One of the stories bubbling away in the background of the industry is the AMD self-imposed ‘25x20’ goal. Starting with performance in 2014, AMD committed to itself, to customers, and to investors that it would achieve an overall 25x improvement in ‘Performance Efficiency’ by 2020, which is a function of raw performance and power consumption. At the time AMD was defining its Kaveri mobile product as the baseline for the challenge – admittedly a very low bar – however each year AMD has updated us on its progress. With this year being 2020, the question on my lips ever since the launch of Zen2 for mobile was if AMD had achieved its goal, and if so, by how much? The answer is yes, and by a lot.

In this article we will recap the 25x20 project, how the metrics are calculated, and what this means for AMD in the long term.

Renoir 2020: New Silicon, Goal Achieved

The announcement today from AMD confirms the company has reached its goal of 25x performance efficiency by the end of 2020, starting from the Kaveri baseline. Here’s the important graph:

As we can see using this metric, there were big jumps from Kaveri to Carrizo, Bristol Ridge to Raven Ridge, then a series of stagnation over Zen/Zen+, before finally a bump up to Renoir. This gives three distinct jumps:

  • Kaveri to Carrizo was 3.5x,
  • Bristol to Raven was 2.2x,
  • then Picasso to Renoir was 2.92x

The base value for AMD’s goal is on its Kaveri mobile processors, which by the standards of today set a very low bar. As AMD moved to Carrizo, it implemented new power monitoring features on chip that allowed the system to offer a better distribution of power and ran closer to the true voltage needed, not wasting power. After Carrizo came Bristol Ridge, still based on the older cores, but used a new DDR4 controller as well as lower powered processors that were better optimized for efficiency.

A big leap came with Raven Ridge, with AMD combining its new highly efficient Zen x86 cores and Vega integrated graphics. This heralded a vast improvement in performance due to doubling the cores and improving the graphics, all within a similar power window as Bristol Ridge. This boosted up the important 25x20 metric and keeping it well above the ‘linear’ gain.

From 2017-2019, this was ultimately a lull in AMD’s strategy, namely because there were no significant design changes. The versions of 2017/2018 Raven Ridge come down to slight SKU differences used for the metric, but ultimately when it came time to measure the systems AMD was a little out of cycle here. Moving from Raven Ridge to Picasso was a shift from using GlobalFoundries 14nm to 12nm, which affords a slight power gain but not so much on the performance. Going from 2017 to 2019 still yielded a 23.5% gain within the same product family, mainly due to minor manufacturing updates and better binning or power algorithms. It was around the Picasso time when OEM’s started taking AMD’s notebook platform more seriously, especially as the lead up to 2020’s Renoir.

The jump from Picasso to Renoir has been well documented. Our first use of the CPUs, reviewed in the ASUS Zephyrus G14, left us with our mouths open, almost literally. We called it a ‘Mobile Revival’, showcasing  AMD’s transition over from Zen+ to Zen2, from GF 12nm to TSMC 7nm, along with a lot of strong design and optimization on the graphics side. The changes from the 2019 to the 2020 chip include doubling the core count, from four to eight, improving the clock-for-clock performance by 15-20%, but also improving the graphics performance and frequencies despite moving down from an silicon design that had 11 compute units down to 8. This comes in line with a number of power updates, adhering to AHCI specifications, and as we discussed with Sam Naffziger, AMD Fellow, supporting the new S0ix low power states has helped tremendously. The reduction in the fabric power, along with additional memory bandwidth, offered large gains.

The jump from Picasso to Renoir is 2.92x, taking AMD to 31.77x over the original target. Goal achieved, and kudos to AMD’s teams that have succeeded at this ambitious target.

How did AMD define how the target will be measured? That’s in the fine print.

Calculating X: Get Me Some X Factor

AMD calls the value it calculates as X, defined as the ratio between a performance metric C and an efficiency metric E. In 2017, it gave detailed notes on how it calculates these values:

  1. Overall performance efficiency X is C divided by E
  2. Performance C is a 50:50 average pf CPU and GPU performance compared to Kaveri
     - CPU Performance from Cinebench R15 nT Score
     - GPU Performance from 3DMark 11 P Score
  3. Energy Use E is defined by ETEC 'Typical Energy Consumption from Notebooks' as per Energy Star Program Requirements, Rev 6.1 Oct-2014
  4. Kaveri is the baseline where X = 1

The secret sauce is based on how you calculate C and E. The headline equation is as stated above:

The compute metric C is relatively easy to understand. Here AMD takes the 50-50 weighted average of CPU and GPU performance with the Cinebench R15 multi-threaded test and 3D Mark 11 P full benchmark.

