Arm Announces Neoverse N1 & E1 Platforms & CPUs: Enabling A Huge Jump In Infrastructure Performance
by Andrei Frumusanu on February 20, 2019 9:00 AM ESTThe Neoverse E1 CPU: A Small SMT Core for the Data-Plane
We’ve talked a lot about the Neoverse N1 – but today’s announcement actually covers two new platforms. Today actually isn’t the first time that we’ve talked about the other new platform, the new Neoverse E1. Codenamed Helios, the E1 CPU actually is derived from the Cortex-A65AE which we’ve already briefly talked about in December.
Arm largely differentiates between two big workload types in infrastructure deployments, “Compute” use-cases where we need arithmetically capable CPU cores such as the N1, and “Throughput” workloads that largely are mainly about shifting large amounts of data around. The latter category is what the new Neoverse E1 is targeting, representing a specialised CPU core that efficiently and cost effectively is able to handle such tasks.
Arm’s First SMT Core
As some might have read in the Cortex-A65AE announcement piece, the µarchitecture used in Helios both in the Cortex chip as well as in the Neoverse E1 represents Arm’s first ever foray into designing and bringing to market an SMT (simultaneous multi-threading) core. It may at first glance sound a bit weird to have SMT introduced in a smaller CPU core, as traditionally we would be thinking about SMT being useful in raising the back-end execution unit utilisation rate in larger microarchitectures, but it actually makes a lot of sense as well in smaller CPU cores whose workloads are predominantly in the data plane.
In data-processing workloads, cache misses dominate CPU work cycles. This is because we’re talking about data that inherently doesn’t have a long residence time on the CPU core, either streaming from sensors as described in the use-case of the Cortex-A65AE, or in this case streaming from the network in the case of infrastructure workloads. This means that the CPU has to deal with long memory latency accesses, introducing stalls in the CPU pipelines.
The E1 CPU is a small out-of-order design with SMT: In data-plane heavy workloads, introducing the ability to handle a secondary thread on the CPU core essentially represents almost a free throughput gain for the microarchitecture, as it’s able to fill unused execution cycles that otherwise would have just gone to waste. Indeed in optimal workloads, this can result in essentially a doubling of the throughput, on top of the single-threaded microarchitectural gains that the E1 CPU brings over predecessors such as the Cortex A55.
At the cluster level, the Neoverse E1 CPU configuration options are extremely similar to what we’ve seen deployable in DynamIQ systems. The cluster itself looks very much like a DSU, with up to eight cores, a cluster-level snoop filter, and an L3 cache configurable up to 4MB.
The E1 CPU’s Pipelines
The E1’s CPU pipeline actually represents a brand new-design which (besides the A65) haven’t seen employed before. What Arm has done here is take the foundation of what was the in-order Cortex A55 µarch and turned it into a minimally narrow out-of-order CPU. Moving to a basic out-of-order CPU design was essential in order to get more throughput out of the core, as it avoids stalling the whole pipeline in scenarios where we’d have a long load.
The fetch/decode/dispatch stages of the pipeline is 2-wide. In terms of its out-of-order windows, we see a small 40-deep ROB (Re-order buffer).
On the back-end we find a similar execution unit count and layout as on the Cortex-A55. A big difference to the A55 is that the integer ALUs are now differently partitioned: One ALU is dedicated for simple arithmetic operations only, while the second unit now takes over both integer multiplication as well as division tasks, whereas this was divided among the two ALUs in the A55. Interestingly, Arm also demarks the branch port being shared with this second complex integer ALUs, no longer representing it as a dedicated port as on the A55.
The SIMD/Neon pipelines seem to remain the same as on the A55 in terms of its high-level capabilities, but it is possible Arm may have improved cycle latencies of some instructions between the two generations.
Finally, the load and store ports also match the capabilities of the A55.
SMT on the Neoverse E1 is enabled through the duplication of architectural state components of the core. This means the CPU has double the general purpose, vector and system registers and their corresponding structures on the physical core.
At the software level, this naturally simply appears as two separate CPU cores, and can be run at different exception levels or even be running different OSes.
Performance partitioning between the two threads is enabled by a simple round-robin instruction fetch mechanism, ensuing that both threads get the same amount of attention.
The front-end of the CPU has seen improvements in all regards and adopts many of the state-of-the art front end branch prediction and prefetch mechanisms we find in other more recent Arm OoO cores – just in a more limited implementation optimised for the smaller nature of the E1 CPU.
