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>>> 2021-09-30 the original microcell

Many readers may know that, historically, telephone instruments (e.g. the thing you hold up to your face and talk into) have been considered part of the telephone system proper. In practice, that meant that up until the '70s most people leased their phones from the telephone company, and the telephone company maintained everything from the exchange office to the side of your head.

The biggest landmark in the shift of telephone instruments from "part of AT&T" to personal property that you can buy at WalMart is the "Carterfone decision." The Carterfone precedent, that telephone users could connect anything they want to the telephone network as long as it is reasonably well-functioning and compatible, created the entire modern industry of telephones and accessories. What's only remembered a little hazily, though, is what the Carterfone actually was---the original device that fought for telephone interconnection.

The Carterfone was an acoustic coupler that allowed a telephone handset to be connected to a two-way radio. Essentially, it was the first form of telephone patch, although it was very simple and did not provide the automation that would later be expected from phone patches. A typical use-case for the Carterfone was to allow a dispatcher to connect someone in the field (using a mobile radio) to someone by telephone, with the dispatcher doing all of the dialing and supervision of the call.

The Carterfone was a long way from the wireless telephony systems we use today, but it is a common ancestor to most of them. It, and several other early telephone radio patch systems, introduced the concept that telephones could be divorced from their wires. Of course this lead to the development of radiotelephony, cellular phones, etc, but great distances weren't required for the radiotelephone to be useful.

Well into the '90s it was common to see people walking around their homes trailing 50' of telephone wire. A great deal of couplers and long cables were available for the purpose, and it either replaced or complemented (depending on budget) the also common practice of providing a telephone jack in each room. Wouldn't it be easier to avoid the need for in-wall, under-carpet, along-baseboard, and trip-hazard wiring entirely by using some sort of local, low-power radiotelephone?

I am, of course, describing the cordless phone, and early cordless phones were not much more complex than low-power two-way radios. There is one primary way in which a telephone is different from a radio: telephones are full-duplex, while "radio" is generally taken to refer to a half-duplex system in which it is necessary to use a push-to-talk or other control to switch to transmit.

Nowadays we tend to take full-duplex communications somewhat for granted, because it is reasonably easy to simulate it through packetization. In the '80s, though, when cordless phones became popular, packetized digital voice technology was still some ways from being sufficiently small and cheap to put in a consumer phone. Instead, full-duplex communication required that the handset and base station both transmit and receive simultaneously.

So, a cordless handset contained two radios, a transmitter and a receiver, and the base station contained two radios as well. There is a basic problem with operating two radios like this: the receive radio will typically be overwhelmed by the signal emitted by the transmit radio, and so unable to receive anything. There are various ways to solve this problem, but it becomes far easier if the simultaneous transmit and receive are at very different frequencies. For this reason, early cordless phone systems made use of pairs.

A typical design was this: the base station transmitted to the handset at around 1.7MHz, and the handset transmitted back to the base station at around 27MHz. The use of two different bands made it relatively easy for each receiver to filter out the signal from the nearby transmitter. Of course, the split-system between two bands can now result in confusion as it's not always clear what a "27MHz phone" for example even means.

Signaling was extremely simple, generally constrained to something like the phone emitting one fixed tone to indicate that the base should go off-hook, and another fixed tone to indicate it should go on-hook. Since DTMF was generated on the handset, no other signaling was required. This allowed the implementation to be almost entirely analog.

Actual modulation was FM, and on early cordless phones channel selection was manual with only a small number of discrete channels available. This meant that interference and crosstalk between different cordless phones was a common problem, one worsened by cordless phones sharing frequency allocations with some devices like baby monitors. Security was a very real problem, people did indeed listen in on other people's cordless phone calls by repurposing consumer devices like baby monitors or using wide-band receive radios.

Later cordless phones continued to use this basic scheme, although a 47Mhz band was added into the mix. The use of the higher frequency bands had the major benefit of making the antennas smaller; 1.7MHz phones had required a telescopic whip antenna while 27MHz/49MHz phones could generally make do with a "rubber ducky" antenna more typical of cordless phones today.

More interestingly, though, these later phones in the VHF low-band were capable of quite a few more channels and so introduced automatic channel selection. The need to implement link negotiation lead naturally to a more sophisticated signaling system between the handset and the base. Digital signaling allowed the base and handset to exchange commands, first enabling the "find handset" button on the base and later allowing the handset to control an answering machine integrated into the base.

The introduction of 900MHz phones (900MHz is a common ISM band used by a variety of devices) occurred somewhat in a transitional period, as there are both analog and digital phones made for 900MHz with various combinations of signaling and security features. Digital encoding and the use of spread spectrum tended to improve audio quality but also security, because even if there was no encryption decoding required a specialized device... and spread spectrum is itself a form of security if the sequence is determined in a secure fashion. Digital cordless phones largely eliminated eavesdropping except by particularly determined opponents, but generally only did so by raising the attack cost (requiring a decoder) rather than by employing strong security.

The 900MHz band is crowded with devices, as are 2.4GHz and 5.8 GHz where various late-'90s and early-'00s digital cordless phones operated. This often translated into disappointing range and reliability, and moreover there was a serious lack of standardization. Standardization tends to be less important for cordless phones because the base and handsets are sold together to the extend that consumers have no real expectation of them being interchangeable (technically they often are but it is difficult to determine between which devices). A bigger issue was a lack of consumer understanding of the different features that cordless phones carried. Was any given phone secure (in that it employed some type of encryption)? Was it going to be more or less subject to interference from the microwave oven? What about range?

All of these questions would be best addressed by the industry concentrating on a standard cordless phone implementation, and the allocation of a dedicated band for these devices would significantly reduce interference problems. The confluence of these two interests lead to a major standards effort in the early '00s that culminated in the adoption of a European standard which had been the norm in Europe since the '90s: DECT.

