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Was there some particular design theory or constraint that made a 36 bit word size attractive for early computers? As opposed to the various power-of-2 word sizes which seem to have won out?

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    Related question: retrocomputing.stackexchange.com/questions/1621/… Commented Jul 23, 2019 at 22:42
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    Back when people were starting to expect 32-bit integers, your Lisp interpreter could store 32-bits worth of immediate data and a 4-bit type code in a single machine word. (Don't ask me how I know!) Commented Jul 24, 2019 at 1:37
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    There is a specific case of this problem: current 64-bit x86 CPUs have a 32-bit mode, but with 36-bit address lines. That is called PAE (Physical Address Extension). It is very useful - you can combine the smaller RAM requirement of 32-bit processes, with the 64GB maximal physical RAM of newer, hard-core machines. The price is that no induvidual process will be able to see more than 4GB.
    – peterh
    Commented Jul 26, 2019 at 19:21
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    IIRC, PAE well pre-dates x86-64 (circa 2000/Pentium-III era?) Commented Apr 19, 2021 at 10:39
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    Because 64 bits would have been a stretch.
    – dave
    Commented Apr 19, 2021 at 12:27

9 Answers 9

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I'm going to address the power of 2 part of the question.

Keep in mind that before microprocessors, computers were assembled by hand. Increasing the number of bits in a computer was really a big deal. Each time you added one bit to the word size, you would need

  • more parts in the register file
  • more parts in the ALU
  • more wires in the buses
  • more cells in memory
  • more parts (relays, vacuum tubes, transistors, or small-scale ICs) to make all the above
  • more circuit boards
  • more time to assemble and solder (or wire-wrap) the parts
  • and more cost for the parts and labor of all of the above.

This wasn't just a one-time design cost. Every unit sold had these extra costs for each added bit. If there wasn't a good reason to add another bit, they didn't add it. And rounding up to the next power of 2 was not a good reason.

This wasn't just limited to processor word sizes. Drum memories were not powers of 2. EBCDIC was not a power of 2 (6 bits). ASCII was not a power of 2 (7 bits).


So why are powers of 2 dominant now?

  • IC transistors cost practically nothing compared to relays, vacuum tubes, or discrete transistors. You don't have to hire someone to solder them together. So there's little incentive to keep the part count low, and little penalty to round up the number of bits to a power of 2.
  • Automated chip design tools make it very easy to add more bits during chip design.
  • Doubling the width of registers can often make a new architecture compatible with the old architecture, either as source code or actual executables. There were many 18-bit systems, and some of these architectures went on to become 36-bit systems.
  • Intel created the first commercially-available microprocessor as a power of 2: the 4004 was 4 bits. Subsequent architectures doubled the register size, resulting in power-of-2 architectures: the 8008 was 8 bits, 8086 was 16 bits, and 80386 was 32 bits.
  • Competition causes different manufacturers to offer something similar to their competitors. There was a time when 18 bits was popular among several manufacturers. Then 36 bits were in vogue. Then 8-bit microprocessors. Followed by the age of 16-bit processors, then 32 bits, and 64 bits today.
  • Finally, powers of 2 seem "natural" or "elegant". We are suspicious of a platform that isn't so, even if it is perfectly valid. Would you like to buy this lovely 67-bit processor? No?
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    Actually, 36 bits was "in vogue" before 18 bits; 36 bit machines were common in the 1950s (IBM 700 series, UNIVAC 1103) but 18-bit machines didn't appear until 1960 or so (PDP-1), as far as I can tell.
    – cjs
    Commented Jul 24, 2019 at 13:36
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    @aCVn: Yet if I had offered a 128-bit processor, some people would rationalize a need for it. It can do cryptography. It can do vector arithmetic. And many would simply think I need it because it must be better. The point is that there is clearly a difference between how critical our thinking becomes. We want the power of 2 processor to be better, but we look for reasons to reject other word sizes.
    – DrSheldon
    Commented Jul 24, 2019 at 14:29
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    Yes, "8008 was 8 bits, 8086 was 16 bits" -- but just look at all the octal-oriented structure in the instruction sets! Three bits was just right to specify one of eight registers, so the instruction values were actually easier to interpret in octal than in hexadecimal. 110 is "load C from B", 103 is "load B from E"...
    – jeffB
    Commented Jul 24, 2019 at 16:39
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    @DrSheldon Of course assemblers/disassemblers have been around forever, but people have been patching things by hand or reading raw dumps during that entire time. And of course you can build as many registers as you want, but the 8080 and its immediate descendants did have three-bit register select fields. I assumed that was why my Z80 pocket guides always showed instructions in both hex and octal, even though my tools all strongly preferred hex.
    – jeffB
    Commented Jul 24, 2019 at 18:01
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    @BobJarvis-ReinstateMonica ...and you'll still get "Your phone is running out of space" messages. Commented Apr 19, 2021 at 10:44
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Was there some particular design theory or constraint that made a 36 bit word size attractive for early computers?

