Adrian Silasi – SiSoftware

Intel Core Gen10 CometLake ULV (i7-10510U) Review & Benchmarks – CPU Performance

By Adrian Silasi | 17th October 2019 - 10:48 am |17th October 2019 Reviews

What is “CometLake”?

It is one of the 10th generation Core arch (CML) from Intel – the latest revision of the venerable (6th gen!) “Skylake” (SKL) arch; it succeeds the “WhiskyLake”/”CofeeLake” 8/9-gen current architectures for mobile (ULV U/Y) devices. The “real” 10th generation Core arch is “IceLake” (ICL) that does bring many changes but has not made its mainstream debut yet.

As a result there ar no major updates vs. previous Skylake designs, save increase in core count top end versions and hardware vulnerability mitigations which can still make a big difference:

Up to 6C/12T (from 4C/8T WhiskyLake/CoffeeLake or 2C/4T Skylake/KabyLake)
Increase Turbo ratios
2-channel LP-DDR4 support and DDR4-2667 (up from 2400)
WiFi6 (802.11ax) AX201 integrated (from WiFi5 (802.11ac) 9560)
Thunderbolt 3 integrated
Hardware fixes/mitigations for vulnerabilities (“Meltdown”, “MDS”, various “Spectre” types)

The 3x (three times) increase in core count (6C/12T vs. Skylake/KabyLake 2C/8T) in the same 15-28W power envelope is pretty significant considering that Core ULV designs since 1st gen have always had 2C/4T; unfortunately it is limited to top-end thus even i7-10510U still has 4C/8T.

LP-DDR4 support is important as many thin & light laptops (e.g. Dell XPS, Lenovo Carbon X1, etc.) have been “stuck” with slow LP-DDR3 memory instead of high-bandwidth DDR4 memory in order to save power. Note the Y-variants (4.5-6W) will not support this.

WiFi is now integrated in the PCH and has been updated to WiFi6/AX (2×2 streams, up to 2400Mbps with 160MHz-wide channel) from WiFi5/AX (1733Mbps); this also means no simple WiFi-card upgrade in the future as with older laptops (except those with “whitelists” like HP, Lenovo, etc.)

Why review it now?

Until “IceLake” makes its public debut, “CometLake” latest ULV APUs from Intel you can buy today; despite being just a revision of “Skylake” due to increased core counts/Turbo ratios they may still prove worthy competitors not just in cost but also performance.

As they contain hardware fixes/mitigations for vulnerabilities discovered since original “Skylake” has launched, the operating system & applications do not need to deploy slower mitigations that can affect performance (especially I/O) on the older designs.

In this article we test CPU core performance; please see our other articles on:

Intel Core Gen10 CometLake ULV (i7-10510U) Review & Benchmarks – Cache & Memory Performance

Hardware Specifications

We are comparing the top-of-the-range Intel ULV with competing architectures (gen 8, 7, 6) as well as competiors (AMD) with a view to upgrading to a mid-range but high performance design.

CPU Specifications	AMD Ryzen2 2500U Bristol Ridge	Intel i7 7500U (Kabylake ULV)	Intel i7 8550U (Coffeelake ULV)	Intel Core i7 10510U (CometLake ULV)	Comments
Cores (CU) / Threads (SP)	4C / 8T	2C / 4T	4C / 8T	4C / 8T	N0 change in cores count on i3/i5/i7.
Speed (Min / Max / Turbo)	1.6-2.0-3.6GHz	0.4-2.7-3.5GHz	0.4-1.8-4.0GHz (1.8 @ 15W, 2GHz @ 25W)	0.4-1.8-4.9GHz (1.8GHz @ 15W, 2.3GHz @ 25W)	CML has +22% faster turbo.
Power (TDP)	15-35W	15-25W	15-35W	15-35W	Same power envelope.
L1D / L1I Caches	4x 32kB 8-way / 4x 64kB 4-way	2x 32kB 8-way / 2x 32kB 8-way	4x 32kB 8-way / 4x 32kB 8-way	4x 32kB 8-way / 4x 32kB 8-way	No L1 changes
L2 Caches	4x 512kB 8-way	2x 256kB 16-way	4x 256kB 16-way	4x 256kB 16-way	No L2 changes
L3 Caches	4MB 16-way	4MB 16-way	6MB 16-way	6MB 16-way	And no L3 changes
Microcode (Firmware)	MU8F1100-0B	MU068E09-8E	MU068E09-AE	MU068E0C-BE	Revisions just keep on coming.

Native Performance

We are testing native arithmetic, SIMD and cryptography performance using the highest performing instruction sets (AVX2, AVX, etc.). “CometLake” (CML) supports all modern instruction sets including AVX2, FMA3 but not AVX512 (like “IceLake”) or SHA HWA (like Atom, Ryzen).

Results Interpretation: Higher values (GOPS, MB/s, etc.) mean better performance.

Environment: Windows 10 x64, latest AMD and Intel drivers. 2MB “large pages” were enabled and in use. Turbo / Boost was enabled on all configurations.

Native Benchmarks		AMD Ryzen2 2500U Bristol Ridge	Intel i7 7500U (Kabylake ULV)	Intel i7 8550U (Coffeelake ULV)	Intel Core i7 10510U (CometLake ULV)	Comments

	Native Dhrystone Integer (GIPS)	103	73.15	125	134 [+8%]	CML starts off 7% faster than CFL a good start.
	Native Dhrystone Long (GIPS)	102	74.74	115	135 [+17%]	With a 64-bit integer workload – increases to 17%.
	Native FP32 (Float) Whetstone (GFLOPS)	79	45	67.29	84.95 [+26%]	With floating-point workload CML is 26% faster!
	Native FP64 (Double) Whetstone (GFLOPS)	67	37	57	70.63 [+24%]	With FP64 we see a similar 24% improvement.
With integer (legacy) workloads, CML-U brings a modest improvement of about 10% over CFL-U, cementing its top position. But with floating-points (also legacy) workloads we see a larger 25% increase which allows it to beat the competition (Ryzen Mobile) that was beating older designs (CFL-U, WHL-U, KBL-U, etc.)