DECT is a very interesting beast. While DECT is now strongly associated with consumer cordless phones, it was always intended for much more ambitious use-cases. DECT could serve as the entire wireless plane for a corporate PBX system, for example, using centralized base stations (ceiling mount perhaps) to set up calls and signaling between a variety of handsets carried by employees [1]. DECT was even contemplated as a cellular telephony standard, with urban-area base stations managing large numbers of subscriber handsets.

In practice, though, DECT has a much more modest role in the US. First, there is a matter of naming. DECT in the US is referred to as DECT 6.0, which has created a false impression that it is either version 6 or operates at 6.0 GHz. In fact, DECT 6.0 operates in a 1.8GHz band allocated for that purpose and the name is just marketing fluff because 6 is a bigger number than the 5.8GHz cordless phones that were on the market at the time.

DECT makes use of frequency-hopping techniques as well as digital encoding that allow for active mitigation of interference based on time-division multiplexing. The takeaway is that, generally speaking, DECT phones will not interfere with other DECT phones. This addressed the biggest performance problems seen in congested areas.

DECT is, of course, packetized, and took many tips from the simultaneous work on ISDN in Europe. The DECT network protocol, LAPC, is based on the ISDN data link layer. Both are based on HDLC, an ISO network protocol that was derived from IBM's SNA. So, in a vague historical sense, modern cordless phones speak the same language as late '70s big iron, but over a wireless medium.

LAPC is a fairly complete network protocol, even from a modern perspective, and provides both connection-oriented and connectionless communications. Like most network protocols from the telecom industry, DECT supports defined-bandwidth connections by means of allocating "slots" in the network scheduling.

On top of LAPC a variety of functionality has been implemented, but most importantly basic call control (supervision) functionality and set up of real-time media channels using various codecs. Common codecs are ADPCM and u-law PCM, which both provide superior call quality to the cellular network (when HD voice does not succeed).

Because of DECT's greater ambitions, there is also a management protocol defined which allows handsets to register with base stations and exchange subscriber information. This allows cellular-like behavior that supports environments where there are multiple base stations with handsets roaming between them.

DECT supports authentication and encryption, but implementation is very inconsistent. The standard authentication and encryption protocol until around a decade ago was one with known weaknesses. As a practical matter, the use of FSS and TDMA in DECT makes active attacks difficult, and so DECT "exploits" do not seem to have ever been particularly common in the wild... but it certainly is possible to intercept DECT traffic, which lead to a change in standards to 128-bit AES encryption with improved key negotiation. Unfortunately it's not always easy to tell if devices make use of the newer encryption capability (or any at all), so security issues remain in practical DECT systems.

That's a lot about what DECT actually does, but what about the weird things it could do and usually doesn't? Those are my favorite kinds of things.

Protocols have been defined to run IP on top of DECT. IP-over-DECT was actually very competitive with 801.11 WiFi---it was slow (0.5mbps) but comparatively very reliable. A particular strong point for DECT was its origin as a possible cellular standard: DECT has always handled roaming between base stations very well, something that multi-AP WiFi systems struggle with in practice to this day. This made DECT a particularly compelling option for data networking in large, industrial environments. DECT IP networking was integrated into some industrial hand-held PC systems but was never common, despite efforts to commercialize a very WiFi-like DECT system under the name Net3. Another DECT computer networking initiative ran under the name PADcard and seems to have been launched on a few consumer products, but fizzled out very quickly.

What about DECT as a public cellular telephony standard? This doesn't seem to have really materialized anywhere. DECT had success in large-area applications like mines, but these were all still private corporate systems. DECT development for large systems ran pretty simultaneously with the development of GSM, which quickly gained more traction in DECT's European stronghold.

Despite DECT's failure to achieve its full potential, it has brought a surprising level of sophistication to the humble cordless phone. Modern cordless phones are almost exclusively DECT and take advantage of DECT's capabilities to offer multiple handsets per base station, intercom calling between handsets (often both dialed and "page" or broadcast), and a solid-state answering machine integrated into the base station and controllable from handsets. All cool features that no one uses, because now we all have cellphones.

[1] This use-case has obtained some success in the US in retail environments. Pacific Northwest retailer Fred Meyer's, for example, at least prior to the Kroger acquisition, armed each staff member with a DECT handset and earpiece at most stores. The advantages of this type of setup are clear: DECT handsets can be similarly priced to two-way radios but allow full-duplex communication and a "hybrid" model of radio vs. telephony behavior, by either selecting an intercom channel or dialing a number to reach a specific person. DECT in retail is likely giving way to IP-based solutions like Theatro (in use at some Walgreens locations), but a great many retailers (most Wal-Marts, for example) still use basic two-way radios on MURS or color dot channels. PBX DECT systems are still available though, and I remain tempted to buy the DECT gateway for the '90s digital PBX that runs in my office closet. More in the modern era, because DECT is better established than WiFi for telephony applications there are a lot of "Cordless IP phones" that handle all the IP in the base station and use DECT to reach the cordless phones. These are basically just IP evolutions of the older approach of a DECT module connected to analog accessory ports or a dedicated board in the PBX.

A special bonus addendum for the Hacker News crowd: After I wrote this, I somehow ran into the Japanese Personal Handy-Phone System. It's a moderately successful (for a time) cellular service using a technology that was very similar to DECT. Despite the Wikipedia article sort of making it sound like it, PHS does not seem to have actually been based on DECT in any way. It looks like a case of parallel evolution at the least.

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>>> 2021-09-20 iMessage for Business

Given the sources of most of my readers, some of you may have seen this article about A/UX, Apple's failed earlier effort towards delivering an Apple user experience on a POSIX operating system. A/UX was driven primarily by demands for a "serious workstation," which was a difficult category to obtain at any kind of reasonable price in the 1980s. It is also an example of Apple putting a concerted effort into attracting large enterprise customers (e.g. universities), something that is not exactly part of the Apple brand identity today.