Beside integer arithmetic, 36 bit words work quite fine with two different byte sizes: Six and nine. Six bit was what's needed to store characters of the standard code for data transmission at that time: Baudot code or more exactly ITA2.

As opposed to the various power-of-2 word sizes?

There is no inherent benefit of power of two word sizes. Any number can do.

Even more, there were no 'various power-of-two sizes' in the early and not so early days. Before the IBM/360 settled for a 32 Bit word size and four 8 bit bytes within a word and two nibble in a byte, power-of-two word sizes were an extreme exception (can't come up with any beside SAGE and IBM Stretch). The vast majority used word sizes divisable by 3, not least to allow the use of octal representation. Before the IBM /360 with its 8 bit bytes, octal was as common to computer scientists as hex today - heck, Unix carries this legacy until today, making everyone learn octal at a time when hex is the generally accepted way to display binary data.

Now, the reason why Amdahl did choose 8 bit bytes is rather simple: A byte size chosen had to be at least 6 bit to store a character, eventually 7 for the upcoming ASCII, but 8 would give the ability to store two BCD digits within. Any larger byte size would again waste storage with this important element. Operating in BCD was one main requirement for the /360 design, as it was meant to not only be compatible to, but as well replace all prior decimal machinery.

What seems today as 'natural' use of power of two is just a side effect from being able to handle decimal by a binary computer.

Conclusion: As so often in computing the answer is IBM /360 and the rest is history :)

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    "There is no inherent benefit of power of two word sizes. " This is the most important part of this answer. Before microprocessors, computers were literally assembled by hand. If you didn't need more bits, you didn't wire them up.
    – DrSheldon
    Commented Jul 24, 2019 at 5:24
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    @Luaan nice, but that's retroactive. You might want to tale a look at these machines. Hex may work fint with 36 bit, but it totally screws 18 bit, which was quite often a common half word on such machines. At that time Octal was the way to go. It covers all common used dividers of 36 bit words (18, 9 and 6). Hex, if at all, a quite exotic way to look at binary. World has changed, hasn't it?
    – Raffzahn
    Commented Jul 24, 2019 at 10:26
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    "There is no inherent benefit of power of two word sizes." Is that still true? I had always assumed there was an advantage to being able to address the bits in a word compactly, which may become even more important in modern complex CPUs. But now that I think about it, I'm having trouble coming up with a specific example where it'd help.
    – Cort Ammon
    Commented Jul 24, 2019 at 19:01
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    @CortAmmon, the advantage comes later, when computers start being assembled from commodity parts. If you've got 8-bit words, you can make your RAM from eight 1-bit chips, four 2-bit chips, two 4-bit chips, or a single 8-bit chip. If your word size isn't a power of 2, you've got fewer ways to mix-and-match parts.
    – Mark
    Commented Jul 24, 2019 at 20:52
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    Re "Unix carries this legacy until today, making everyone learn octal", I presume you are talking about chmod? If so, you are mistaken. Using the numeric form of chmod doesn't require any knowledge of octal since one doesn't need to know the number formed. Each digit is independent of the others. Knowledge of hex would do just as well, as so would memorizing the meaning of 4,5,6,7.
    – ikegami
    Commented Jul 26, 2019 at 19:47
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36 bit word size attractive

