I don’t think there’s any way to sugarcoat this, but 2015 has not been a particularly great year for Qualcomm in the high-end SoC business. The company remains a leading SoC developer, but Snapdragon 810, the company’s first ARMv8 AArch64-capable SoC, did not live up to expectations. Seemingly held back by design matters and a rough 20nm planar manufacturing process – a problem shared by many vendors in the last year – Snapdragon 810 couldn’t make good use of its highly clocked ARM Cortex-A57 cores, and ultimately struggled in the face of SoCs built on better processes such as Samsung’s surprisingly early Exynos 7420.

But the purpose of today’s article isn’t to reminisce about the past, rather it’s to look towards the future. Qualcomm knows all too well what has happened in the past year and the cost to the company that has come from it, so now they need to dust themselves off and try again. With Samsung’s more advanced 14nm FinFET process in hand, a new CPU core, a new GPU, and a number of other advancements, Qualcomm is ready to try again; to try to recapture the good old days of 28nm and their Krait CPU architecture.

To that end Qualcomm started talking about Snapdragon 820 early and doing so loudly. Last month the company held their first press demonstration of the SoC, showcasing early demonstrations in action and going into more detail than ever before on their performance and power projections for their next-generation SoC.

If there is any unfortunate aspect to any of this, it’s that while Qualcomm is showing off Snapdragon 820 today, it won’t be ready for the holidays (lining up with what we expect will be the typical spring smartphone refreshes). But some of this is clearly driven by Qualcomm’s business needs and the aforementioned effort at Qualcomm to quickly pick themselves up and try again.

Meanwhile after last month’s demonstrations, this month Qualcomm is ready to move on to the next phase in what has become their traditional roll-out process for a new SoC: giving the press access to the company’s Mobile Development Platform (MDP) devices. Designed for software developers to begin building apps and (for lack of a better word) experiences around the new SoC, the MDP is something of the home-stretch in SoC development, as it means Qualcomm is ready to let the press and developers see the hardware and near-final software stack. We’ve previously previewed the Snapdragon 800, 805, and 810 via their MDPs, and for Snapdragon 820 Qualcomm has once again opted to do the same. So without further ado, let’s take our first look at Snapdragon 820.

Qualcomm Snapdragon S810 Specifications
SoC Snapdragon 820 Snapdragon 810 Snapdragon 800
CPU 2x Kryo@1.593GHz
512KB(?) L2 cache

2x Kryo@2.150GHz
1MB(?) L2 cache
4x A53@1.555GHz
512KB L2 cache

4x A57@1.958GHz
2MB L2 cache
4x Krait 400@2.45GHz
4x512KB L2 cache
Memory
Controller
2x 32-bit
LPDDR4 @ 1803MHz

28.8GB/s b/w
2x 32-bit
LPDDR4 @ 1555MHz

24.8GB/s b/w
2x 32-bit
LPDDR3 @ 933MHz

14.9GB/s b/w
GPU Adreno 530
@ 624MHz
Adreno 430
@ 600MHz
Adreno 330
@ 600MHz
Mfc.
Process
Samsung
14nm LPP
TSMC
20nm SoC
TSMC
28nm HPm

Taking a trek down to sunny San Diego, Qualcomm handed to us the Snapdragon 820 MDP/S. A 6.2” phablet, the MDP/S is a development kit designed for function over form, containing a full system implementation (sans cellular) in an otherwise utilitarian design. Along with the Snapdragon 820 SoC, the 820 MDP/S also includes a 6.2” 2560x1600 display, 3GB of LPDDR4 memory runnning at a slightly higher 1804MHz instead of 1555MHz we've seen on the Snapdragon 810 and Exynos 7420, a 64GB Universal Flash Storage package, a 21MP rear camera, 802.11ac WiFi, and a Sense ID ultrasonic fingerprint scanner. Overall the aesthetics of the MDP/S differs significantly from what retail phones will go for, but internally the MDP/S won’t be far removed from the kinds of configurations we’ll see in 2016 smartphones.

Overall there’s little to report on the MDP/S experience itself. Qualcomm is still sorting out some driver bugs – only one device in our group was ready to run PCMark – and to be sure like past Qualcomm MDP previews this is very much a preview. However the experience was otherwise unremarkable (in a good way) with our unit completing all of our tests bar part of SPEC CPU 2000, which will require further analysis.

More interesting from a testing perspective is that Qualcomm opted to demonstrate Snapdragon 820 using the MDP/S smartphone development kit, instead of a larger MDP/T tablet development kit. Qualcomm has used MDP/T for the press demonstrations on both Snapdragon 800 and Snapdragon 810, so the fact that they are once again using the MDP/S is very notable. From a pure performance perspective the MDP/T allowed Qualcomm to show off previous Snapdragon designs at their best – these are just performance previews, after all – but after Snapdragon 810 I don’t doubt that had this been another MDP/T that the 820’s thermals and power consumption would be called into question. So instead we are looking at 820 in a phablet, and while this may not put 820 in the best possible light, the end result is that we get to see what performance in a large phone looks like, and for Qualcomm there isn’t any doubt about 820’s suitability for a smartphone.