	Native Integer (Int32) Multi-Media (Mpix/s)	239	193	306	409 [+34%]	In this vectorised AVX2 integer test CML-U is 34% faster than CFL-U.
	Native Long (Int64) Multi-Media (Mpix/s)	53.4	75	117	149 [+27%]	With a 64-bit AVX2 integer workload the difference drops to 27%.
	Native Quad-Int (Int128) Multi-Media (Mpix/s)	2.41	1.12	2.21	2.54 [+15%]	This is a tough test using Long integers to emulate Int128 without SIMD; here CML-U is still 15% faster.
	Native Float/FP32 Multi-Media (Mpix/s)	222	160	266	328 [+23%]	In this floating-point AVX/FMA vectorised test, CML-U is 23% faster.
	Native Double/FP64 Multi-Media (Mpix/s)	127	94.8	155.9	194.4 [+25%]	Switching to FP64 SIMD code, nothing much changes still 20% slower.
	Native Quad-Float/FP128 Multi-Media (Mpix/s)	6.23	4.04	6.51	8.22 [+26%]	In this heavy algorithm using FP64 to mantissa extend FP128 with AVX2 – we see 26% improvement.
With heavily vectorised SIMD workloads CML-U is 25% faster than previous CFL-U that may be sufficient to see future competition from Gen3 Ryzen Mobile with improved (256-bit) SIMD units, something that CFL/WHL-U may not beat. IcyLake (ICL) with AVX512 should improve over this despite lower clocks.

	Crypto AES-256 (GB/s)	10.9	7.28	13.11	12.11 [-8%]	With AES/HWA support all CPUs are memory bandwidth bound.
	Crypto AES-128 (GB/s)	10.9	9.07			–
	Crypto SHA2-256 (GB/s)	6.78	2.55	3.97	4.28 [+8%]	Without SHA/HWA Ryzen Mobile beats even CML-U.
	Crypto SHA1 (GB/s)	7.13	4.07			Less compute intensive SHA1 allows CML-U to catch up.
	Crypto SHA2-512 (GB/s)	1.48	1.54			SHA2-512 is not accelerated by SHA/HWA CML-U does better.
The memory sub-system is crucial here, and CML-U can improve over older designs when using faster memory (which we were not able to use here). Without SHA/HWA supported by Ryzen Mobile, it cannot beat it and improves marginally over older CFL-U.

	Black-Scholes float/FP32 (MOPT/s)	93.34	49.34	73.02		With non vectorised CML-U needs to cath up.
	Black-Scholes double/FP64 (MOPT/s)	77.86	43.33	75.24	87.17 [+16%]	Using FP64 CML-U is 16% faster finally beating Ryzen Mobile.
	Binomial float/FP32 (kOPT/s)	35.49	12.3	16.2		Binomial uses thread shared data thus stresses the cache & memory system.
	Binomial double/FP64 (kOPT/s)	19.46	11.4	19.31	20.99 [+9%]	With FP64 code CML-U is 9% faster than CFL-U.
	Monte-Carlo float/FP32 (kOPT/s)	20.11	9.87	14.61		Monte-Carlo also uses thread shared data but read-only thus reducing modify pressure on the caches.
	Monte-Carlo double/FP64 (kOPT/s)	15.32	7.88	14.54	16.54 [+14%]	Switching to FP64 nothing much changes, CML-U is 14% faster.
With non-SIMD financial workloads, CML-U modestly improves (10-15%) over the older CFL-U but this does allow it to beat the competition (Ryzen Mobile) which dominated older CFL-U designs. This may just be enough to match future Gen3 Ryzen Mobile and thus be competitive all-round.

	SGEMM (GFLOPS) float/FP32	107	76.14	141		In this tough vectorised AVX2/FMA algorithm.
	DGEMM (GFLOPS) double/FP64	47.2	31.71	55	69.2 [+26%]	With FP64 vectorised code, CML-U is 26% faster than CFL-U.
	SFFT (GFLOPS) float/FP32	3.75	7.21	13.23		FFT is also heavily vectorised (x4 AVX2/FMA) but stresses the memory sub-system more.
	DFFT (GFLOPS) double/FP64	4	3.95	6.53	7.35 [+13%]	With FP64 code, CML-U is 13% faster.
	SNBODY (GFLOPS) float/FP32	112.6	105	160		N-Body simulation is vectorised but with more memory accesses.
	DNBODY (GFLOPS) double/FP64	45.3	30.64	57.9	64.16 [+11%]	With FP64 code nothing much changes.
With highly vectorised SIMD code (scientific workloads) CML-U is again 15-25% faster than CFL-U which should be enough to match future Gen3 Ryzen Mobile with 256-bit SIMD units. Again we need ICL with AVX512 to bring dominance to these workloads or more cores.

	Blur (3×3) Filter (MPix/s)	532	474	720	891 [+24%]	In this vectorised integer AVX2 workload CML-U is 24% faster.
	Sharpen (5×5) Filter (MPix/s)	146	191	290	359 [+24%]	Same algorithm but more shared data still 24%.
	Motion-Blur (7×7) Filter (MPix/s)	123	98.3	157	186 [+18%]	Again same algorithm but even more data shared reduces improvement to 18%.
	Edge Detection (2*5×5) Sobel Filter (MPix/s)	185	164	251	302 [+20%]	Different algorithm but still AVX2 vectorised workload still 20% faster.
	Noise Removal (5×5) Median Filter (MPix/s)	26.49	14.38	25.38	27.73 [+9%]	Still AVX2 vectorised code but here just 9% faster.
	Oil Painting Quantise Filter (MPix/s)	9.38	7.63	14.29	15.74 [+10%]	Similar improvement here of about 10%.
	Diffusion Randomise (XorShift) Filter (MPix/s)	660	764	1525	1580 [+4%]	With integer AVX2 workload, only 4% improvement.
	Marbling Perlin Noise 2D Filter (MPix/s)	94,16	105.1	188.8	214 [+13%]	In this final test again with integer AVX2 workload CML-U is 13% faster.

Without any new instruction sets (AVX512, SHA/HWA, etc.) support, CML-U was never going to be a revolution in performance and has to rely on clock and very minor improvements/fixes (especially for vulnerabilities) only. Versions with more cores (6C/12T) would certainly help if they can stay within the power limits (TDP/turbo).

Intel themselves did not claim a big performance improvement – still CML-U is 10-25% faster than CFL-U across workloads – at same TDP. At the same cost/power, it is a welcome improvement and it does allow it to beat current competition (Ryzen Mobile) which was nipping at its heels; it may also be enough to match future Gen3 Ryzen Mobile designs.

SiSoftware Official Ranker Scores

Intel Core i7-10510U

Final Thoughts / Conclusions

For some it may be disappointing we do not have brand-new improved “IceLake” (ICL-U) now rather than a 3-rd revision “Skylake” – but “CometLake” (CML-U) does seem to improve even over the previous revisions (8/9th gen “WhiskyLake”/”CofeeLake” WHL/CFL-U) while due to 2x core count completly outperforming the original (6/7th gen “Skylake”/”KabyLake”) in the same power envelope. Perhaps it also shows how much Intel has had to improve at short notice due to Ryzen Mobile APUs (e.g. 2500U) that finally brought competition to the mobile space.