Using Kaveri as a base result of 1.0, Carrizo scores 1.23, Bristol Ridge scores 1.36, and Raven Ridge 2017 scored 2.47 etc.

The efficiency metric E is vastly more complicated. It relies on a ‘typical energy use’ model defined by ETEC Energy Star program that adds weights based on sleep power, idle power, and some loading power. The equation looks a little like this:

The PT(x) options are the power consumed in those modes. The main thing to bring up about this metric is that it ends up being highly dependent on the device or laptop the processor is being used in. If you want the best result, you need a device that has a low powered, preferably low resolution but efficient display, a small efficient SSD, as few controllers as possible, and as much thermal headroom as possible. The best environment becomes this odd hybrid of premium components but low specifications.

For this metric AMD uses their internal reference platforms, which is often based on one of the first devices to launch with the new product. This is where we initially believe that AMD’s improvements kick in – the first devices in 2017 with Raven Ridge were, not to sugar coat it, rather middle-of-the-road. As reported by our sister website Laptop Mag, the HP Envy x360 with Raven Ridge was a repurposed chassis from HP’s catalogue, rather than something hyper optimized. It is likely that AMD’s reference design mirrors this unit a lot, as AMD and HP work very close together. But clearly room for some improvement.

For those keeping track, again the base line for this value is referred back to Kaveri. Kaveri also sets a low bar here, being a 19W TDP processor to begin with, and Carrizo improved the metric a lot through its much more optimized power monitoring and delivery. The goal here is for a lower value, so while Kaveri scored a value of E of 1.00 as the baseline, Carrizo was 0.35, Bristol Ridge was 0.34, and Raven Ridge was 0.28, and also gave double the performance of Bristol Ridge. When it came time to Renoir 2020, performance was +75% over Picasso 2019, but also offered 40% lower power as measured by this metric, giving that 2.92x overall gain.

For anyone wondering, the equation for the ‘goal’ line approximates to:

The Final Data

For this disclosure, AMD has given us all the data as collected. We had to have a couple of emails back and forth, because some of the data that AMD provided was different to what it had given us in previous 25x20 disclosures – beyond that, there was some mathematical errors in a number of places. AMD took some time to reconfirm the correct numbers, and admitted that in light of some of the issues I’d found, previous data may have been incorrect as well (at one point they had moved a data point from a 19W CPU to a 35W CPU, among other issues).

With that being said, here are all the platforms that AMD has used for the 25x20 goal:

AMD 25x20 Systems
  CPU uArch Base/
Turbo
GPU
CUs
GPU
Freq
DDR
Freq
TDP
Kaveri
2014
FX-7600P 2 x
Steamroller
2700
3600
8 x R7 686 2 x 4 GB
DDR3L-1600
35 W
Carrizo
2015
FX-8800P 2 x
Excavator
2100
3400
8 x R7 800 2 x 2 GB
DDR3-1866
35 W
Bristol
2016
FX-9830P 2 x
Excavator+
3000
3700
8 x R7 900 2 x 4 GB
DDR4-2133
35 W
Raven
2017
Ryzen 7
2700U
4 x
Zen
2200
3800
Vega10 1300 2 x 4 GB
DDR4-2400
15 W
Raven
2018
Ryzen 7
2800H
4 x
Zen
3300
3800
Vega11 1300 2 x 8 GB
DDR4-3200
35 W
Picasso
2019
Ryzen 7
3750H
4 x
Zen+
2300
4000
Vega10 1400 2 x 8 GB
DDR4-2400
35 W
Renoir
2020
Ryzen 7
4800H
8 x
Zen2
2900
4200
Vega8 1600 2 x 8 GB
DDR4-3200
35 W

Note that some of these platforms are not running at their standard TDP designations. This was done for unity across the performance years (which explains some variance in the results over the years), with Raven Ridge 2017 being the sole 15 W data point due to where the product stack was at the time. The Ryzen 7 4800H, used for the Renoir testing, was run in 35W mode (essentially a 4800HS).

