Arm's New Cortex-A78 and Cortex-X1 Microarchitectures: An Efficiency and Performance Divergenceby Andrei Frumusanu on May 26, 2020 9:00 AM EST
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- Cortex A78
- Cortex X1
- Mali G78
2019 was a great year for Arm. On the mobile side of things one could say it was business as usual, as the company continued to see successes with its Cortex cores, particularly the new Cortex-A77 which we’ve now seen employed in flagship chipsets such as the Snapdragon 865. The bigger news for the company over the past year however hasn’t been in the mobile space, but rather in the server space, where one can today rent Neoverse-N1 CPUs such as Amazon’s impressive Graviton2 chip, with more vendors such as Ampere expected to release their server products soon.
While the Arm server space is truly taking off as we speak, aiming to compete against AMD and Intel, Arm hasn't reached the pinnacle of the mobile market – at least, not yet. Arm’s mobile Cortex cores have lived in the shadow of Apple’s custom CPU microarchitectures over the past several years, as Apple has seemingly always managed to beat Cortex designs by significant amounts. While there’s certainly technical reasons to the differences – it was also a lot due to business rationale on Arm’s side.
Today for Arm’s 2020 TechDay announcements, the company is not just releasing a single new CPU microarchitecture, but two. The long-expected Cortex-A78 is indeed finally making an appearance, but Arm is also introducing its new Cortex-X1 CPU as the company’s new flagship performance design. The move is not only surprising, but marks an extremely important divergence in Arm’s business model and design methodology, finally addressing some of the company’s years-long product line compromises.
The New Cortex-A78: Doubling Down on Efficiency
The new Cortex-A78 isn’t exactly a big surprise – Arm had first publicly divulged the Hercules codename over two years ago when they had presented the company’s performance roadmap through 2020. Two years later, and here we are, with the Cortex-A78 representing the third iteration of Arm’s new Austin-family CPU microarchitecture, which had started from scratch with the Cortex-A76.
The new Cortex-A78 pretty much continues Arm’s traditional design philosophy, that being that it’s built with a stringent focus on a balance between performance, power, and area (PPA). PPA is the name of the game for the wider industry, and here Arm is pretty much the leading player on the scene, having been able to provide extremely competitive performance at with low power consumption and small die areas. These design targets are the bread & butter of Arm as the company has an incredible range of customers who aim for very different product use-cases – some favoring performance while some other have cost as their top priority.
All in all (we’ll get into the details later), the Cortex-A78 promises a 20% improvement in sustained performance under an identical power envelope. This figure is meant to be a product performance projection, combining the microarchitecture’s improvements as well as the upcoming 5nm node advancements. The IP should represent a pretty straightforward successor to the already big jump that were the A76 and A77.
The New Cortex-X1: Breaking the Design Constraint Chains
Arm’s existing business model was aimed at trying to create a CPU IP that covers the widest range of customer needs. This creates the problem that you cannot hyper-focus on any one area of the PPA triangle without making compromises in the other two. I mentioned that Arm’s CPU cores have for years lived in the shadow of Apple’s CPU cores, and whilst for sure, the Apple's cores were technical superior, one very large contributing factor in Arm's disadvantage was that the business side of Arm just couldn’t justify building a bigger microarchitecture.
As the company is gaining more customers, and is ramping up R&D resources for designing higher performance cores (with the server space being a big driver), it seems that Arm has finally managed to get to a cross-over point in their design abilities. The company is now able to build and deliver more than a single microarchitecture per year. In a sense, we sort of saw the start of this last year with the introduction of the Neoverse-N1 CPU, already having some more notable microarchitectural changes over its Cortex-A76 mobile sibling.
Taking a quick look at the new Cortex-X1, we find the X1 higher up in Arm’s Greek pantheon family tree of CPU microarchitectures. Codenamed Hera, the design at least is named similarly to its Hercules sibling, denominating their close design relationship. The X1 is much alike the A78 in its fundamental design – in fact both CPUs were created by the same Austin CPU design team in tandem, but with the big difference that the X1 breaks the chains on its power and area constraints, focusing to get the very best performance with very little regard to the other two metrics of the PPA triangle.
The Cortex-X1 was designed within the frame of a new program at Arm, which the company calls the “Cortex-X Custom Program”. The program is an evolution of what the company had previously already done with the “Built on Arm Cortex Technology” program released a few years ago. As a reminder, that license allowed customers to collaborate early in the design phase of a new microarchitecture, and request customizations to the configurations, such as a larger re-order buffer (ROB), differently tuned prefetchers, or interface customizations for better integrations into the SoC designs. Qualcomm was the predominant benefactor of this license, fully taking advantage of the core re-branding options.