I wanted t, expand on A/UX by discussing some of Apple's other efforts to make serious inroads into the world of Big Business. In the 2000s and 2010s, Apple was frequently perceived as focusing on consumers and small organizations rather than large organizations. This was perhaps a result of Apple's particular nexus to the personal computing ethos; Apple believed that computers should be affordable and easy to use rather than massively integrated.

This doesn't seem to have been a choice made by intention, though: through the '90s Apple made many efforts to build a platform which would be attractive to large enterprises. Many major events in the company's history are related to these attempts, and they're formative to some aspects of Apple's modern products... but they were never really successful. There's a reason that our usual go-to for an integrated network computing environment is the much maligned Microsoft Active Directory, and not the even more maligned Apple Workgroup Manager.

Indeed, somewhere around 2010 Apple seems to have lost interest in enterprise environments entirely, and has been slowly retiring their products aimed at that type of customer. On the one hand, Apple probably claims that their iCloud offerings replace some of the functionality of their on-prem network products. On the other hand, I think a far larger factor is that they just never sold well, and Apple made a decision to cut their losses.

But that's starting at the end. Let's take a step back to the '80s, during the project that would become A/UX, to Apple's first major step into the world of networking.

I have previously mentioned the topic of network operating systems, or NOS. NOS can be tricky because, at different points in time, the term referred to two different things. During the '80s, an NOS was an operating system that was intended specifically to be used with a network. Keep in mind that at the time many operating systems had no support for networking at all, so NOS were for a while an exciting new category. NOS were expected to supported file sharing, printer sharing, messaging, and other features we now take for granted [1].

Apple never released an NOS as such (stories about the 'i' in iMac standing for 'internet' aside), but they were not ignoring the increasing development of microcomputer networks. The Apple Lisa appears to have been the first Apple product to gain network support, although only in the most technical sense. Often referred to as AppleNet [2], this early Apple effort towards networking was directly based on Xerox XNS (which will be familiar to long-time readers, as many early PC network protocols were derived from XNS). AppleNet ran at 1mbps using coaxial cables, and failed to gain any meaningful traction. While Apple announced Lisa-based AppleNet file and print servers, I'm not sure whether they ever actually shipped a server product at all (at least the file server was vaporware).

Apple's second swing at networking took the form of AppleBus. AppleBus was fundamentally just a software expansion of the Macintosh serial controller into an RS-422 like multi-drop serial network scheme. Because AppleBus also served as the general-purpose peripheral interconnect for many Apple systems into the '90s, it could be seen as an unusually sophisticated interconnect in terms of its flexibility. On the other hand, consumers could find it confusing that a disk drive and the network could be plugged into the same port, a confusion that in my experience lasted into the '00s among some devoted Macintosh users.

Nonetheless, the idea that inter-computer networking was simply an evolution of the peripheral bus was a progressive one that would continue to appear in Apple-influenced interconnects like Firewire and to a lesser extent Thunderbolt, although it would basically never be successful. In a different world, the new iMac purchaser that thought USB and Ethernet were the same thing might have been correct. Like the proverbial mad prophet, they have a rare insight into a better way.

For all of my optimism about AppleBus, it was barely more successful than AppleNet. AppleBus, by that name, came and went with barely any actual computer inter-networking applications. AppleBus was short-lived to the extent that it is barely worth mentioning, except for the interesting fact that AppleBus development as a computer network was heavily motivated by the LaserWriter. One of the first laser printers on the market, the LaserWriter was formidably expensive. AppleBus was the obvious choice of interface since it was well supported by the Macintosh, but the ability to share the LaserWriter between multiple machines seemed a business imperative to sell them. Ipso facto, the peripheral interconnect had to become a network interconnect.

In 1985, Apple rebranded the AppleBus effort to AppleTalk, which will likely be familiar to many readers. Although AppleTalk was a fairly complete rebrand and significantly more successful than AppleBus, it was technically not much different. The main component of AppleTalk outside of the built-in serial controller was an external adapter box which performed some simple level conversions to allow for a longer range. Unfortunately this simple design lead to limitations, the major one being a speed of just 230kbps which was decidedly slow even for the time.

As early as the initial development of AppleBus, token ring seem to be the leading direction for microcomputer networking and, indeed, Apple had been involved in discussions with IBM over use of token ring for the Macintosh. Unfortunately for IBM, their delays in having token ring ready for market lead somewhat directly to Apple's shift towards ethernet. Since token ring was not an option for the LaserWriter, Apple pushed forward with serial AppleBus for several years, by which point it became clear that Ethernet would be the victor. In 1987, AppleTalk shifted to Ethernet as a long-range physical layer (called EtherTalk) and the formerly-AppleBus serial physical layer was rebranded as LocalTalk.

AppleTalk was a massive success. For fear of turning this entire post into a long discussion of Apple networking history, I will now omit most of the fate of AppleTalk, but LocalTalk remained in use to the late '90s even as IP over Ethernet became the norm. AppleTalk was for a time the most widely deployed microcomputer networking protocol, and a third-party accessory ecosystem flourished that included alternate physical media, protocol converters, switches, etc. Of course, this all inevitably fell out of use for inter-networking as IP proliferated.

The summation of this history is that Apple has offered networking for their computers from the mid-'80s to the present. But what of network applications?

One of the great selling points of AppleTalk was its low-setup, auto-configuring nature. As AppleTalk rose to prominence, Apple broke from conventional NOS vendors by keeping to more of a peer-to-peer logical architecture where basic services like file sharing could be hosted by any Macintosh. This seems to have been an early manifestation of Apple's dominance in zero-configuration network protocols, which is perhaps reduced today by their heavy reliance on iCloud but is still evident in the form of Bonjour.