Many sizes have been tried, but fundamentally, this results in a certain precision; from Wikpedia on 36-bit

Early binary computers aimed at the same market therefore often used a 36-bit word length. This was long enough to represent positive and negative integers to an accuracy of ten decimal digits (35 bits would have been the minimum). It also allowed the storage of six alphanumeric characters encoded in a six-bit character code.

 

As opposed to the various power-of-2 word sizes?

It is lack of requirement to conform to pre-existing specifications, for example, no internet, even simple disc files were not easily shared between computers back in those days.

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The key point made by Wikipedia seems to be:

Prior to the introduction of computers, the state of the art in precision scientific and engineering calculation was the ten-digit, electrically powered, mechanical calculator....Computers, as the new competitor, had to match that accuracy....

Many early computers did this by storing decimal digits. But when switching to binary:

Early binary computers aimed at the same market therefore often used a 36-bit word length. This was long enough to represent positive and negative integers to an accuracy of ten decimal digits (35 bits would have been the minimum).

35 bits is obviously a slightly more awkward size than 36 bits anyway, but there are other reasons to choose it if your minimium size is 35 bits.

  1. 36 bits was on average a bit more efficient when packing characters into a word, especially for the 6-bit character encodings common at the time:

    Char size | 35 bit word       | 36 bit word
    ----------+-------------------+-------------------
        6-bit | 5 + 5 bits unused | 6 + 0 bits unused
        7-bit | 5 + 0 bits unused | 5 + 1 bit unused
        8-bit | 4 + 3 bits unused | 4 + 4 bits unused
    
  2. If you intend to make smaller computers later, having registers that are exactly divisible by two makes having some level of data interoperability easier, if not perfect. (Numerical data in a single large word can easily be split into two smaller high and low words, and a 6-char x 6-bit word can be split into two 3-char words, but splitting a 36-bit word with packed 7- and 8-bit character data would result in either splitting parts of characters between the smaller words or adding additional smaller words and ending up using more bits than the original larger word.)

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    I think the smaller computers with half the wordsize is an important point. DEC, who made a fair few 36 bit computers, already had the PDP-7 and other 18-bitters on the market for a long time. And of course, 36 also is a multiple of 12, another wordsize they used (PDP-8) Commented Jul 24, 2019 at 15:36
  • @Wilson Actually, I'm starting to doubt that point now: DEC's first computer, the PDP-1, was 18-bit, and they moved up to 36-bit only later. The major 36-bit architecture predating DEC was the IBM 701 and its descendants, but I can't find any evidence that they ever created a smaller 18-bit version of that. (If anything, the PDP-1 was that smaller version!) Still, I suppose they could have planned for that, even if they didn't do it.
    – cjs
    Commented Jul 24, 2019 at 15:47
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    w.r.t. 7 bit character data and splitting parts of characters between words: The 36-bit PDP-10 architecture had instruction set support for variable-sized "characters" and compilers used that to pack 5 7-bit characters per word - with one bit left over, which didn't hurt addressing at all, but which clever application programs would use for all kinds of things ... - Frequently programs used both 6-bit (where only upper case and digits and some punctuation was needed - like symbol tables - and 7-bit (where you wanted a full alphabet plus digits plus punctuation) character representations.
    – davidbak
    Commented Jul 25, 2019 at 2:24
  • @davidbak That's a clever trick, but rather beside my point. I've tried to clarify that part of the answer. The issue is that with 6-bit chars, a 36-bit word of 6 chars divides nicely into two 18-bit words of 3 chars each, but with 7-bit chars a 36-bit word of of 5 chars cannot be divided into two 18-bit words without splitting a character between those two words. Given the various difficulties that would produce, it would make more sense to allocate the 7 chars amongst three 18-bit words, but then you are sigificantly changing both the size and processing of the storage.
    – cjs
    Commented Jul 27, 2019 at 2:45
  • @CurtJ.Sampson - I did get your point. But we're talking about 36-bit word machines, like the PDP-10. And though you could do halfword stuff on that machine, you didn't. You used it fullword all the time. You couldn't address halfwords.. And I don't have a history in front of me - but the PDP-10 came after 3 generations of Digital Equipment Corp's 18-bit machines, and was intended to be a "mainframe", so they weren't particularly worried about "making smaller computers later" with any kind of compatibility.
    – davidbak
    Commented Jul 27, 2019 at 3:08
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Wiki page 36-bit shows some reasons (all copied from the page):