While owners of 8/9-th gen won’t be upgrading – it is very rare to recommend changing from one generation to another anyway – owners of older hardware can look forward to over 2x performance increase in most workloads for the same power draw, not to mention the additional features (integrated WiFi6, Thunderbolt, etc.).

On the other hand, the competition (AMD Ryzen Mobile) also good performance and older 8/9th gen also offer competitive performance – thus it will all depend on price. With Gen3 Ryzen Mobile on the horizon (with 256-bit SIMD units) “CometLake” may just manage to match it on performance. It may also be worth waiting for “IceLake” to make its debut to see what performance improvements it brings and at what cost – which may also push “CometLake” prices down.

All in all Intel has managed to “squeeze” all it can from the old Skylake arch that while not revolutionary, still has enough to be competitive with current designs – and with future 50% increase core count (6C/12T from 4C/8T) might even beat them not just in cost but also in performance.

In a word: Qualified Recommendation!

Please see our other articles on:

Intel Core Gen10 CometLake ULV (i7-10510U) Review & Benchmarks – Cache & Memory Performance

SiSoftware Sandra 20/20 (2020) SP1 Released

By Adrian Silasi | 2nd October 2019 - 4:05 pm |17th October 2019 Releases, Updates

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We are pleased to release SP1 (version 30.20) update for 20/20 (2020) with the following updates:

Sandra 20/20 (2020) Press Release

Hardware Support:
- AMD Ryzen2 (Matisse), Stoney Ridge updated support
- Intel CometLake (CML), CannonLake (CNL), IceLake (ICL) updated support

CPU Benchmarks:
- Tools (Visual C++ compiler 142) Update

GPGPU Benchmarks:
- CUDA SDK 10.1 Updated
- OpenCL: Updated SDK support

Reviews using Sandra 20/20:

Update & Download

Commercial version customers can download the free updates from their software distributor; Lite users please download from your favourite download site.

Download Sandra Lite

AMD Radeon 5700XT: Navi GPGPU Performance in OpenCL

By Adrian Silasi | 7th August 2019 - 2:42 am |30th August 2019 Reviews

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What is “Navi”?

It is the code-name of the new AMD GPU, the first of the brand-new RDNA (Radeon DNA) GPU arch(itecture) – replacing the “Vega” that was the last of the GCN (graphics core next) arch(itecture). It is a mid-range GPU optimised for gaming thus not expected to set records, but GPUs today are used for many other tasks (mining, encoding, algorithm/compute acceleration, etc.) as well.

RDNA arch brings big changes from the various GCN revisions we’ve seen previously, but its first iteration here does not bring any major new features at least in the compute domain. Hopefully the next versions will bring tensor units (matrix multiplicators) and other accelerated instruction sets and so on.

See these other articles on GPGPU performance:

Hardware Specifications

We are comparing the middle-range Radeon with previous generation cards and competing architectures with a view to upgrading to a mid-range high performance design.

GPGPU Specifications	AMD Radeon 5700XT (Navi)	AMD Radeon VII (Vega2)	nVidia Titan X (Pascal)	AMD Radeon 56 (Vega1)	Comments
Arch Chipset	RDNA / Navi 10	GCN5.1 / Vega 20	Pascal / GP102	GCN5.0 / Vega 10	The first of the Navi chips.
Cores (CU) / Threads (SP)	40 / 2560	60 / 3840	28 / 3584	56 / 3584	Less CUs than Vega1 and same (64x) SP per CU.
SIMD per CU / Width	2 / 32 [2x]	4 / 16	–	4 / 16	Navi increases the SIMD width but decreases counts.
Wave/Warp Size	32 [1/2x]	64	32	64	Wave size is reduced to match nVidia.
Speed (Min-Turbo)	1.6 / 1.755	1.4 / 1.75	1.531 / 1.91	1.156 / 1.471	40% faster base and 20% turbo than Vega 1.
Power (TDP)	225W	295W	250W	210W	Slightly higher TDP but nothing significant
ROP / TMU	64 / 160	64 / 240	96 / 224	64 / 224	ROPs are the same but we see ~30% less TMUs.
Shared Memory	64kB [+2x]	32kB	48kB / 96kB per SM	32kB	We have 2x more shared memory allowing bigger kernels.
Constant Memory	4GB	8GB	64kB dedicated	4GB	No dedicated constant memory but large.
Global Memory	8GB GDDR6 14Gt/s 256-bit	16GB HBM2 1Gt/s 4096-bit	12GB GDDR5X 10Gt/s 384-bit	8GB HBM2 900Gt/s 4096-bit	Sadly no HBM this time but the faster but not very wide.
Memory Bandwidth (GB/s)	448GB/s [+9%]	1024GB/s	512GB/s	410GB/s	Still bandwidth is 9% higher.
L1 Caches	? x40	16kB x60	48kB x28	16kB x56	L1 does not appear changed but unclear.
L2 Cache	4MB	4MB	3MB	4MB	L2 has not changed.
Maximum Work-group Size	1024 / 1024	256 / 1024	1024 / 2048 per SM	256 / 1024	AMD has unlocked work-group sizes to 4x.
FP64/double ratio	1/16x	1/4x	1/32x	1/16x	Ratio is same as consumer Vega1 rather than pro Vega2.
FP16/half ratio	2x	2x	1/64x	2x	Ratio is the same throughout.

Processing Performance

We are testing both OpenCL performance using the latest SDK / libraries / drivers from both AMD and competition.

Results Interpretation: Higher values (GOPS, MB/s, etc.) mean better performance.

Environment: Windows 10 x64, latest AMD and nVidia drivers. Turbo / Boost was enabled on all configurations.

Processing Benchmarks		AMD Radeon 5700XT (Navi)	AMD Radeon VII (Vega2)	nVidia Titan X (Pascal)	AMD Radeon 56 (Vega1)	Comments

	Mandel FP16/Half (Mpix/s)	18,265 [-7%]	29,057	245	19,580	Navi starts well but cannot beat Vega1.
	Mandel FP32/Single (Mpix/s)	11,863 [-13%]	17,991	17,870	13,550	Standard FP32 increases the gap to 13%.
	Mandel FP64/Double (Mpix/s)	1,047 [-16%]	5,031	661	1,240	FP64 does not change much, Navi is 16% slower.
	Mandel FP128/Quad (Mpix/s)	43 [-45%]	226	25	77	Emulated FP128 is hard on FP64 units and here Navi is almost 1/2 Vega1.
Starting up, Navi does not seem to be able to beat Vega1 in heavy vectorised compute loads with FP16 most efficient (almost parity) while complex FP128 is 2x slower.