This is not at all to say that Apple did not introduce a server product, although Apple was slow to the server market, and the first AppleTalk file and print servers were third-party. In 1987, Apple released their own effort: AppleShare. AppleShare started out as a file server (using the AFP protocol that Apple designed for this purpose), but it gained print and mail support, which put it roughly on par with the NOS landscape at the time.

But what of directory services? Apple lagged on development of their own directory system, but had inherited NetInfo from their acquisition of NeXT. I've had a hard time finding much about NetInfo, and apparently the one fact I used to state here was wrong. It seems to have been used in universties but not especially widely.

The story of Apple directory services becomes clearer with Apple Open Directory, an LDAP-based solution introduced in 2002. Open Directory is largely similar to competitors like MS AD and Red Hat IDM. As a result of the move to open standards, it has occasionally, with certain versions of the relevant operating systems, been possible to use OS X Server as an Active Directory domain controller or join OS X to an Active Directory domain. I have previously worked with OS X machines joined to an Oracle directory, which was fine except for all the Oracle parts and the one time that Apple introduced a bug where OS X didn't check user's passwords any more. Haha, wacky hijinx!

As I mentioned, Apple has been losing interest in the enterprise market. The primary tool for management of Apple directory environments, Workgroup Manager, was retired around 2016 and has not really received a replacement. It is still possible to use Open Directory, but no longer feels like a path that Apple intends to support.

That of course brings us naturally to the entire topic of OS X Server and the XServe hardware. Much like Windows Server, for many years OS X Server was a variant of the operating system that included a variety of pre-configured network services ranging from Open Directory to Apache. As of now, OS X Server is no longer a standalone product and is instead offered as a set of apps to be installed on OS X. This comes along with the end of the XServe hardware in 2011, meaning that it is no longer possible to obtain a rack-mount system which legitimately runs OS X.

The industry norm now appears to be affixing multiple Mac Minis to a 19" sheet of plywood with plumber's tape. And that, right there, is a summary of Apple's place in the enterprise market. In actuality, Apple has come around somewhat and now offers an official rack ear kit for the Mac Pro. That said, it's 5U for specifications that other vendors fit in 1U (save the GPU which is not of interest to conventional NOS applications), and lacks conventional server usability features like IPMI or even a cable arm. In general, Apple continues to be uninterested in the server market, even to support their own workstations, and really offers the Mac Pro rack option only for media professionals who have one of the desks with 19" racks integrated [3].

I originally set out to write this post about Apple's partnership with IBM, which has delightful parallels to Microsoft's near simultaneous partnership with IBM as both were attempting to develop a new operating system for the business workstation market. I find great irony and amusement in the fact that both Microsoft, which positioned itself as Not IBM, and Apple, which positioned itself as even more Not IBM, both spent an appreciable portion of their corporate histories desperately attempting to court IBM. While neither was successful, Apple was even less successful than Microsoft. Let's take a look at that next time---although I am about to head out on a vacation and might either not write for a while or end up writing something strange related to said trip.

[1] Amusingly, despite many efforts by vendors, local file and printer sharing can still be a huge pain if there are heterogeneous product families involved. The more things change, the more they stay the same, which is to say that we are somehow still fighting with SMB and NFS.

[2] AppleBus, AppleNet, and AppleTalk all refer to somewhat different things, but for simplicity I am calling it AppleNet until the AppleTalk name was introduced. This is really just for convenience and because it matches the terminology I see other modern sources using. The relationship between AppleBus and AppleNet was as confusing at the time as it is now, and it is common for '80s articles to confuse and intermix the two.

[3] I would absolutely be using one of these if I had room for one.

Update: A reader sent me a correction. I had said that NetInfo functioned on AppleTalk, but it did not, it was IP only. The reader also raised questions about the capability of MacOS server to function as an Active Directory DC. Apple does state this in the sell sheet for OS X Server 10.4, but I agree that there are reasons to question how extensive that capability was, and it seems to have disappeared shortly thereafter. I'm going to do some more research into that aspect.

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>>> 2021-09-08 W X Y Z

Let's return, for a while, to the green-ish-sometimes pastures of GUI systems. To get to one of my favorite parts of the story, delivery of GUIs to terminals over the network, a natural starting point is to discuss an arcane, ancient GUI system that came out of academia and became rather influential.

I am referring of course to the successor of W on V: X.

Volumes could be written about X, and indeed they have. So I'm not intending to present anything like a thorough history of X, but I do want to address some interesting aspects of X's design and some interesting applications. Before we talk about X history, though, it might be useful to understand the broader landscape of GUI systems on UNIX-like operating systems, though, because so far we've talked about the DOS/VMS sort of family instead and there are some significant differences.

Operating systems can be broadly categorized as single-user and multi-user. Today, single-user operating systems are mostly associated only with embedded and other very lightweight devices [1]. Back in the 1980s, though, this divide was much more important. Multi-user operating systems were associated with "big iron," machines that were so expensive that you would need to share them for budget reasons. Most personal computers were not expected to handle multiple users, over the network or otherwise, and so the operating systems had no features to support this (no concept of user process contexts, permissions, etc).

Of course, you can likely imagine that the latter situation, single-user operating systems, made the development of GUI software appreciably easier. It wasn't even so much about the number of users, but rather about where they were. Single-user operating systems usually only supported someone working right at the console, and so applications could write directly to the graphics hardware. A windowing system, at the most basic, only really needed to concern itself with getting applications to write to the correct section of the frame buffer.

On a multi-user system, on the other hand, there were multiple terminals connected by some method or other that almost certainly did not allow for direct memory access to the graphics hardware. Further, the system needed to manage what applications belonged on which graphics devices, as well as the basic issue of windowing. This required a more complicated design. In particular, server-client systems were extremely in at the time because they had the same general shape as the computer-terminal architecture of the system. This made them easier to reason about and implement.