  • "This was long enough to represent positive and negative integers to an accuracy of ten decimal digits (35 bits would have been the minimum). It also allowed the storage of six alphanumeric characters encoded in a six-bit character code. "

  • And for characters:

    • six 5.32-bit DEC Radix-50 characters, plus four spare bits
    • six 6-bit Fieldata or IBM BCD characters (ubiquitous in early usage)
    • six 6-bit ASCII characters, supporting the upper-case unaccented letters, digits, space, and most ASCII punctuation characters. It was used on the PDP-6 and PDP-10 under the name sixbit.
    • five 7-bit characters and 1 unused bit (the usual PDP-6/10 convention, called five- seven ASCII)1[2]
    • four 8-bit characters (7-bit ASCII plus 1 spare bit, or 8-bit EBCDIC), plus four spare bits
    • four 9-bit characters1[2] (the Multics convention).
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When I was first exposed to this stuff in engineering school in 1978, I was taught that a "byte" could be either six or eight bits; the former were usually represented as two octal digits, and the latter by two hex digits. Most of the computers I used in college (PDP-8s and a CDC 6600) were based on six-bit bytes.

There were quite a few computers using odd word sizes in the '70s; probably there were more different architectures based on 6-bit bytes than 8-bit bytes. The PDP-8 was a 12-bit machine; Harris actually sold a microprocessor compatible with the PDP-8 instruction set.

DEC also made 36-bit machines for a while. The CDC6600 and 7600 were 60-bit machines. I gather that there were quite a few 18-bit machines in military applications, but I've only ever worked with those architectures in emulation (and I'm confident there are still emulators of 18-bit processors being built).

There probably are still 36-bit machines (or at least 36-bit software) running production EDI applications, because General Electric kept using their own computers in their EDI services business long after they'd sold that hardware business off to Honeywell (and in fact after Honeywell sold it to Bull). Although these days I'd guess they're running in emulation on 8-bit hardware.

From my perspective there was no more rationale than success in the marketplace, and the turning point was Intel's choice of 8 bits for single-chip microprocessors.

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    IMO the turning point was IBM's choice of an 8-bit byte for the System/360, which (along with its successors) became the dominant mainframe computers for the next 30 years. Commented Jul 26, 2019 at 17:11
  • In my experience of two very different machines, octal was used for 8-bit quantities. PDP-11 (16 bit word/8 bit byte). KDF9 (48-bit word/8 bit syllable, "syllabic octal" used when writing a word as six syllables).
    – dave
    Commented Jul 26, 2019 at 17:19
  • I also occasionally saw 8- and 16-bit words represented in octal. Lot more octal than hex in those days.
    – jefuf
    Commented Jul 26, 2019 at 17:40
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    I suspect in many cases octal was used for 8- and 16-bit byte/word sizes because octal had already been used extensively in previous machines (where it made more sense) and both existing knowedge and existing code (e.g., when building, e.g., cross-assemblers or porting other tools) could be re-used. DEC had spent more than ten years producing various 18-, 12- and 36-bit machines by the time they released the PDP-11.
    – cjs
    Commented Jul 27, 2019 at 1:09
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I happen to find an explanation on 36-bit floatpoint advantage over 32-bit from an article in the WIKI, which I found interesting but unable to verify. It says.

