The iPhone 7 and iPhone 7 Plus Review: Iterating on a Flagshipby Joshua Ho & Brandon Chester on October 10, 2016 8:00 AM EST
- Posted in
- iOS 10
- iPhone 7
- iPhone 7 Plus
Section by Brandon Chester
At the heart of a smartphone lies the SoC. While there's now an increasingly common belief that specifications don't matter, the truth of the matter is that almost all of the software features that users now take for granted in a smartphone have only been made possible by the continued improvements in hardware performance. Modern smartphones with high resolution displays and complex interfaces would not exist if the available CPU and GPU processing power hadn't advanced as much as it has. On top of that, performance is something of a gating factor for software development, as the innovation that happens in software has to happen within the boundaries of what can be done with the hardware. Specifications in a smartphone actually matter quite a lot, even if the user isn't actively aware of all the individual components that make up their smartphone's SoC.
With the iPhone 7 Apple doesn't have the benefit of a new major process node to help improve performance. Any improvements will be the result of architectural improvements, as well as improvements that have been made to TSMC's 16nm process since the release of the Apple A9, which was Apple's first FinFET SoC. It's important to note that one of the goals of A10 Fusion is improving dynamic range, so the focus isn't solely on improving performance. However, device performance seemingly must improve with each generation, and Apple is advertising a 40% improvement in CPU performance and a 50% improvement in GPU performance with A10 Fusion compared to A9.
A10 Fusion's Floorplan (Special thanks to Chipworks)
While an in-depth look at A10 Fusion will have to wait until our seperate technology deep dive, we can still take a look at how performance has changed at a higher level. A10 Fusion's peak frequency is 2.3GHz, up from 1.8GHz on A9. This gives a theoretical improvement of 28% on its own, and the remainder will have to come from improvements to the architecture in Apple's (big) Hurricane cores. Based on our testing so far, Hurricane is not radically different from Twister (A9), but Apple has been making some optimizations. Meanwhile it should be noted that while A10 technically has four CPU cores – the two Hurricane cores and the two smaller cores – this is not a heterogeneous design, and only two cores are active at once. So for the purposes of high performance benchmarking, this means we're benchmarking the big cores nearly exclusively.
Anyhow, we've run our standard suite of benchmarks on the iPhone 7 and 7 Plus to see if A10 Fusion stands up Apple's performance claims.
I've brought back BaseMark OS II for this review, although unfortunately the reason has less to do with wanting it back in the benchmark suite and more to do with there being very few cross-platform general system benchmarks nowadays. You can focus on the GPU, or the CPU, but the major system performance benchmark in mobile is PCMark and it remains exclusive to Android. BaseMark OS II is a pretty large optimization target now, and while it does test many aspects of the system it doesn't do so by directly simulating the tasks that a user would perform. Despite that, it helps in getting a holistic view of a device's performance by going beyond tests of a single component, so it's not without its uses.
The iPhone 6s and 6s Plus have remained the fastest overall devices in this test, so it's really just a matter of seeing how much Apple has improved. The latest generation of Android devices outpaced the GPU performance Apple's A9 SoC some time ago, so that's one area where Apple could stand to improve against the competition. As it turns out, they have. The iPhone 7 and 7 Plus show significant gains over their predecessors across the board. Performance in the system sub-test is up by 25-30%, and the graphics score is right in line with Apple's claimed 50% increase in performance. Web shows similar gains to system, which makes sense given that both are relatively CPU-bound.
The memory/storage test also shows a large improvement, which is interesting at first glance given that Apple didn't highlight any improvements in this area. However, this is just the result of the tested units being the 256GB model. On my retail iPhone 7 which is 128GB the memory score is essentially the same as the iPhone 6s which was also tested in a 128GB configuration. This comes down to the fact that these devices use a hybrid SLC/TLC storage solution, where the SLC storage can be used for writes and data can be moved later as needed. It's likely that on the 128GB iPhones the BaseMark OS II memory test is exceeding the size of the SLC cache, leading to lower scores based on the performance of the TLC NAND. On the 256GB iPhone the SLC cache is large enough to fit the entire data set used in the test, leading to a much higher score.