	Crypto AES-256 (GB/s)	51 [-25%]	91	42	67	Despite more bandwidth Navi is 25% slower than Vega1.
	Crypto AES-128 (GB/s)			58	88	–

	Crypto SHA2-256 (GB/s)	176 [+40%]	209	145	125	Navi shows its power here beating Vega1 by a huge 40%!
	Crypto SHA1 (GB/s)			107	162	–
	Crypto SHA2-512 (GB/s)			76	32	–
Despite more bandwidth of GDDR6, streaming algorithms work better on on “old” HBM2 thus Navi cannot beat Vega. But in pure integer compute algorithms like hashing, it is much faster by a significant amount which bodes well for the future.

	Black-Scholes float/FP32 (MOPT/s)	12,459 [+31%]	23,164	11,480	9,500	In this FP32 financial workload Navi is 30% faster than Vega1!
	Black-Scholes double/FP64 (MOPT/s)		7,272	1,370	1,880	–
	Binomial float/FP32 (kOPT/s)	850 [1/3x]	3,501	2,240	2,530	Binomial uses thread shared data thus stresses the memory system and here we have some optimisation to do.
	Binomial double/FP64 (kOPT/s)		789	129	164	–
	Monte-Carlo float/FP32 (kOPT/s)	5,027 [+30%]	6,249	5,350	3,840	Monte-Carlo also uses thread shared data but read-only thus reducing modify pressure – here Navi is again 30% faster.
	Monte-Carlo double/FP64 (kOPT/s)		1,676	294	472	–
For financial FP32 workloads, Navi is ~30% faster than Vega1 – a pretty good improvement – though it naturally cannot compete with Vega2 due to consumer multiplier (1/16x). Crypto-currencies fans will love the Navi.

	SGEMM (GFLOPS) float/FP32	5,165 [+2%]	6,634	6,073	5,066	GEMM can only bring a measly 2% improvement over Vega1.
	DGEMM (GFLOPS) double/FP64		2,339	340	620	–
	SFFT (GFLOPS) float/FP32	376 [+2%]	643	235	369	FFT loves HBM but Navi is still 2% faster.
	DFFT (GFLOPS) double/FP64		365	207	175	–
	SNBODY (GFLOPS) float/FP32	4,534 [-6%]	6,846	5,720	4,840	Navi can’t manage as well in N-Body and ends up 6% slower.
	DNBODY (GFLOPS) double/FP64		1,752	275	447	–
The scientific scores don’t show the same improvement as the financial ones likely due to heavy use of shared memory with Navi just matching Vega1. Perhaps the larger shared memory can allow us to use larger workgroups.

	Blur (3×3) Filter single/FP32 (MPix/s)	8,674 [1/2.1x]	25,418	18,410	19,130	In this 3×3 convolution algorithm, Navi is 1/2x the speed of Vega1.
	Sharpen (5×5) Filter single/FP32 (MPix/s)	1,734 [1/3x]	5,275	5,000	4,340	Same algorithm but more shared data makes Navi even slower.
	Motion Blur (7×7) Filter single/FP32 (MPix/s)	1,802 [1/2.5x]	5,510	5,080	4,450	With even more data the gap remains at 1/2.5x.
	Edge Detection (2*5×5) Sobel Filter single/FP32 (MPix/s)	1,723 [1/2.5x]	5,273	4,800	4,300	Still convolution but with 2 filters – same 1/2.5x performance.
	Noise Removal (5×5) Median Filter single/FP32 (MPix/s)	48.44 [=]	92.53	37	48	Different algorithm allows Navi to tie with Vega1.
	Oil Painting Quantise Filter single/FP32 (MPix/s)	97.34 [+2.5x]	57.66	12.7	38	Without major processing, this filter performs well on Navi.
	Diffusion Randomise (XorShift) Filter single/FP32 (MPix/s)	32,050 [+1.5x]	47,349	19,480	20,880	This algorithm is 64-bit integer heavy and Navi is 50% faster than Vega1.
	Marbling Perlin Noise 2D Filter single/FP32 (MPix/s)	9,516 [+1.6x]	7,708	305	6,000	One of the most complex and largest filters, Navi is again 50% faster.
For image processing using FP32 precision, Navi goes from 1/2.5x Vega1 performance (convolution) to 50% faster (complex algorithms with integer processing). It seems some optimisations are needed for the convolution algorithms.

Memory Performance

We are testing both OpenCL performance using the latest SDK / libraries / drivers from AMD and competition.

Results Interpretation: For bandwidth tests (MB/s, etc.) high values mean better performance, for latency tests (ns, etc.) low values mean better performance.

Environment: Windows 10 x64, latest AMD and nVidia. drivers. Turbo / Boost was enabled on all configurations.

Memory Benchmarks		AMD Radeon 5700X (Navi)	AMD Radeon VII (Vega2)	nVidia Titan X (Pascal)	AMD Radeon 56 (Vega1)	Comments

	Internal Memory Bandwidth (GB/s)	376 [+13%]	627	356	333	Navi’s GDDR6 manages 13% more bandwidth than Vega1.
	Upload Bandwidth (GB/s)	21.56 [+77%]	12.37	11.4	12.18	PCIe 4.0 brings almost 80% more bandwidth
	Download Bandwidth (GB/s)	22.28 [+84%]	12.95	12.2	12.08	Again almost 2x more bandwidth.
Navi’s PCIe 4.0 interface (on 500-series motherboards) brings as expected almost 2x more upload/download bandwidth while its high-clocked GDDR6 manages just over 10% higher bandwidth over HBM2.

	Global (In-Page Random Access) Latency (ns)	276 [+11%]	202	201	247	Navi’s GDDR6 brings slight latency increase (+10%)
	Global (Full Range Random Access) Latency (ns)		341	286	353	–
	Global (Sequential Access) Latency (ns)			89.8	115	–
	Constant Memory (In-Page Random Access) Latency (ns)			117	237	–
	Shared Memory (In-Page Random Access) Latency (ns)			18.7	55	–
	Texture (In-Page Random Access) Latency (ns)			195	193	–
	Texture (Full Range Random Access) Latency (ns)			282	301	–
	Texture (Sequential Access) Latency (ns)			87.6	80	–
Not unexpected, GDDR6′ latencies are higher than HBM2 although not by as much as we were fearing.