So, graphics systems written for multi-user systems were often, but not always, server-client. X is no different: the basic architecture of X is that of a server (running within the user context generally) that has access to a graphics device and input devices (that it knows how to use), and one or more clients that want to display graphics. The clients, which are the applications the user is using, tell the server what they want to display. In turn, the server tells the clients what input they have received. The clients never interact directly with the display or input hardware, which allows X to manage multiple access and to provide abstraction.

While X was neither the first graphics system for multi-user operating systems, nor the first server-client graphics system, it rapidly spread between academic institutions and so became a de facto standard fairly quickly [2]. X's dominance lasts nearly to this day, Wayland has only recently begun to exceed it in popularity. Wayland is based on essentially the same architecture.

X has a number of interesting properties and eccentricities. One of the first interesting things many people discover about X is that its client-server nature actually means something in practice: it is possible for clients to connect to an X server running on a different machine via network sockets. Combined with SSH's ability to tunnel arbitrary network traffic, this means that nearly all Linux systems have a basic "remote application" (and even full remote desktop) capability built in. Everyone is very excited when they first learn this fact, until they give it a try and discover that the X protocol is so hopelessly inefficient and modern applications so complex that X is utterly unusable for most applications over most internet connections.

This gets at the first major criticism of X: the protocol that clients use to describe their output to X is very low level. Besides making the X protocol fairly inefficient for conveying typical "buttons and forms" graphics, X's lack of higher-level constructs is a major contributor to the inconsistent look-and-feel and interface of typical Linux systems. A lot of basic functionality that feels cross-cutting, like copy-and-paste, is basically considered a client-side problem (and you can probably see how this leads to the situation where Linux systems commonly have two or three distinct copy and paste buffers).

But, to be fair, X never aimed to be a desktop environment, and that type of functionality was always assumed to occur at a higher level.

One of the earliest prominent pseudo-standards built on top of X was Motif, which was used as a basis for the pseudo-standard Common Desktop Environment presented by many popular UNIX machines. Motif was designed in the late '80s and shows it, but it was popular and both laid groundwork and matched the existing designs (Apple Lisa etc) to an extent that a modern user wouldn't have much trouble using a Motif system.

Motif could have remained a common standard into the modern era, and we can imagine a scenario where Linux had a more consistent look-and-feel because Motif rose to the same level of universality as X. But it didn't. There are a few reasons, but probably the biggest is that Motif was proprietary and not released as open source until well after it had fallen out of popularity. No one outside of the big UNIX vendors wanted to pay the license fees.

There were several other popular GUI toolkits built on top of X in the early days, but I won't spend time discussing them for the same reason I don't care to talk about Gnome and KDE in this post. But rest assured that there is a complex and often frustrating history of different projects coming and going, with few efforts standing the test of time.

Instead of going on about that, I want to dig a bit more into some of the less discussed implications of X's client-server nature. The client and server could exist on different machines, and because of the hardware-independence of the X protocol could also be running different operating systems, architectures, etc. This gave X a rather interesting property: you could use one computer to "look at" X software running on another computer almost regardless of what the two computers were running.

In effect, this provided one of the first forms of remote application delivery. Much like textual terminals had allowed the user to be physically removed from the computer, X allowed the machine that rendered the application and collected input to be physically removed from the actual computational resources running the software. In effect, it created a new kind of terminal: a "dumb" machine that did nothing but run an X server, with all applications running on another machine.

The terminology around this kind of thing can be confusing and is not well agreed upon, but most of the time the term "thin terminal" refers to exactly this: a machine that handles the basic mechanics of graphical output and user input but does not run any application software.

Because of the relatively high complexity of handling graphics outputs, thin terminals tend to be substantially similar to proper "computers," but have very limited local storage (usually only enough for configuration) and local processing and memory capacity that are just enough to handle the display task. They're like really low-end computers, basically, that just run the display server part of the system.

In a way that's not really very interesting, as it's conceptually very similar to the block terminals used by IBM and other mainframes. In practice, though, this GUI foray into terminals took on some very odd forms over the early history of personal computers. The terminal was decidedly obsolete, but was also the hot new thing.

Take, for example, DESQview. DESQview was a text-mode GUI for DOS that I believe I have mentioned before. After DESQview, the same developer, Quarterdeck, released DESQview/X. DESQview/X was just one of several X servers that ran on DOS. X was in many ways a poor fit for DOS, given DOS's single task nature and X's close association with larger machines running more capable operating systems, but it was really motivated by cost-savings. DOS was cheap, and running an X server on DOS allowed you to both more easily port applications written for big expensive computers, and to use a DOS machine as an X server for an application running on another machine. The cheap DOS PC became effectively a hybrid thin terminal that could both run DOS software and "connect to" software running on a more expensive system.

One way to take advantage of this functionality was reduced-cost workstations. For example, at one time years ago the middle school I attended briefly had a computer lab which consisted of workstations (passed down from another better funded middle school) with their disks removed. The machines booted via PXE into a minimal Linux environment. The user was presented with a specialized display manager that connected to a central server over the network to start a desktop environment.

The goal of this scheme was reduced cost. In practice, the system was dog slow [3] and the unfamiliarity of KDE, StarOffice, and the other common applications on the SuSE server was a major barrier to adoption. Like most K-12 schools at the time the middle school was already firmly in the grasp of Apple anyway.

Another interesting aspect of X is the way it relates to the user model. I will constrain myself here to modern Linux systems, because this situation has varied over time. What user does X run as?

On a typical Linux distribution (that still uses X), the init system starts a desktop manager as root and then launches an X server to use, still with root privileges. The terminology for desktop things can get confusing, but a desktop manager is responsible for handling logins and setting up graphical user sessions. It's now common for the display manager to actually run as its own user to contain its capabilities (by switching users after start), so it may use setuid in order to start the X server with root capabilities.