And here are the raw results, with the key columns highlighted:

AMD 25x20 Scores
AnandTech CB
R15 nT
3DM11 Compute
(C)
ETEC Energy
(E)
Performance
Efficiency (X)
Kaveri 2014 232 2142 1.00 0.931 1.00 1.00x
Carrizo 2015 277 2709 1.23 0.327 0.35 3.50x
Bristol 2016 279 3234 1.36 0.318 0.34 3.97x
Raven 2017 667 4425 2.47 0.261 0.28 8.81x
Raven 2018 754 4877 2.76 0.261 0.28 9.86x
Picasso 2019 772 5191 2.88 0.246 0.26 10.88x
Renoir 2020 1727 5546 5.02 0.147 0.16 31.77x

Overall AMD has achieved a 5.02x performance gain with a 6.33x idle efficiency, which the company is wrapping up into a combined 31.77x performance efficiency metric.

In speaking with AMD’s Sam Naffziger, he mentioned that when this project started, the company had created what it assumed would be the year-on-year targets for both the CPU and the GPU. Ultimately in 2014 AMD was very big on the heterogenous system architecture, attempting to meld GPU compute in with the CPU. While GPU acceleration has made it into some aspects of a standard laptop-style device, it perhaps isn’t as ubiquitous as was originally envisioned, however the ultimate end-point ended up being a distinct CPU and GPU gain anyway. Sam told me that based on those original targets back in 2014/2015, AMD exceeded his projects in CPU by some considerable margin, which offset some of the GPU projections.

Sam mentioned that one of the key elements to helping achieve this metric was the work AMD has done in idle power management, which has a direct consequence on standard laptop use battery life. Because the 'efficiency' part of the calculation is heavliy weighted towards idle, decreasing the latency for a CPU to enter and exit a turbo mode helps a machine power to idle quicker. Also, optimizing the voltage characteristics of what defines an idle state amd supporting the S0ix power states was also a big leap in that metric. The ACPI standards have helped define some of that roadmap, and some of the requirements imposed by Microsoft in order to enable certain features have driven the design forward.

AMD and x86 vs Arm

As an aside, I did want to get Sam’s thoughts on how AMD is approaching the increasing competition from Arm based designs. Note that we had this briefing well before Apple announced its recent news. Sam stated that Arm designs still have to push both frequency and performance at the high-end, which is going to require some extensive work. He pointed to the tribal knowledge of driving x86 at high-performance and at scale – although he did concede that Arm’s partners have a number of impressive core and SoC designs, and they are keeping tabs on what that market is doing. On top of the core work, Arm’s partners still have the ISA/software porting task, and architecture transitions have to enable significant benefits and lots of investment to be taken advantage of. Sam’s point of view is that AMD has no intention of letting any advantage materialize from the Arm space, and aim to stay several steps ahead at all times. Sam was keen to point out that he believes competition is healthy, and not to dismiss Arm, but to acknowledge that AMD aims to be ahead of the curve if any competition does arise.

‘The Next Five Years Are Going To Be Fun’

At this point I asked Sam if AMD has a similar goal to 25x20 in mind for the next 5-10 years. He was admittedly coy, saying that there is another efficiency goal in the plan, however it would be applied in a much broader context, especially with how the world has changed when it comes to compute requirements. Such a goal would consider a number of performance aspects, perhaps relating to AI acceleration, but also go beyond notebooks into the desktop and the server space – these markets have different performance/energy co-optimization efforts. Sam stated that ultimately AMD plans to focus on what matters most to end-users, what drives to lower energy consumption, and what can offer impressive environmental gains in the future.

I was told that AMD is not going to sit on its laurels any time soon, regardless of where it sits in the competitive landscape. The goal of projects like 25x20 is to create paradigm shifts, either internally or externally, to drive a level of continuous innovation by pushing boundaries. ‘The next five years are going to be fun’, Sam said.