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

“Navi” is an interesting chip to be sure and perhaps more was expected of it; as always the drivers are the weak link and it is hard to determine which issues will be fixed driver-side and which will need to be optimised in compute kernels.

Thus performance-wise it oscillates between 1/2x and 50% Vega1 performance depending on algorithm, with compute-heavy algorithms (especially crypto-currencies) doing best and shared/local memory heavy algorithms doing worst. The 2x bigger shared memory (64kB vs 32) in conjunction with the larger work-group (1024 vs 256 by default) sizes do present future optimisation opportunities. AMD has also reduced the warp/wave size to match nVidia – a historic change.

Memory wise, the cost-cutting change from HBM2 to even high-speed GDDR6 does bring more bandwidth but naturally higher latencies – but PCIe 4.0 doubles upload/download bandwidths which will become much more important on higher capacity (16GB+) cards in the future.

Overall it is hard to recommend it for compute workloads unless the particular algorithm (crypto, financial) does well on Navi, otherwise the much older Vega1 56/64 offer better performance/cost ratio especially today. However, as drivers mature and implementations are optimised for it, Navi is likely to start to perform better.

We are looking forward to the next iterations of Navi, especially the rumoured “big Navi” version optimised for compute…

AMD Radeon VII: Vega2 GPGPU Performance in OpenCL

By Adrian Silasi | 1st August 2019 - 12:13 pm |8th August 2019 Reviews

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What is “Vega2”?

It is the code-name of the updated “Vega” GPU arch(itecture), the last of the GCN (graphics core next) arch (version 5.1) shrinked to 7nm before being replaced by the forthcoming “Navi”. Originally for the professional/workstation high-end market, “Vega2″/”big Vega” designed for compute (scientific, machine learning, etc.) workloads was pressed into service to battle the latest 2000-series “Turing”/RTX competition.

As a result it contains many high-end features not normally found on consumer cards:

1/4 FP64 rate (instead of 1/16 or worse)
16GB HBM2 memory (instead of 8-12)
4096-bit HBM2 memory 1TB/s bandwidth (instead of 400-500)
Int8/Int4 support for AI/ML workloads
PCIe 4.0 capable but not enabled at this time

See these other articles on GPGPU performance:

Hardware Specifications

We are comparing the middle-range Radeon with previous generation cards and competing architectures with a view to upgrading to a mid-range high performance design.

GPGPU Specifications	AMD Radeon VII (Vega2)	nVidia Titan V (Volta)	nVidia Titan X (Pascal)	AMD Vega 56 (Vega1)	Comments
Arch Chipset	Vega 20 / GCN 5.1	GV100 / 7.0	GP102 / 6.1	Vega 10 / GCN 5.0	A minor revision of Vega1.
Cores (CU) / Threads (SP)	60 / 3840	80 / 5120	28 / 3584	56 / 3584	More CUs than normal Vega but not 64.
SIMD per CU / Width	4 / 16	n/a	n/a	4 / 16	Naturally same SIMD count and width
Wave/Warp Size	64	32	32	75	Wave size has always been 2x nVidia.
Speed (Min-Turbo)	1.4 – 1.750 [+21%]	(135-1455)	1.531 (139-1910)	1.156 – 1.471	Base clock is ~20% higher and turbo
Power (TDP)	300W [+42%]	300W	250W	210W	TDP has gone up by 40%.
ROP / TMU	64 / 256	96 / 320	96 / 224	64 /	ROPs and TMUs unchanged
Shared Memory	32kB	48 / 96 kB	48 / 96kB	32kB	No shared memory change.
Constant Memory	8GB	64kB	64kB	4GB	No dedicated constant memory but large.
Global Memory	16GB HBM2 2Gbps 4096-bit	12GB HBM2 2x850Mbps 3072-bit	12GB GDDR5X 10Gbps 384-bit	8GB HBM2 1.89Gbps 2048-bit	2x as big and 2x as wide HBM a huge improvement.
Memory Bandwidth (GB/s)	1000 [+2.4x]	652	512	410	Still bandwidth is 9% higher.
L1 Caches	16kB x 60	96kB x 80	48kB x 28	16kB x 56	L1 has not changed.
L2 Cache	4MB	4.5MB	3MB	4MB	L2 has not changed.
Maximum Work-group Size	256 / 1024	1024 / 2048	1024 / 2048	256 / 1024	Same work-group sizes.
FP64/double ratio	1/4x	1/2x	1/32x	1/16x	Ratio is 4x better than Vega1.
FP16/half ratio	2x	2x	1/64x	2x	Ratio is the same throughout.

Processing Performance

We are testing both OpenCL performance using the latest SDK / libraries / drivers from both AMD and competition.

Results Interpretation: Higher values (GOPS, MB/s, etc.) mean better performance.

Environment: Windows 10 x64, latest AMD and nVidia drivers. Turbo / Boost was enabled on all configurations.

Processing Benchmarks		AMD Radeon VII (Vega2)	nVidia Titan V (Volta)	nVidia Titan X (Pascal)	AMD Vega 56 (Vega1)	Comments

	Mandel FP16/Half (Mpix/s)	29,057 [+48%]	33,860	245	19,580	Vega2 starts strong with a 48% lead over Vega1 and almost catching Volta.
	Mandel FP32/Single (Mpix/s)	18,340 [+35%]	22,680	17,870	13,550	Good improvement here +35% over Vega1 again close to Volta.
	Mandel FP64/Double (Mpix/s)	5,377 [+4.3x]	11,000	661	1,240	1/4 FP64 rate makes it over four (4x) times faster than Vega1.
	Mandel FP128/Quad (Mpix/s)	234 [+3x]	458	25.77	77	Similar to above, Vega2 is over three (3x) faster.
Vega2 looks about 35-50% faster than Vega1 in FP32/FP16 and 3-4x faster in FP64 due to its 1/4 FP64 rate. It won’t beat real workstation cards with 1/2 FP64 rate through thus that Titan has nothing to worry about.

	Crypto AES-256 (GB/s)	91 [+36%]	70	42	67	The fast HBM2 memory allows it to beat even Volta not just Vega1.
	Crypto AES-128 (GB/s)		93	58	88	–

	Crypto SHA2-256 (GB/s)	209 [+67%]	245	145	125	Vega2 is a huge 70% faster in integer/crypto workloads.
	Crypto SHA1 (GB/s)		129	107	162	–
	Crypto SHA2-512 (GB/s)		176	76	32	–
Vega2 increases its lead in integer workloads even streaming ones no doubt due to its very fast HBM2 memory making it the crypto-king of the hill though its cost may be an issue.

