The NVIDIA GeForce GTX 1080 & GTX 1070 Founders Editions Review: Kicking Off the FinFET Generation
by Ryan Smith on July 20, 2016 8:45 AM ESTDesigning GP104: Running Up the Clocks
So if GP104’s per-unit throughput is identical to GM204, and the SM count has only been increased from 2048 to 2560 (25%), then what makes GTX 1080 60-70% faster than GTX 980? The answer there is that instead of vastly increasing the number of functional units for GP104 or increasing per-unit throughput, NVIDIA has instead opted to significantly raise the GPU clockspeed. And this in turn goes back to the earlier discussion on TSMC’s 16nm FinFET process.
With every advancement in fab technology, chip designers have been able to increase their clockspeeds thanks to the basic physics at play. However because TSMC’s 16nm node adds FinFETs for the first time, it’s extra special. What’s happening here is a confluence of multiple factors, but at the most basic level the introduction of FinFETs means that the entire voltage/frequency curve gets shifted. The reduced leakage and overall “stronger” FinFET transistors can run at higher clockspeeds at lower voltages, allowing for higher overall clockspeeds at the same (or similar) power consumption. We see this effect to some degree with every node shift, but it’s especially potent when making the shift from planar to FinFET, as has been the case for the jump from 28nm to 16nm.
Given the already significant one-off benefits of such a large jump in the voltage/frequency curve, for Pascal NVIDIA has decided to fully embrace the idea and run up the clocks as much as is reasonably possible. At an architectural level this meant going through the design to identify bottlenecks in the critical paths – logic sections that couldn’t run at as high a frequency as NVIDIA would have liked – and reworking them to operate at higher frequencies. As GPUs typically (and still are) relatively low clocked, there’s not as much of a need to optimize critical paths in this matter, but with NVIDIA’s loftier clockspeed goals for Pascal, this changed things.
From an implementation point of view this isn’t the first time that NVIDIA has pushed for high clockspeeds, as most recently the 40nm Fermi architecture incorporated a double-pumped shader clock. However this is the first time NVIDIA has attempted something similar since they reined in their power consumption with Kepler (and later Maxwell). Having learned their lesson the hard way with Fermi, I’m told a lot more care went into matters with Pascal in order to avoid the power penalties NVIDIA paid with Fermi, exemplified by things such as only adding flip-flops where truly necessary.
Meanwhile when it comes to the architectural impact of designing for high clockspeeds, the results seem minimal. While NVIDIA does not divulge full information on the pipeline of a CUDA core, all of the testing I’ve run indicates that the latency (in clock cycles) of the CUDA cores is identical to Maxwell. Which goes hand in hand with earlier observations about throughput. So although optimizations were made to the architecture to improve clockspeeds, it doesn’t look like NVIDIA has made any more extreme optimizations (e.g. pipeline lengthening) that detectably reduces Pascal’s per-clock performance.
Finally, more broadly speaking, while this is essentially a one-time trick for NVIDIA, it’s an interesting route for them to go. By cranking up their clockspeeds in this fashion, they avoid any real scale-out issues, at least for the time being. Although graphics are the traditional embarrassingly parallel problem, even a graphical workload is subject to some degree of diminishing returns as GPUs scale farther out. A larger number of SMs is more difficult to fill, not every aspect of the rendering process is massively parallel (shadow maps being a good example), and ever-increasing pixel shader lengths compound the problem. Admittedly NVIDIA’s not seeing significant scale-out issues quite yet, but this is why GTX 980 isn’t quite twice as fast as GTX 960, for example.
Just increasing the clockspeed, comparatively speaking, means that the entire GPU gets proportionally faster without shifting the resource balance; the CUDA cores are 43% faster, the geometry frontends are 43% faster, the ROPs are 43% faster, etc. The only real limitation in this regard isn’t the GPU itself, but whether you can adequately feed it. And this is where GDDR5X comes into play.
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DonMiguel85 - Wednesday, July 20, 2016 - link
Agreed. They'll likely be much more power-hungry, but I believe it's definitely doable. At the very least it'll probably be similar to Fury X Vs. GTX 980sonicmerlin - Thursday, July 21, 2016 - link
The 1070 is as fast as the 980 ti. The 1060 is as fast as a 980. The 1080 is much faster than a 980 ti. Every card jumped up two tiers in performance from the previous gen. That's "standard" to you?Kvaern1 - Sunday, July 24, 2016 - link
I don't think there's much evidence pointing in the direction of GCN 4 blowing Pascal out of the water.Sadly, AMD needs a win but I don't see it coming. Budgets matter.
watzupken - Wednesday, July 20, 2016 - link
Brilliant review. Thanks for the in depth review. This is late, but the analysis is its strength and value add worth waiting for.ptown16 - Wednesday, July 20, 2016 - link
This review was a L O N G time coming, but gotta admit, excellent as always. This was the ONLY Pascal review to acknowledge and significantly include Kepler cards in the benchmarks and some comments. It makes sense to bench GK104 and analyze generational improvements since Kepler debuted 28nm and Pascal has finally ushered in the first node shrink since then. I guessed Anandtech would be the only site to do so, and looks like that's exactly what happened. Looking forward to the upcoming Polaris review!DonMiguel85 - Wednesday, July 20, 2016 - link
I do still wonder if Kepler's poor performance nowadays is largely due to neglected driver optimizations or just plain old/inefficient architecture. If it's the latter, it's really pretty bad with modern game workloads.ptown16 - Wednesday, July 20, 2016 - link
It may be a little of the latter, but Kepler was pretty amazing at launch. I suspect driver neglect though, seeing as how Kepler performance got notably WORSE soon after Maxwell. It's also interesting to see how the comparable GCN cards of that time, which were often slower than the Kepler competition, are now significantly faster.DonMiguel85 - Thursday, July 21, 2016 - link
Yeah, and a GTX 960 often beats a GTX 680 or 770 in many newer games. Sometimes it's even pretty close to a 780.hansmuff - Thursday, July 21, 2016 - link
This is the one issue that has me wavering for the next card. My AMD cards, the last one being a 5850, have always lasted longer than my NV cards; of course at the expense of slower game fixes/ready drivers.So far so good with a 1.5yrs old 970, but I'm keeping a close eye on it. I'm looking forward to what VEGA brings.
ptown16 - Thursday, July 21, 2016 - link
Yeah I'd keep an eye on it. My 770 can still play new games, albeit at lowered quality settings. The one hope for the 970 and other Maxwell cards is that Pascal is so similar. The only times I see performance taking a big hit would be newer games using asynchronous workloads, since Maxwell is poorly prepared to handle that. Otherwise maybe Maxwell cards will last much longer than Kepler. That said, I'm having second thoughts on the 1070 and curious to see what AMD can offer in the $300-$400 price range.