As for Snapdragon 820 itself, we’ve already covered the SoC in some depth in past articles – and this week’s preview doesn’t come with much in the way of new architectural information – but here’s a quick recap of what we know so far. 820 uses a new Qualcomm developed CPU core called Kryo. The quad core CPU is best described as an HMP solution with two high-performance cores clocked at 2150 MHz and two low-power cores clocked at 1593MHz. The CPU architectures of both clusters are identical, but with differences in cache configuration and their power/frequency tuning.

Meanwhile the GPU inside 820 is the Adreno 530. This is a next-generation design from Qualcomm and includes functionality that until now has only been found in PC desktops, such as shared virtual memory with the CPU, which allows an OpenCL host program and a device's kernel to share a virtual address space so access to data structures like lists and trees can be easily shared between the host and GPU. The underlying architecture is capable of Renderscript and OpenCL 2.0 on the compute side – a significant step up from Adreno 400 – and on the graphics side supports OpenGL ES 3.1 + AEP and Vulkan. We know the 530 should be powerful, but like past Qualcomm designs the company is saying virtually nothing about the underlying architecture.

Finally, while it’s not something that can be covered in our brief testing, the 820 contains a new DSP block, the Hexagon 680. Hexagon 680 and its Hexagon Vector Extensions (HVX) are designed to handle significant compute workloads for image processing applications such as virtual reality, augmented reality, image processing, video processing, and computer vision. This means that tasks that might otherwise be running on a relatively power hungry CPU or GPU can run a comparatively efficient DSP instead. The HVX has 1024-bit vector data registers, with the ability to address up to four of these slots per instruction, which allows for up to 4096 bits per cycle.

CPU Performance: Meet Kryo
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  • Impulses - Friday, December 11, 2015 - link

    Your backwards interpretation of what he said is the only weird thing. Reply
  • ganz - Friday, December 11, 2015 - link

    Thanks @tipoo and @jjj. It's just that I see people posting stuff like, "The device get [sic] unnaturally hot." I parse this complaint to mean, "Ow, my hand!", not, "Dang, why so slow?"

    I think yours is the valid complaint, but what I keep reading are comments like @Krysto's here. And I still think @Krysto and others are actually complaining about the device becoming uncomfortable to hold.

    My meaning is this: "Quantify your complaint, @Krysto" If it's *really* the heat (really?), how hot is too hot? If it's the performance, maybe say so.
    Reply
  • extide - Thursday, December 10, 2015 - link

    Supporting the SHA1 instructions is part of being ARMv 8 compliant -- it's not really their choice... Reply
  • lilmoe - Thursday, December 10, 2015 - link

    On the first chart, the memory controller stack of the 820 should be 64bit dual channel. Reply
  • tipoo - Thursday, December 10, 2015 - link

    Mixed feels. A move away from the frankly bad Cortex A57 cores, cool. But you could pretty well tell from the very first page that this was set to punch below A9, coudn't you? Longer latencies on float, int, 1/3rd the L2, no L3 at all. And particularly as a big.LITTLE design that means less sharing between high power/low power core clusters.

    And unlike S810, there's 2, not 4, "big" cores to at least make up for the lackluster IPC 810 had compared to A9.

    Just think their aim wasn't high enough...Again...
    Reply
  • r3loaded - Thursday, December 10, 2015 - link

    Oi, don't slate the A57! Those cores run beautifully in Samsung's Exynos 7 without overheating or throttling, and performance of that SoC is broadly comparable to the A8.

    Integration and implementation are just as important as the initial selection of IP blocks for an SoC.
    Reply
  • tuxRoller - Thursday, December 10, 2015 - link

    You're forgetting that Samsung had a rather significant process advantage. Take that away, and they'd need to lower their clocks to sd808 levels, is imagine. Reply
  • Andrei Frumusanu - Thursday, December 10, 2015 - link

    The Exynos 5433 runs quite better than the Snapdragon 808. Reply
  • tuxRoller - Thursday, December 10, 2015 - link

    According to wikipedia it's clocked at 1.9ghz, which is right around the snapdragon 808. Reply
  • lilmoe - Friday, December 11, 2015 - link

    He's not talking about clock speeds. He's talking about the whole package. Samsung has lots more experience with big.LITTLE and their implementations are far superior than competing chips on the SAME process node. Both the Exynos 5433 and the Snapdragon 808 are built on 20nm, yet the Exynos performs AND sustains its performance better than the Snapdragon. Reply

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