Once a user authenticates to the display manager, a common display manager behavior is to launch the user's desktop environment as the user and then hand it the information necessary to connect to the existing X instance. X runs as root the whole time.

It is completely possible to run X as a non-privileged user. The problem is that X handles all of the hardware abstraction, so it needs direct write access to hardware. For numerous reasons this is typically constrained to root.

You can imagine that the security concerns related to running X as root are significant. There is work to change this situation, such as the kernel mode setting feature, but of course there is a substantial problem of inertia: since X has always run with root privileges, a great many things assume that X has them, so there are a lot of little problems that need solving and this usage is not yet well supported.

This puts X in a pretty weird situation. It is a system service because it needs to interact directly with scarce hardware, but it's also a user application because it is tied to one user session (ultimately by means of password authentication, the so-called X cookie). This is an inherent tension that arises from the nature of graphics cards as devices that expect very low-level interaction. Unfortunately, continuously increasing performance requirements for graphical software make it very difficult to change this situation... as is, many applications use something like mesa to actually bypass the X server and talk directly to the graphics hardware instead.

I am avoiding talking about the landscape of remote applications on Windows, because that's a topic that deserves its own post. And of course X is a fertile field for technology stores, and I haven't even gotten into the odd politics of Linux's multiple historic X implementations.

[1] Windows looks and feels like a single-user operating system to the extent that I sometimes have to point out to people that NT windows releases are fully multi-user. In fact, in some ways Windows NT is "more multi-user" than Linux, since it was developed later on and the multi-user concept is more thoroughly integrated into the product. Eventually I will probably write about some impacts of these differences, but the most obvious is screen locking: on Linux, the screen is "locked" by covering it with a window that won't go away. On Windows, the screen is "locked" by detaching the user session from the local console. This is less prone to bypasses, which perennially appear in Linux screensaver implementations.

[2] The history of X, multi-user operating systems from which UNIX inherited, and network computing systems in general is closely tied to major projects at a small number of prominent American universities. These universities tended to be very ambitious in their efforts to provide a "unified environment" which lead to the development of what we might now call a "network environment," in the sense of shared resources across an institution. The fact that this whole concept came out of prominent university CS departments helps to explain why most of the major components are open source but hilariously complex and notoriously hard to support, which is why everyone today just pays for Microsoft Active Directory, including those universities.

[3] Given the project's small budget, I think the server was just under-spec'd to handle 30 sessions of Firefox at once. The irony is, of course, that as computers have sped up web browsers have as well, to the extent that running tens of user sessions of Firefox remains a formidable task today.

Note: several corrections made, mostly minor, thanks to HN users smcameron, yrro, segfaultbuser. One was a larger one: I find the startup process around X to be confusing (you hopefully see why), and indeed I described it wrong. The display manager starts first and is responsible for starting an X server to use, not the other way around (of course, when you use xinit to start X after login, it goes the way I originally said... I didn't even get into that).

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>>> 2021-08-26 a permanent solution

The strategic and tactical considerations surrounding nuclear weapons went through several major eras in a matter of a few decades. Today we view the threat of nuclear wear primarily through the "triad": the capability to deliver a nuclear attack from land, sea, and air. This would happen primarily through intercontinental ballistic missiles (ICBMs), so-called because they basically launch themselves to the lower end of space before strategically falling towards their targets (ballistic reentry). ICBMs are fast, taking about 30 minutes to arrive across the globe. The result is that we generally expect to have very little warning of a nuclear first trike.

The situation in the early Cold War was quite different. ICBMs, and long-range missiles in general, are complex and took some time to develop. From the end of World War II to roughly the late '60s, the primary method of delivery for nuclear weapons was expected to be by air: bombs, delivered by long-range bombers. The travel time from the Soviet Union would be hours, allowing significant warning and a real opportunity for air defense intervention.

The problem was this: we would have to know the bombers were coming.

Many people seem to assume that the United States has the capability to detect and track all aircraft flying in US airspace. The reality is quite a bit different. The problem of detecting and tracking aircraft is a surprisingly difficult one, and even today our capabilities are limited. Nonetheless, surveillance of airspace is considered a key element of "air sovereignty," or our ability to maintain military and civil control of our airspace.

Let's take a look at the history of the United States ability to monitor our airspace.

During the 1940s, it was becoming clear that airspace surveillance was an important problem. Although the United States did not then face attacks on the contiguous US (and never would), were the Axis forces to advance to the point of bombing missions on CONUS it would be critical to be able to detect the incoming aircraft. The military invested in a system for Aircraft Control and Warning, or AC&W. Progress was slow: long-range radar was primitive and expensive, and the construction of AC&W stations was not a high-level priority. By the end of the 1948, there were only a small number of AC&W stations, they were considered basically experimental, and the ability to integrate data coming from the several stations was very limited. Efforts to expand the air surveillance system routinely failed due to lack of funding.

The Lashup project, launched in '48, made up the first major effort to build an air surveillance system. As the name suggests, Lashup was only intended to be temporary, funded by the congress as a stopgap measure until a more complete system could be designed. Over the next two years, 44 radar stations were built focused around certain strategically important areas. Lashup provided nothing near nationwide coverage, but was expected to detect bombing runs directed towards the most important military targets. Lashup included three stations surrounding my own Albuquerque, due to the importance of the Sandia and Manzano Amy Bases and the Z Division of Los Alamos.

Lashup sites used sophisticated radar sets for the time, but perhaps the most important innovation of Lashup was the command and control infrastructure built around it. Lashup stations were connected to the air defense command by dedicated telephone lines, the air defense command was connected to the continental air command by another dedicated telephone line, and ultimately dedicated lines were connected all the way to the White House. This was the first system built to allow a prompt nuclear response by informing the commander in chief of an impending nuclear attack as quickly as possible.