	Black-Scholes float/FP32 (MOPT/s)	23,164 [+2.3x]	18,570	11,480	9,500	Vega2 is over 2x faster than Vega1 also beating Volta.
	Black-Scholes double/FP64 (MOPT/s)	7,272 [+3.84x]	8,400	1,370	1,880	In FP64 its almost 4x faster just below Volta!
	Binomial float/FP32 (kOPT/s)	3,501 [+38%]	4,200	2,240	2,530	Binomial uses thread shared data thus stresses the memory system Vega2 is still 40% faster.
	Binomial double/FP64 (kOPT/s)	789 [+4.8x]	2,000	129	164	With FP64 we’re almost 5x faster than Vega1.
	Monte-Carlo float/FP32 (kOPT/s)	6,249 [+62%]	11,920	5,350	3,840	Monte-Carlo also uses thread shared data but read-only thus reducing modify pressure – here Vega2 is 60% faster.
	Monte-Carlo double/FP64 (kOPT/s)	1,676 [+3.55x]	4,440	294	472	With FP64 we’re over 3.5x faster.
For financial FP32 workloads, Vega2 is 40-60% faster than Vega1 a decent improvement; naturally in FP64 it’s 4-5x times faster thus a significant upgrade for algorithms that require such precision.

	SGEMM (GFLOPS) float/FP32	6,634 [+30%]	11,000	6,073	5,066	GEMM still brings a 30% improvement over Vega1.
	DGEMM (GFLOPS) double/FP64	2,339 [+3.77x]	3,830	340	620	But DGEMM is almost 4x faster.
	SFFT (GFLOPS) float/FP32	643 [+74%]	617	235	369	FFT loves HBM thus Vega2 is 75% faster.
	DFFT (GFLOPS) double/FP64	365 [+2.1x]	280	207	175	DFFT is tough but Vega2 is still twice as fast.
	SNBODY (GFLOPS) float/FP32	6,846 [+41%]	7,790	5,720	4,840	In N-Body physics Vega2 is 40% faster.
	DNBODY (GFLOPS) double/FP64	1,752 [+3.9x]	4,270	275	447	And in FP64 physics Vega2 is almost 4x faster.
The scientific scores show a similar improvement, with FP32 30-40% better but FP64 a whopping four (4x) faster than Vega1 and, in some algorithms, matching the hugely expensive Volta.

	Blur (3×3) Filter single/FP32 (MPix/s)	25,418 [+32%]	26,790	18,410	19,130	In this 3×3 convolution algorithm, Vega2 is 32% faster than Vega1
	Sharpen (5×5) Filter single/FP32 (MPix/s)	5,275 [+21%]	9,295	5,000	4,340	Same algorithm but more shared data reduces the lead to 21%.
	Motion Blur (7×7) Filter single/FP32 (MPix/s)	5,510 [+24%]	9,428	5,080	4,450	With even more data the gap remains constant.
	Edge Detection (2*5×5) Sobel Filter single/FP32 (MPix/s)	5,273 [+23%]	9,079	4,800	4,300	Still convolution but with 2 filters – similar 23% faster.
	Noise Removal (5×5) Median Filter single/FP32 (MPix/s)	92 [+91%]	112	37	48	Different algorithm makes Vega2 almost 2x faster than Vega1.
	Oil Painting Quantise Filter single/FP32 (MPix/s)	57 [+50%]	42	12.7	38	Without major processing, this filter is 50% faster on Vega2.
	Diffusion Randomise (XorShift) Filter single/FP32 (MPix/s)	47,349 [+2.3x]	24,370	19,480	20,880	This algorithm is 64-bit integer heavy and Vega2 flies 2x faster than Vega1.
	Marbling Perlin Noise 2D Filter single/FP32 (MPix/s)	7,708 [+28%]	8,460	305	6,000	One of the most complex and largest filters, Vega2 is 28% faster.
For image processing using FP32 precision, Vega goes from 21% to 2x faster, overall a decent improvement if you are processing a large number of images. In many filters it beats the far more expensive Volta competition.

Memory Performance

We are testing both OpenCL performance using the latest SDK / libraries / drivers from AMD and competition.

Results Interpretation: For bandwidth tests (MB/s, etc.) high values mean better performance, for latency tests (ns, etc.) low values mean better performance.

Environment: Windows 10 x64, latest AMD and nVidia. drivers. Turbo / Boost was enabled on all configurations.

Memory Benchmarks		AMD Radeon VII (Vega2)	nVidia Titan V (Volta)	nVidia Titan X (Pascal)	AMD Vega 56 (Vega1)	Comments

	Internal Memory Bandwidth (GB/s)	627 [+88%]	536	356	333	Vega2’s wide HBM2 is almost 2x faster as expected.
	Upload Bandwidth (GB/s)	12.37 [+2%]	11.47	11.4	12.18	Using PCIe 3.0 similar upload bandwidth.
	Download Bandwidth (GB/s)	12.95 [+7%]	12.27	12.2	12.08	Again similar bandwidth.
Vega2 benefits greatly from its very wide HBM2 memory (4096-bit) which provides almost 2x real bandwidth as expected. But while PCIe 4.0 capable for now it has to make do with 3.0 and thus same upload/download bandwith. Here’s hoping for a BIOS update once new motherboards come out.

	Global (In-Page Random Access) Latency (ns)	202 [-19%]	180	201	247	The higher clock allows Vega2 a 20% latency reduction.
	Global (Full Range Random Access) Latency (ns)	341 [-4%]	311	286	353	Full range is only 4% faster.
	Global (Sequential Access) Latency (ns)		53.4	89.8	115	–
	Constant Memory (In-Page Random Access) Latency (ns)		75.4	117	237	–
	Shared Memory (In-Page Random Access) Latency (ns)		18.1	18.7	55	–
	Texture (In-Page Random Access) Latency (ns)		212	195	193	–
	Texture (Full Range Random Access) Latency (ns)		344	282	301	–
	Texture (Sequential Access) Latency (ns)		88.5	87.6	80	–
Not unexpected, GDDR6′ latencies are higher than HBM2 although not by as much as we were fearing.

SiSoftware Official Ranker Scores

AMD Radeon VII

Final Thoughts / Conclusions

Vega2 (“BigVega”) is a big improvement over normal Vega1 and its workstation-class pedigree shows. For FP16/Fp32 workloads though the 30-40% performance improvement may not be worth it considering the much higher price: naturally FP64 performance is almost 4x due to 1/4 FP64 rate though not as good at professional cards with 1/2 rate or Titan competition with similar 1/2 rate.