WebXPRT is a small exception. As far as mobile benchmarks go, it's quite long and has short bursty workloads with pauses between each to simulate how a user would pause between different actions while using the browser. I suspect that in this case we're seeing the effects of A10 switching between its low power and high performance cores, causing parts of the test to be run on the little cores, which are not as performant. In fact, In the case of very quick actions that take only tenths or hundreths of a second to complete, it may not be possible to switch to the high performance cores before the operation has ended, causing the score to reflect the performance of the low power cores instead.
While it might seem reasonable to attribute the superior web performance of iOS devices to Apple's focus on improving single threaded CPU performance, the fact that Android devices with Cortex A72 CPUs are only matching Apple's A8 SoC shows that the gap is not only due to the CPU power available. Chrome's generally poor performance on Android is a significant limiting factor, and you can see in the chart how the improvement in Android device CPU performance over time has not translated into anything close to the sorts of gains that Apple has seen in the same period. While there are customized versions of Chromium like Snapdragon Browser that provide optimizations for a class of SoCs, it doesn't look like the gap between Android devices running Chrome and iOS devices running Mobile Safari is going to close any time soon, and if anything, it's only widening with each year.
Post Your CommentPlease log in or sign up to comment.
View All Comments
ex2bot - Wednesday, October 12, 2016 - linkApple claims ~25 hours total using the charging case (the Air Pods themselves have 5 hour life). That should be enough to get through the day
Meteor2 - Monday, October 10, 2016 - linkI think the big leap was 5->6. Since then not a lot has *noticeably* changed (I.e. outside the spec sheet).
Tams80 - Tuesday, October 11, 2016 - linkHow courageous.
I recently had to go back to a 5s. It's rather good.
techconc - Monday, October 10, 2016 - linkWhich SoCs are faster than the A10 and in what respect? Which phone has faster NAND storage than the iPhone 7? Cameras in Android systems have largely caught up, but are not universally accepted to be better. Yes, sensor size matters and that does help with detail, but so does color accuracy and overall ISP ability. I'd suggest they're more on par than you suggest.
CloudWiz - Monday, October 10, 2016 - link"faster in lots of aspects"
Hmm, maybe next year the SD830 or E8895 can finally start beating the iPhone 6 in single threaded performance.
"UFS 2.0 is comparable with Apple"
Sequential reads and writes in the 6s/7 are approximately twice as fast as the fastest UFS storage in androids. In randoms, everyone is about equal.
"have been better for a while"
Perhaps, to certain people, because over saturation is highly pleasing to the eye. But Apple has always remained relatively true to life, and being able to outperform many Android phones with much larger sensors is a testimony to their ISP.
"6S has better battery life"
The 6S has battery life barely comparable to the 6, while the 7 has battery life comparable to the SE, which lasts nearly 3 full hours longer than the 6S.
CloudWiz - Monday, October 10, 2016 - linkSlight correction: *get close to the 6s
menting - Monday, October 10, 2016 - linki like how you're cherry picking to compare.
jlabelle2 - Tuesday, October 11, 2016 - link"Sequential reads and writes in the 6s/7 are approximately twice as fast as the fastest UFS storage in androids. In randoms, everyone is about equal"
except that GSMArena tested the 32Go version as well, and it appears that the memopry is SIGNIFICANTLY slower. And that is an euphemism as the write spead appears 8 times slower and it showed a 4 times longer time to trim the same 4K video.
So only the 128Go version seems to be in line or slightly above the competition but the 32Go seems dog slow.
It would not be surprising of Apple, being cheap as usual.
steven75 - Wednesday, October 12, 2016 - linkPosted without a trace of irony considering Android manufacturers still can't beat the 2 years old iPhone 6 in CPU performance.
tuxRoller - Tuesday, October 11, 2016 - linkYeah, no.
Do you have evidence that there exists any android soc that is "faster" than these apple socs?