perform specific tasks for each other, without any particular parent-child relationship. Again, doing work in separate processes gives better insulation than using one big program. In addition, the Postfix approach has the advantage that a service such as address rewriting is available to every Postfix component program, without incurring the cost of process creation just to rewrite one address. By the way: I do not claim that Postfix is the only (mail) program using this approach. Even in this relatively young discipline it is hard to come up something new that no-one ever did before.

Postfix is implemented as a resident master server that runs Postfix daemon processes on demand: daemon processes to send or receive network mail messages, daemon processes to deliver mail locally, etc. These processes are created up to a configurable number, are re-used for a configurable number of times, and go away after a configurable amount of idle time. This approach drastically reduces process creation overhead while still providing the good insulation from separate processes.

Postfix is intended to be a Sendmail replacement. For this reason it tries to be compatible with existing infrastructure. However, many parts of the Postfix system, such as the local delivery program, are easily replaced by editing an inetd-like configuration file. For example, the plan is to provide an alternate local delivery program that runs at a fixed low privilege, for POP/IMAP users that never log into the shell, and that may not even have a UNIX account.

As a result of this architecture, Postfix is easy to strip down to the bare minimum. Subsystems that are turned off cannot be exploited. Firewalls do not need local delivery. On client workstations, one disables both the smtp listener and local delivery subsystems; or the client mounts the maildrop directory from a file server, and runs no resident Postfix processes at all.

Communication between Postfix processes

The core of the Postfix system is implemented by a dozen semi-resident programs. For privacy reasons, these Postfix processes communicate via UNIX-domain sockets or FIFOs that live in a protected directory. Despite this privacy, Postfix processes do not really trust the data that they receive in this manner; just like the contents of Postfix queue files, they merely treat it as gossip.

The amount of information passed on between Postfix processes is limited. In many cases, the only information exchanged between Postfix processes is a queue file name and a list of recipients or some status information. Once an email message is saved to file it stays there until it is read by a mail delivery program.

Postfix takes the usual precautions to avoid loss of information: flush and fsync() all data before acknowledging receipt, and check all system call results for error conditions. This style of programming may be new to some people, but I can assure you that it has been standard practice for years in many places.


Up one level | Introduction | Goals and features | Global architecture | Queue Management | Security