The new Cortex-X program is an evolution of the BoACT license, this time around making much more significant microarchitectural changes to the “base” design that is listed on Arm’s product roadmap. Here, Arm proclaims that it allows customers to customize and differentiate their products more; but the real gist of it is that the company now has the resources to finally do what some of its lead customers have been requesting for years.
One thing to note, is that while Arm names the program the “Cortex-X Custom Program”, it’s not to be confused with actual custom microarchitectures by vendors with an architectural license. The custom refers to Arm’s customization of their roadmap CPU cores – the design is still very much built by Arm themselves and they deliver the IP. For now, the X1 IP will also be identical between all licensees, but the company doesn’t rule out vendor-specific changes the future iterations – if there’s interest.
This time around Arm also maintains the marketing and branding over the core, meaning we’ll not be seeing the CPU under different names. All in all, the whole marketing disclosure around the design program is maybe a bit confusing – the simple matter of fact is that the X1 is simply another separate CPU IP offering by Arm, aimed at its leading partners, who are likely willing to pay more for more performance.
At the end of the day, what we're getting are two different microarchitectures – both designed by the same team, and both sharing the same fundamental design blocks – but with the A78 focusing on maximizing the PPA metric and having a big focus on efficiency, while the new Cortex-X1 is able to maximize performance, even if that means compromising on higher power usage or a larger die area.
It’s an incredible design philosophy change for Arm, as the company is no longer handicapped in the ultra-high-tier performance ring with the big players such as Apple, AMD, or Intel – all whilst still retaining their bread & butter design advantages for the more cost-oriented vendors out there who deliver hundreds of millions of devices.
Let’s start by dissecting the microarchitecture changes of the new CPUs, starting off with the Cortex-A78…
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Drake H. - Tuesday, May 26, 2020 - linkHonestly, who cares about that? This extra power is useless. Playing on mobile device is uncomfortable and bad for eye health. They should convert priority into maximum efficiency only.
The critical point that needs to evolve in smartphones is the battery and nobody talks about. Where are the graphene batteries samsung promised? I miss having a cell phone that lasts a week without charging. :(
syxbit - Tuesday, May 26, 2020 - linkExtra power is never useless. Sure if you just browse facebook. But iPads and Android tablets are trying to replace laptops. The A13 can probably replace a laptop. No Qualcomm chip can do that as well.
I suspect when Apple replaces their laptop intel chips with their Arm chips, they'll be faster, and better battery life. But when Microsoft tries to do it with QCOMM, they're much worse
skavi - Tuesday, May 26, 2020 - linkAndroid tablets are dead in the high end. Would like to see some X1 cores in a future Surface tho.
Drake H. - Tuesday, May 26, 2020 - linkNah, there is no ARM CPU that can replace a regular x86 CPU for gaming or work, and it won't exist at any time soon. You don't reverse millions of software and years of optimization overnight.
FunBunny2 - Tuesday, May 26, 2020 - link"You don't reverse millions of software and years of optimization overnight."
cross-compile is old news. any C/C++ compiler can do that. OTOH, all those system calls are the major issue.
vladx - Tuesday, May 26, 2020 - linkCross-compiling doesn't mean your software will run at same performance on everything, for that to happen you still need to implement architecture-specific optimizations and even so there's still no guarantees.
serendip - Wednesday, May 27, 2020 - linkA fast ARM chip could brute force x86-32 code translation so it was fast enough. The SQ1 in the Surface Pro X can run x86-32 code without it being snail slow like on older SD850 devices. An X1-based chip could probably do x86-64 translation (coming next year according to Microsoft) at 8th gen i5 levels, and it would fly when running ARM native code.
Drake H. - Wednesday, May 27, 2020 - linkBy this logic it seems that anyone could port the x86 recompiler from pcsx2 to ARM with a few clicks. Optimizing software for ARM would take a lot of time and money, not to mention that some of these software has no source code available.
iphonebestgamephone - Wednesday, May 27, 2020 - linkNot on android or windows, but on a console its pretty good for gaming, as proven by the switch?
soresu - Wednesday, May 27, 2020 - linkHow can you be disappointed?
It's not like there is a direct comparison, often with high end apps and games there is a serious lag between it being available on iOS and it becoming available on Android, sometimes it never comes at all.
Though the openness of Android means we get some things easily that iOS device owners have to jump through hoops for, namely console emulators.
What's the use having all that power in the Apple Axx SoC's when you are restricted in your freedom to do with it as you wish? All things considered I'll take a performance hit for that freedom any day of the week.