While the GCN core (rev 5.1) has seen internal updates, there is nothing new that can be supported/optimised for in the compute land thus any code working well on Vega1 should work just as well on Vega2.

The 16GB HBM2 wide memory also helps big workloads with 2x higher bandwidth and also lower latency due to higher clock. For some workloads this alone makes it a definite buy when competition stops at 12GB.

Unfortunately the card has had a limited release at a relatively high price thus value/price ratio depends entirely on your workload – if FP64 with large datasets then it is very much worth it; if FP32/FP16 with datasets that fit in standard 8GB memory then the older Vega1 is much better value and you can even get 2 for the price of the Vega2.

For revolutionary change we need to wait for Navi and its brand new RDNA (Radeon DNA) arch(itecture)…

SiSoftware Sandra 20/20 (2020) Released!

By Adrian Silasi | 18th July 2019 - 12:00 am |17th October 2019 Releases

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FOR IMMEDIATE RELEASE

Contact: Press Office

SiSoftware Sandra 20/20 (2020) Released:
Brand-new benchmarks (AI/ML), hardware support

Updates: SP1.

London, UK, July 18th, 2019 – We are pleased to announce the launch of SiSoftware Sandra 20/20 (2020), the latest version of our award-winning utility, which includes remote analysis, benchmarking and diagnostic features for PCs, servers, mobile devices and networks.

It adds two Neural Networks AI/ML (Artificial Intelligence/Machine Learning) benchmarks for both CPU and GP (GPU) to measure both CNN (Convolution Neural Network) & RNN (Recurrent Neural Networks) performance on modern hardware.

It also adds hardware support and optimisations for brand-new CPU architectures (AMD Ryzen 2 (3000 series); Intel IceLake, CometLake) not forgetting GPGPU architectures across the various interfaces (CUDA, OpenCL, DirectX ComputeShader, OpenGL Compute).

As SiSoftware operates a “just-in-time” release cycle, some features were introduced in Sandra 2017 service packs: in Sandra Titanium they have been updated and enhanced based on all the feedback received.

Broad Operating System Support

All current versions supported: Windows 10, 8.1*, 8*, 7*; Server 2019, 2016, 2012/R2 and 2008/R2*

Brand new AI/ML benchmarks featuring both CNN & RNN networks testing both inference/forward and training/back-propagation performance.

	Processor Neural Networks (AI/ML) A combined performance index of CNN (inference/forward & training) & RNN (inference/forward & training) for all precisions (single/FP32, double/FP64 floating-point) and instruction sets (AVX512, AVX2/FMA, AVX, SSE4, SSE2, RTM/HLE with NUMA and large-page support) Ranker: Processor Neural Networks (Normal/Single Precision) Ranker: Processor Neural Networks (High/Double Precision)
	GP (GPU) Neural Networks (AI/ML) A combined performance index of CNN (inference/forward & training) & RNN (inference/forward & training) for all precisions (half/FP16, single/FP32 floating-point) and platforms (CUDA, OpenCL, DirectX Compute) GP (GPU) Neural Networks (Normal/Single Precision) GP (GPU) Neural Networks (Low/Half Precision)
	CNN (Convolution Neural Network) Architecture Detailed document on the CNN architecture, data-sets and results that underpin our choices for the new benchmarks. The new Neural Networks (AI/ML) Benchmarks: CNN Architecture
	RNN (Recurrent Neural Network) Architecture Detailed document on the RNN architecture, data-sets and results that underpin our choices for the new benchmarks. The new Neural Networks (AI/ML) Benchmarks: RNN Architecture

Major changes

All connections to website engines (Ranker, Information, Price) are now secured by SSL through HTTP.
Sandra client (management console) is now installed as native 64-bit (on x64 and arm64) and thus needs 64-bit Access components (2016, 2013, 2010, etc.) or SQL Server (2017, 2016, 2014, etc) for its database.

Key features of Sandra 20/20

4 native architectures support (x86, x64, ARM64** – Windows; ARM, ARM64, x86, x64 – Android)
Huge official hardware support through technology partners (AMD/ATI, nVidia, Intel).
4 native (GP)GPU/APU platforms support (OpenCL 2.1+, CUDA 10.1+, DirectX Compute Shader 11/10+, OpenGL Compute 4.5+, Vulkan 1.0+).
4 native Graphics platforms support (DirectX 11.x/10.x, OpenGL 4.0+, Vulkan 1.0+).
9 language versions (English, German, French, Italian, Spanish, Japanese, Chinese (Traditional, Simplified), Russian) in a single installer.
Enhanced Sandra Lite (Eval) version (free for personal/educational use, evaluation for other uses)

Articles & Benchmarks

For more details, please see the following articles:

Purchasing

For more details, and to purchase the commercial versions, please click here.

Updating or Upgrading

To update your existing commercial version, please click here.

Downloading

For more details, and to download the Lite (Evaluation) version, please click here.

Reviewers and Editors

For your free review copies, please contact us.

About SiSoftware

SiSoftware, founded in 1995, is one of the leading providers of computer analysis, diagnostic and benchmarking software. The flagship product, known as “SANDRA”, was launched in 1997 and has become one of the most widely used products in its field. Many worldwide IT publications, magazines and review sites use SANDRA to analyse the performance of today’s computers. Thousands on-line reviews of computer hardware that use SANDRA are catalogued on our website alone.

Since launch, SiSoftware has always been at the forefront of the technology arena, being among the first providers of benchmarks that show the power of emerging new technologies such as multi-core, GPGPU, OpenCL, OpenGL, DirectCompute, x64, ARM64, ARM, NUMA, SMT (Hyper-Threading), SMP (multi-threading), AVX512, AVX2/FMA3, AVX, NEON/2, SSE4.2/4, SSSE3, SSE2, SSE, Java and .NET.

SiSoftware is located in London, UK. For more information, please visit www.sisoftware.net, www.sisoftware.eu, or www.sisoftware.co.uk

AMD Ryzen2 3700X Review & Benchmarks – CPU 8-core/16-thread Performance

By Adrian Silasi | 17th July 2019 - 1:46 am |17th July 2019 Reviews

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What is “Ryzen2” ZEN2?