AMD also highlighted its work with TSMC on 7nm, with Sam stating that without it, achieving the goal would not have been possible. Back when the project first started, there wasn’t a clear indication of what TSMC’s 7nm was going to perform like, but by being an early TSMC partner and going deep into design and technology co-optimization, AMD has been able to extract what they need from the process – without that work, Sam predicts that AMD would have barely hit 20x in its performance efficiency goal. Going forward, AMD plan to continue to be lead partners on upcoming process node technologies.

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  • CajunArson - Thursday, June 25, 2020 - link

    How to achieve your goal: Start with a dumpster fire like Kaveri as the baseline. Relative improvements are easy when you can set the bar beneath ground level.
  • mjz_5 - Thursday, June 25, 2020 - link

    thats the CPU they had at the time
  • quadibloc - Wednesday, July 15, 2020 - link

    Indeed, and it also means that it can't be expected that they will improve by another factor of 25 in the next five years. That and the fact that it's getting more challenging to get process improvements past 7nm.
  • Sahrin - Thursday, June 25, 2020 - link

    It's not just "25x faster" - it's power efficiency as well.

    Compared with June 2014 competition, Kaveri socred 235 on r15nt, and Haswell-U scored 291.

    AMD took that CPU from 2014, and soundly beats Comet Lake with its successor - in *both* power *and* performance.
  • Alistair - Thursday, June 25, 2020 - link

    exactly
  • CajunArson - Thursday, June 25, 2020 - link

    Compared to Tiger Lake that is allegedly on an "inferior" process I'm not particularly impressed by anything that AMD has done in mobile at all. That includes blatantly superior GPU performance and CPU parity even in most multi-threaded workloads. On top of that I don't see USB 4.0 anywhere in AMD's mobile stack (or anywhere else).

    When you consider that 90% of the improvements being attributed to AMD are really due to simply not using GloFo as a foundry, it really comes into focus that Moore's law isn't really that dead and AMD gets to ride on the coattails of other companies.
  • PixyMisa - Thursday, June 25, 2020 - link

    Tiger Lake doesn't exist yet. Neither does USB 4.0.

    And AMD created an entirely new design and applied it to everything from laptops to high-end servers while Intel was putting out its fourth respin of Skylake.
  • close - Monday, June 29, 2020 - link

    CajunArson already thoroughly tested a Tiger Lake platform and was positively flabbergasted by the performance, especially when combined with the USB4 devices they had around. They also have those rare GloFo manufactured Ryzens that performed so poorly that the only conclusion is that TSMC's manufacturing makes up 104% of the reasons for Ryzen 4000 series performance. They're basically just K6-2s with slightly smaller wires and whatnot inside. The Intel offering is also cheaper I'm sure.

    In the meantime in the real world all we have to judge Tiger Lake is Intel's own marketing. While this may very well turn out to be accurate at this time it's coming from the same company that was demoing seemingly incredible frequencies to gullible journalists not seeing through the smoke, mirrors, and 1HP chillers just a short while back. Also it's comparing a CPU that is "coming soon" to one that's been on the market for months now. Why not compare it to Cézanne (Zen 3 + RDNA2) if we're comparing future products?

    Through the magic of the internet and anonymity we get to hear some dope talk with such certainty about some stuff they don't know or understand but heard a rumor.
  • GigaFlopped - Friday, June 26, 2020 - link

    Are you telling me a future product may be faster than a something currently available? Shock, isn’t that which way tech is supposed to go? Also, you’re a bit clueless if you ask me, first of all, Intel 10nm is equivalent to TSMC 7nm, secondly, they don’t have to rely on multi core count at all, they are in fact currently ahead in IPC with a comparable CPU clocked at the same speed, ironically, it’s actually Intels 14nm fab that’s allowed Intel to be competitive, allowing very high clock speeds.

    So let’s look at the here and now, the 4900hs CPU beats every mobile CPU Intel has, at 35w, only when you push the Intel chips to 90w do they start to become competitive, this is a fact, as per every review site. The 4000u series, they’ve managed to place double the amount of cores at the same TDP as Intel, even their 10nm parts and nearly double the performance.

    Yet you’re down playing their achievements and banging on about some unreleased Intel part beating their current crop of CPUs. You sound like a very ignorant Intel fan.
  • brantron - Friday, June 26, 2020 - link

    Uh...AMD does use Global Foundry. This is one of the most confused comments I think I've ever seen lol.

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