The PS3 had a 128-bit CPU. Sort of. "Altivec" vector processing could split each 128-bit word into several values and operate on them simultaneously. So for example if you wanted to do 3D transformations using 32-bit numbers, you could do four of them at once, as easily as one. It doesn't make doing one any faster.

Vector processing is present in nearly every modern CPU, though. Intel's had it since the late 90s with MMX and SSE. Those just had to load registers 32 bits at a time before performing each same-instrunction-multiple-data operation.

The benefit of increasing bit depth is that you can move that data in parallel.

The downside of increasing bit depth is that you have to move that data in parallel.

To move a 32-bit number between places in a single clock cycle, you need 32 wires between two places. And you need them between any two places that will directly move a number. Routing all those wires takes up precious space inside a microchip. Indirect movement can simplify that diagram, but then each step requires a separate clock cycle. Which is fine - this is a tradeoff every CPU has made for thirty-plus years, as "pipelining." Instead of doing a whole operation all-at-once, or holding back the program while each instruction is being cranked out over several cycles, instructions get broken down into stages according to which internal components they need. The processor becomes a chain of steps: decode instruction, fetch data, do math, write result. CPUs can often "retire" one instruction per cycle, even if instructions take many cycles from beginning to end.

To move a 128-bit number between places in a single clock cycle, you need an obscene amount of space. Each lane is four times as wide and still has to go between all the same places. This is why 1990s consoles and graphics cards might advertise 256-bit interconnects between specific components, even for mundane 32-bit machines. They were speeding up one particular spot where a whole bunch of data went a very short distance between a few specific places.

Modern video cards no doubt have similar shortcuts, but that's no longer the primary way the perform ridiculous quantities of work. Mostly they wait.

CPUs are linear. CPU design has sunk eleventeen hojillion dollars into getting instructions into and out of the processor, as soon as possible. They'll pre-emptively read from slow memory into layers of progressively faster memory deeper inside the microchip. Having to fetch some random address means delaying things for agonizing microseconds with nothing to do. That focus on straight-line speed was synonymous with performance, long after clock rates hit the gigahertz barrier. There's this Computer Science 101 concept called Amdahl's Law that was taught wrong as a result of this - people insisted 'more processors won't work faster,' when what it said was, 'more processors do more work.'

Video cards wait better. They have wide lanes where they can afford to, especially in one fat pipe to the processor, but to my knowledge they're fairly conservative on the inside. They don't have hideously-complex processors with layers of exotic cache memory. If they need something that'll take an entire millionth of a second to go fetch, they'll start that, and then do something else. When another task stalls, they'll get back to the other one, and hey look the fetch completed. 3D rendering is fast because it barely matters what order things happen in. Each pixel tends to be independent, at least within groups of a couple hundred to a couple million, for any part of a scene. So instead of one ultra-wide high-speed data-shredder, ready to handle one continuous thread of whatever the hell a program needs next, there's a bunch of mundane grinders being fed by hoppers full of largely-similar tasks. It'll all get done eventually. Adding more hardware won't do any single thing faster, but it'll distribute the workload.

Video cards have recently been pushing the ability to go back to 16-bit operations. It lets them do more things per second. Parallelism has finally won, and increased bit depth is mostly an obstacle to that.

So what 128-bit computing would look like is probably one core on a many-core chip. Like how Intel does mobile designs, with one fat full-featured dual-thread linear shredder, and a whole bunch of dinky little power-efficient task-grinders. Or... like a Sony console with a boring PowerPC chip glued to some wild multi-phase vector processor. A CPU that they advertised as a private supercomputer. A machine I wrote code for during a college course on machine vision. And it also plays Uncharted.

The PS3 was originally intended to ship without a GPU. That's part of its infamous launch price. They wanted a software-rendering beast, built on the Altivec unit's impressive-sounding parallelism. This would have been a great idea back when TVs were all 480p and games came out on one platform. As HDTVs and middleware engines took off... it probably would have killed the PlayStation brand. But in context, it was a goofy path toward exactly what we're doing now - with video cards you can program to work however you like. They're just parallel devices pretending to act linear, rather than they other way around.

They would look the same really. The word size being 128 instead of 64 doesn't really change anything about the architecture. It just means the proc's registers are 128 bits in size, the system bus is 128, each RAM address and data is 128, etc. The only difference would be significantly more expensive to crunch ridiculously large numbers. So really not much benefit. I expect 64 to be the standard for quite a long time, maybe forever, because we have much bigger bottlenecks to worry about.

exactly the same as 64 bit computing, except pointers now take up twice as much ram, and therefore you need mire baseline momory throuput/ more cache, for pretty much no practical benefit. Because we aren't close to fully using up a 64-bit address space .

It wouldn't be much different. Was it noticeably different when you went from a 32 bit to 64 bit computer?

The big shortcoming of 32 bit hardware was that it limits the amount of RAM in the computer to 4 GB. 64 bit is not inherently faster (for most things) but it enables up to 16 exabytes of RAM, an incomprehensible amount. Going to 128 bit would only be helpful if 16 exabytes wasn't enough.

We have 128 bit stuff in some places where it's advantageous, but in most cases there's not really a need. 64 bits already provides a maximum integer value of (+/-)9,223,372,036,854,775,807. Double it if you don't need negatives and drop the sign. There's little need in most cases for a bigger number, and cases that do either get 128 bit hardware, or can be handled by big number libraries.

Similar to a modern 64 bit computer, my computer actually has a 512 bit wide ALU for SIMD, basically it lets you do the same operation on multiple numbers simultaneously.

Riscv has a 128bit instruction set under proposal.

Nobody will ever use it, they know they'll never use it, it's stupid and impractical.

But maybe one day we want to connect every computer on the world together, we could probably use 128bit addresses so my computer could work on data in your computers memory.

There are ways to do this now, but maybe they make it simpler later.

You'd be able to access more memory than we'd be able to physically build in the world.

In fact, your computer is already capable of processing more than 64 bits at once using SIMD instructions. Many applications or things you don't suspect may or are already using them, including games.

It’s hard to picture “128bit computing” in a general sense as ever being a thing. It’s just so far beyond anything we can realistically use now, plus would be inefficient/wasteful on most ordinary tasks.

Put this together with the physical limits to Moore’s law and current approaches to at least mobile computing ……

I picture more use of multi-core, specialty core, system on a chip. Some loads, like video, benefit from wide lanes, huge bandwidth, addresses many things at once, and we have video cores with architectures more suited for that. Most loads can be done with a standard compute core, and it is unnecessary, maybe counterproductive to move up to 128bit. If we want efficiency cores, like some mobile already have, 128bit is wrong/bad/inefficient. We’ll certainly have more AI cores, but I have no idea what they need

If you can forgive the Apple boosterism and take this as a general trend, see the focus on fast interconnections to many specialty cores. Each core has a different architecture and different needs

— https://www.apple.com/newsroom/2023/06/apple-introduces-m2-ultra/