If you've read any of my other material on the cold war, you might understand that this is the core of my fascination with cold war defense history: the threat of nuclear attack was, for the large part, the first thing to motivate the development of a nationwide rapid communications system. For the first half of the 20th century there simply wasn't a need to deliver a message from the west coast to the President in minutes, but in the second half of the 20th century there most definitely was.

The fear of a Soviet nuclear strike, and the resulting government funding, was perhaps the largest single motivator of progress in communications and computing technology from the 1940s to the 1980s. Most of the communications technology we now rely on was originally built to meet the threat of a first strike.

We see this clearly in the case of air defense radar. While Lashup nominally had the capability to deliver a prompt warning of nuclear attack, the entire process was rather manual and thus not very reliable. Fortunately, lashup was temporary, and just as construction of the Lashup sites was complete work started on its replacement: the Permanent System.

The Permanent System consisted of a large number of radar stations, ultimately over 100. More importantly, though, it consisted of a system of communications and coordination centers intended to quickly confirm and communicate a nuclear threat.

It will help in understanding this system to understand the strategic principal involved. The primary defense against a nuclear attack by bombers was a process called ground-controlled intercept, or GCI. The basic concept of GCI was that radar stations would provide up-to-date position and track information on inbound enemy aircraft, which would be used to vector interceptor aircraft directly towards the threat. The aid of ground equipment was critical to an effective response, as fighter aircraft of the time lacked sophisticated targeting radar and had no good way to search for bombers.

To this end, the Permanent System included Manual Air Defense Control Centers (ADCC) (the "manual" was used to differentiate from automatic centers in the later SAGE system). The ADCCs received information on radar targets from the individual radar sites via telephone, and plotted them with wet erase marker on clear plexiglass maps (perhaps the source of the clear whiteboard trope now ubiquitous in films) in order to correlate multiple tracks. They then reported these summarized formations and tracks to the Air Defense Command, at Ent AFB in Colorado, for use in directing interceptors.

The Permanent System was extended beyond CONUS, although Alaska continued to have a distinct air defense program. The biggest OCONUS extension of the Permanent System was into Canada, with the Pinetree Line (the first of the cross-Canadian early warning radar networks) roughly integrated into the Permanent System. Perhaps most interestingly, the Permanent System also saw an early effort at extension of early warning radar into the ocean. This took the form of the Texas Towers, a set of three awkward offshore radar stations that were later abandoned due to their poor durability against rough seas [1].

Technology was advancing extremely rapidly in the mid-20th century, and by the time the Permanent System reached nearly 200 radar stations it had also become nearly obsolete. For its vast scale, the capabilities of the Permanent System were decidedly limited: it could only detect large aircraft, it performed poorly at low altitudes (often requiring mitigation through "gap filler" stations), and interpretation and correlation of radar data was a manual process, costing precious minutes in the timeline of a nuclear reprisal.

Here in Albuquerque, Kirtland Air Force Base was host to the Kirtland Manual ADCC, activated in 1951. 13 radar stations around New Mexico, eastern Arizona, and western Texas reported to Kirtland AFB. Each of these 13 radar stations was itself a manned Air Force Station including housing and cantonment. The Continental Divide Air Force Station, for example, consisted of some fifty people in remote McKinley County. The station included amenities like a library and gym, housing and a trailer park, and two radars: an early warning radar and a height-finding radar. Finally, a ground-air transmit-receive (GATR) radio site provided a route for communications with interceptors.

Continental Divide AFS was deactivated in 1960. You can still see the remains today, although there is little left other than roads and some foundations.

Like Continental Divide AFS, the Permanent System as a whole failed to make it even a decade. In 1960, it was as obsolete as Lashup, having been replaced not only by improved radar equipment but, more importantly, by a vastly improved communications and correlation system: the Semi-Automatic Ground Environment, or SAGE---by most measures, the first practical networked computer system.

We'll talk about SAGE later, but for now, check out a list of Permanent System sites. There might be one in your area. Pay it a visit some time; in many ways it's the beginning of the computer revolution: a manual data collection network obsoleted in just a few years by the development of the first nationwide computer network.

[1] The Texas Towers were connected to shore via troposcatter radio links, one of my favorite communications technologies and something that will surely get a full post in the future.

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>>> 2021-08-16 on voting

The use of electronics to administer elections has been controversial for some time. Since the "hanging chads" of the 2000 election, there's been some degree of public awareness of the use of technology for voting and its possible impacts on the accuracy and integrity of the election. The exact nature of the controversy has been through several generations, though, reflecting both changes in election technology and changes in the political climate.

Voting is a topic of great interest to me. The administration of elections is critical to a functioning democracy, and raises a variety of interesting security and practical challenges. In particular, the introduction of automation into elections presents great opportunity for cost savings and faster reporting, but also a greater risk of intentional and accidental interference in the voting process. Back when I was in school, I focused some of my research on election administration. Today, I continue to research the topic, and have added the practical experience of being a poll worker in two states and for many elections [1].

Given my general propensity to have opinions, it will come as no surprise that this has all left me with strong opinions on the role of computer technology in election administration. But before we get to any of that, I want to talk a bit about the facts of the matter.

The thing that most frustrates me about controversies surrounding electronic voting is the generally very poor public understanding of what electronic voting is. If you follow me on Twitter, you may have seen a thread about this recently, and it's a ramble I go on often. There is a great deal of public misconception about the past, present, and future role of electronics in elections. These misunderstandings constantly taint debate about electronic voting.

In an on-and-off series of posts, I plan to provide an objective technical discussion of election technology, "electronic voting," and security concerns surrounding both. I will largely not be addressing recent "stolen election" conspiracy theories for a variety of reasons, but will undoubtedly touch on them occasionally. At the very least, because I can never turn down an opportunity to talk about J. Hutton Pulitzer, an amazing wacko who has a delightful way of appearing with a huge splash, making a fool of himself, and then disappearing... to pop up again a couple years later in a completely different context.