The 1100 Series has used a 36-bit word with 6-bit characters since 1962. This word and character size was a Department of Defense (DoD) requirement.[citation needed] Since the military needed to be able to calculate accurate trajectories, design bridges, and perform other engineering and scientific calculations, they needed more than 32 bits of precision. A 32-bit floating point number only provided about 6 digits of accuracy while a 36 bit number provided the 8 digits of accuracy that were accepted as the minimum requirement. Since memory and storage space and costs drove the system, going to 64 bits was simply not acceptable in general. These systems use ones' complement arithmetic, which was not unusual at the time. Almost all computer manufacturers of the time delivered 36-bit systems with 6-bit characters including IBM, DEC, General Electric, and Sylvania.

Well, now it turns out to me that IBM's adoption of 32-bit, rather than other firms sticking to 36-bit to 1996 or new century, is a big surprise indeed.

PS: As for charset, it's not that surprising.

The 6-bit character set used by the 1100 Series is also a DoD mandated set. It was defined by the Army Signal Corps and called Fieldata (data returned from the field).1 The 1108 provided a 9-bit character format in order to support ASCII and later the ISO 8-bit sets, but they were not extensively used until the 1980s again because of space constraints.

Thus I don't think packing five 7-bit ASCII in 36bit is a big deal or ASCII justified 8-bit bytes.

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Computers used to be all sorts of varying standards for varying reasons. When only large businesses could afford a computer, they bought or designed a computer for the reasons they needed. Thus, there were systems including 4, 6, 8, 13, 16, 18, 24, 26, 32, 36, etc.

There have been computers using binary and trinary (ternary).

Eventually, due to the popularization of Intel CPU along with many other Risc chips being 16-32-64 binary bits, these became the standard.

Windows 7-x64-Home only allowed 8 or 16 GB of memory address space in 64-bit mode.

Today, most 64-bit CPU have a 48-bit memory interface, with 56 as an option. Many BIOS/EFI don't have 48-bits, and might only allow 36, 38, 40 or whatever bits of memory space. E.g. many systems cannot address more than 16 GB or 64 GB, or whatever. The CPU and OS can use the remainder as swap/page file space.

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    1. This doesn't address the particular reasons that someone looking at any of those bit ranges you mentioned would choose 36. 2. The size of the address bus relevant here; even a number of the 36-bit computers being talked about didn't have a 36-bit address bus. (The IBM 701 had 12-bit addresses, for example.) 3. Address space cannot be used as "swap space."
    – cjs
    Commented Jul 27, 2019 at 0:53
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    You've sort of just written "varying reasons" where the answer should be.
    – wizzwizz4
    Commented Jul 27, 2019 at 11:56
  • The particular reason is because a developer, programmer, manager, or designer chose that number. Same with the other options. The reasons for many choices are simply choices made that might meet some need. They may not meet the current or the next need. The choice might become a standard or be replaced.
    – MikeP
    Commented Jul 28, 2019 at 4:28
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The main reason I was taught back in the 70s, was the original binary (vs. decimal) IBM machines (e.g., the IBM 701)'s ability to store two 18 bit addresses (about the most memory one could afford at the time) pushed the development of a programming language that took advantage of it. And thus that capability caused later machines to inherit that as a minimum word size. Also named "CAR" and "CDR". Yep, it was Lisp.

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  • Right, the decimal machines (e.g. using binary coded decimal) represented decimal numbers (i.e. used 4 bits to represent 0-9), and I believe virtually all the machines that preceded the 701 did that. So the representation of 12 was different in a decimal machine than a binary machine. See here: en.wikipedia.org/wiki/Decimal_computer
    – I'm Pliny
    Commented Mar 22, 2023 at 21:57
  • Thanks - thought that's what was intended, but not quite confident to make the edit for you! Commented Mar 23, 2023 at 7:26

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