As mentioned just earlier, although the throughput of the execution pipelines hasn’t fundamentally changed, Arm has updated the execution units to employ newer designs with shorter cycle latencies. Here in particular FMAC latency has bene halved, while the integer division unit has been updated to a Radix-16 unit. It’s to be noted that these improvements are again slightly misleading as Arm is making comparisons to the Cortex A53 – the newer Cortex A55 already employed the aforementioned changed, including the new ARMv8.2 double throughput FP16 instructions as well as Int8 dot-products.
On the memory system side of things, we again see very large similarities to the Cortex A55 and the E1 enjoys the same improvements made by that µarch. The only other notable changes here are the fact that the data prefetchers as well as the L2 TLB are now multi-thread aware and are optimised in their design to better operate with the new SMT nature of the core.
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WinterCharm - Wednesday, February 20, 2019 - link
There's a gigantic Arm vs x86/64 battle brewing for the entire computer industry. ARM is just more efficient at every level, and if software is properly optimized it performs brilliantly.eva02langley - Wednesday, February 20, 2019 - link
However, it doesn't have the raw power required for many fields like scientific, compute and research. The core-count is also a huge factor in the upcoming future and unless you develop a chiplet approach, ARM is going to face the same issue of monolithic chips.The next chiplet evolution will require stacking. The future is way more related to modularity than the chip architecture. Don't get me wrong, the more advancement, the better for everyone, but I don't believe ARM is going to render x86 obsolete, hovwever I believe multi-chips SoC are going to render monolithic chip obsolete in the computer world.
SarahKerrigan - Wednesday, February 20, 2019 - link
Sure it does. There are ARM supercomputers, and this very article shows an N1 core outperforming Zen on single-thread, and both Zen and SKL-SP on throughput.HStewart - Wednesday, February 20, 2019 - link
I think you are forgetting the very nature of RISC (Arm) vs CISC (x86) architectures. By the nature of designed of RISC - reduce instruction set, it takes more instruction to execute same operation than CISC. For simple stuff RISC can likely do better but remember also modern x86 based CPU also break down more complex instructions in simpler instruction so it can run one multiple pipelines.SarahKerrigan - Wednesday, February 20, 2019 - link
Dude, I work in the semi industry, and I've designed pipelined cores. Saying "ARM's workload-demonstrated higher performance doesn't matter because x86 is CISC" is idiotic.SPEC isn't "simple stuff." It is a selection of extremely compute-intensive workstation loads, one that the whole industry - including Intel - uses to demonstrate comparative performance.
HStewart - Wednesday, February 20, 2019 - link
The biggest thing I found that seems misinformation is statement that these are estimates and this chip is simulated which tells me they don't need the real numbers.All I am saying is that CISC instructions can do more than RISC instructions per instruction, and it depends on compiler to take advantage of the those instructions. Please note I never sated it does not matter and that was in your words. I just mention considerations need to take in account of different architextures and the fact they are comparing future simulated designed to last year designs.
Andrei Frumusanu - Wednesday, February 20, 2019 - link
> All I am saying is that CISC instructions can do more than RISC instructions per instructionNobody cares. If the performance per clock is same or higher, you're just arguing about semantics.
Internally CISC processors break things down into RISC like µOps anyway.
ZolaIII - Wednesday, February 20, 2019 - link
@Andrei Frumusanu what would be estimated size of an A55 core with similar amount of cache as on represented E1 on 7nm lithography? I am very curious about that one. Also comparation to the A72 & A73 should be a good thing as ARM clames it reaches their level of performance. Its very interesting first born (SMT) and much needed one.zmatt - Wednesday, February 20, 2019 - link
When people talk about complex instructions they don't mean something like find the derivative of x^2. They mean something like a conditional move operation. The speed advantages on paper between RISC and CISC are in theory a wash. This is because while CISC can conceivably do more in an instruction, RISC can do more instructions per clock generally. In the real world the simplicity of RISC means usually, all other things being equal, the chips are simpler and can run higher clocks, draw less power and generate less heat for a given level of performance.x86 chips haven't actually been CISC since the mid 90's. Both Intel and AMD have been making chips that take the CISC instructions and run them through an instruction decoder that then hands RISC instructions to the actual cpu. Yes this does incur some overhead but it frees up cpu design quite a bit without being so closely tied to backwards compatibility.
The fact that modern x86 chips ultimately are actually executing code as reduced instruction sets shows you don't understand the concept.
Wilco1 - Wednesday, February 20, 2019 - link
x86 is still a CISC ISA irrespectively of how it executes instructions. Note that compilers predominantly use the simpler instructions, rather than the microcoded instructions and that's why it's possible for x86 to be fast at all.