I will restate that my goal here is to remain largely apolitical (mocking J. Hutton Pulitzer aside), and as a result I will not necessarily respond to any given election fraud or interference claim directly. But I do think anyone interested in or concerned by these theories will find the technical context that I can provide very useful.

Who runs elections?

One of the odd things about the US, compared to other countries, is the general architecture of election administration. In the US, elections are mostly administered by the county clerk, and the election process is defined by state law. Federal law imposes only minimal requirements on election administration, leaving plenty of room for variation between states.

Although election administration is directly performed by the county clerk, for state-level elections (which is basically all the big ones) the secretary of state performs many functions. It's also typical for the secretary of state to provide a great deal of support and policy for the county clerks. So, while county clerks run elections, it's common for them to do so using equipment, software, and methods provided by the state. It's ultimately the responsibility of states to pay for elections, which is probably the greatest single problem with US election integrity, because states are poor.

While it seems a little odd that, say, a presidential election is run by the county clerks, it can also be odd the other way. Entities like municipalities, school districts, higher education districts, flood control districts, all kinds of sub-county entities may also have elected offices and the authority to issue bond and tax measures. These are typically (but not always) administered by the county or counties as well, usually on a contract basis.

What is electronic voting?

Debate around electronic voting tends to focus purely around "voting machines," a broad category that I will define more later. The reality is that voting machines are only a small portion of the overall election apparatus, and are not always the most important part. So before I get into the world of election security theory, I want to talk a bit about the moving parts of an election, and where technology is used.

The general timeline of an election looks like this:

To meet these ends, election administrators use various different systems. There's a great deal of mix-and-match between these systems, many vendors offer a "complete solution" but it's still common for election administrators to use products from multiple vendors.

Each of these systems poses various integrity and security concerns. However, election systems can be roughly divided into two categories: tabulating systems and non-tabulating systems.

Tabulating systems, such as tabulators and direct recording electronic (DRE) machines, directly count votes which they record in various formats for later totalization. Tabulating systems tend to be the highest-risk element of an election because they are the key point at which the outcome of an election could be altered by, for example, changing votes.

Non-tabulating systems perform support functions such as design of ballots, registration of voters, and totalizing of tabulated votes. These systems tend to be less security critical because they produce artifacts which are relatively easy to audit after the fact. For example, a fault in ballot design will be fairly obvious and easy to check for. Similarly, totalizing of tabulated votes can fairly easily be repeated using the original output of the tabulators (and tabulators typically output their results in multiple independent formats to facilitate this verification).

This is not to say that tabulating systems are not subject to audit. When a paper form of the voter's selections exists (a ballot or paper audit trail), it's possible to manually recount the paper form in order to verify the correctness of the tabulation. However, this is a much more labor intensive and costly operation than auditing the results of other systems. In the case of DRE systems with no paper audit trail, an audit may not be possible.

We will be discussing all of these systems in more detail in the future.

Why electronic voting

There is one fundamental question about electronic voting that I want to address up front, in this overview. That is: why electronic voting at all?

Most of the fervor around electronic voting has centered around direct recording electronic (DRE) machines that lack a voter verifiable paper audit trail (VVPAT) [2]. These machines, typically touchscreens, record the voter's choices directly to digital media without producing any paper form. As a result, there is typically no acceptable way to audit the tabulation performed by these machines. Software bugs or malicious tampering could result in an incorrect tabulation that could not be readily detected or corrected after the fact.

It's fairly universally accepted that these machines are a bad idea. Basically no one approves of them at this point. So why are they so common?

Well, this is the first major misconception about the nature of electronic voting: DRE machines with no VVPAT are rare. Only ten states still use them, and most of those states only use them in some polling places. Year by year, the number of DRE w/o VVPAT machines in use decreases as they are generally being replaced with other solutions.

The reason is simple: they are extremely unpopular.

So why did anyone ever have DRE machines? And why do we use machines at all instead of paper ballots placed in a simple box?

The answer is the Help America Vote Act of 2002 (HAVA). The HAVA was written with a primary goal of addressing the significant problems that occurred with older mechanical voting systems in the 2000 election, including accessibility problems. Accessibility is its biggest enduring impact: the HAVA requires that all elections offer a voting mechanism which is accessible to individuals with various disabilities including impaired or no vision.

In 2002, there were few options that met this requirement.

The other key ingredient is, as we discussed earlier, the nature of election administration in the US. Elections are not just administered but funded at the state and county level. State budgets for elections have typically been very slim, and suddenly, in 2002, most states suddenly faced a requirement that they replace their voting systems.

The result was that, in the years shortly after 2002, basically the entire United States replaced its voting systems on a shoestring budget. Many states were forced to go for the cheapest possible option. Because paper handling adds an appreciable amount of complexity, the cheapest option was to do it in software: "paperless," or non-auditable, DRE machines.

To the extent that DRE w/o VVPAT machines are still in use in 2021, we are still struggling with the legacy of the HAVA's good intentions combined with the US's decentralized and tiny budget for the fundamental administration of democracy.

We don't have non-auditable voting systems because someone likes them. We have them because they were all we could afford in 2003, and because we haven't since been able to afford to replace them.

Basically the entire electronic voting landscape revolves around this single issue: there is enormous pressure in the US to perform elections as cheaply as possible, while still meeting sometimes stringent but often lax standards. The driver on selection of election technology is almost never integrity, and seldom speed or efficiency. It is nearly always price.

In upcoming posts, I will be expanding on this with (at least!) the following topics:

[1] I highly recommend that anyone with an interest in election administration step up as a poll worker. You will learn more than you could imagine about the practical considerations around elections.

[2] We will talk more about VVPAT and how it compares to a paper ballot in the future.

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