AMD’s Zen2 (“Matisse”) is the “true” 2nd generation ZEN core on 7nm process shrink while the previous ZEN+ (“Pinnacle Ridge”) core was just an optimisation of the original ZEN (“Summit Ridge”) core that while socket compatible it introduces many design improvements over both previous cores. An APU version (with integrated “Navi” graphics) is scheduled to be launched later.

While new chipsets (500 series) will also be introduced and required to support some new features (PCIe 4.0), with an BIOS/firmware update older boards may support them thus allowing upgrades to existing systems adding more cores and thus performance. [Note: older boards will not be enabled for PCIe 4.0 after all]

The list of changes vs. previous ZEN/ZEN+ is extensive thus performance delta is likely to be very different also:

Built around “chiplets” of up to 2 CCX (“core complexes”) each of 4C/8T and 8MB L3 cache (7nm)
Central I/O hub with memory controller(s) and PCIe 4.0 bridges connected through IF (“Infinity Fabric”) (12nm)
Up to 2 chiplets on desktop platform thus up to 2x2x4C (16C/32T 3950X) (same amount as old ThreadRipper 1950X/2950X)
2x larger L3 cache per CCX thus up to 2x2x16MB (64MB) L3 cache (3900X+)
24 PCIe 4.0 lanes (2x higher transfer rate over PCIe 3.0)
2x DDR4 memory controllers up to 4266Mt/s

To upgrade from Ryzen+/Ryzen1 or not?

Micro-architecturally there are more changes that should improve performance:

256-bit (single-op) SIMD units 2x Fmacs (fixing a major deficiency in ZEN/ZEN+ cores)
TLB (2nd level) increased (should help out-of-page access latencies that are somewhat high on ZEN/ZEN+)
Memory latencies claim to be reduced through higher-speed memory (note all requests go through IF to Central I/O hub with memory controllers)
Load/Store 32bytes/cycle (2x ZEN/ZEN+) to keep up with the 256-bit SIMD units (L1D bandwidth should be 2x)
L3 cache is 2x ZEN/ZEN+ but higher latency (cache is exclusive)
Infinity Fabric is 512-bit (2x ZEN/ZEN+) and can run 1x or 1/2x vs. DRAM clock (when higher than 3733Mt/s)
AMD processors have thankfully not been affected by most of the vulnerabilities bar two (BTI/”Spectre”, SSB/”Spectre v4″) that have now been addressed in hardware.
HWM-P (hardware performance state management) transitions latencies reduced (ACPI/CPPCv2)

In this article we test CPU core performance; please see our other articles on:

Hardware Specifications

We are comparing the middle-of-the-range Ryzen2 (3700X) with previous generation Ryzen+ (2700X) and competing architectures with a view to upgrading to a mid-range high performance design.

CPU Specifications	AMD Ryzen 9 3900X (Matisse)	AMD Ryzen 7 3700X (Matisse)	AMD Ryzen 7 2700X (Pinnacle Ridge)	Intel i9 9900K (Coffeelake-R)	Intel i9 7900X (Skylake-X)	Comments
Cores (CU) / Threads (SP)	12C / 24T	8C / 16T	8C / 16T	8C / 16T	10C / 20T	Core counts remain the same.
Topology	2 chiplets, each 2 CCX, each 3 cores (1 disabled) (12C)	1 chiplet, 2 CCX, each 4 cores (8C)	2 CCX, each 4 cores (8C)	Monolithic die	Monolithic die	1 chiplet+1 sio rather than 1 die
Speed (Min / Max / Turbo)	3.8 / 4.6GHz	3.6 / 4.4GHz	3.7 / 4.2GHz	3.6 / 5GHz	3.3 / 4.3GHz	3700x base clock is lower than 2700x but turbo is higher
Power (TDP / Turbo)	105 / 135W	65 / 90W	105 / 135W	95 / 135W	140 / 308W	TDP has been greatly reduced vs. ZEN+
L1D / L1I Caches	12x 32kB 8-way / 12x 32kB 8-way	8x 32kB 8-way / 8x 32kB 8-way	8x 32kB 8-way / 8x 64kB 4-way	8x 32kB 8-way / 8x 32kB 8-way	10x 32kB 8-way / 10x 32kB 8-way	L1I has been halved but better no. ways
L2 Caches	12x 512kB (6MB) 8-way	8x 512kB (4MB) 8-way	8x 512kB (4MB) 8-way	8x 256kB (2MB) 16-way	10x 1MB (10MB) 16-way	No changes to L2
L3 Caches	2x2x 16MB (64MB) 16-way	2x 16MB (32MB) 16-way	2x 8MB (16MB) 16-way	16MB 16-way	13.75MB 11-way	L3 is 2x ZEN+
Mitigations for Vulnerabilities	BTI/”Spectre”, SSB/”Spectre v4″ hardware	BTI/”Spectre”, SSB/”Spectre v4″ hardware	BTI/”Spectre”, SSB/”Spectre v4″ software/firmware	RDCL/”Meltdown”, L1TF hardware, BTI/”Spectre”, MDS/”Zombieload”, software/firmware	RDCL/”Meltdown” , L1TF, BTI/”Spectre”, MDS/”Zombieload”, all software/firmware	Ryzen2 addresses the remaining 2 vulnerabilities while Intel was forced to add MDS to its long list…
Microcode	MU-8F7100-11	MU-8F7100-11	MU-8F0802-04	MU-069E0C-9E	MU-065504-49	The latest microcodes included in the respective BIOS/Windows have been loaded.
SIMD Units	256-bit AVX/FMA3/AVX2	256-bit AVX/FMA3/AVX2	128bit AVX/FMA3/AVX2	256-bit AVX/FMA3/AVX2	512-bit AVX512	ZEN2 SIMD units are 2x wider than ZEN+

Native Performance

We are testing native arithmetic, SIMD and cryptography performance using the highest performing instruction sets (AVX2, FMA3, AVX, etc.). Ryzen2 supports all modern instruction sets including AVX2, FMA3 and even more like SHA HWA but not AVX-512.

Results Interpretation: Higher values (GOPS, MB/s, etc.) mean better performance.

Environment: Windows 10 x64, latest AMD and Intel drivers. 2MB “large pages” were enabled and in use. Turbo / Boost was enabled on all configurations. All mitigations for vulnerabilities (Meltdown, Spectre, L1TF, MDS, etc.) were enabled as per Windows default where applicable.

Native Benchmarks		AMD Ryzen 7 3700X (Matisse)	AMD Ryzen 7 2700X (Pinnacle Ridge)	Intel i9 9900K (Coffeelake-R)	Intel i9 7900X (Skylake-X)	Comments

	Native Dhrystone Integer (GIPS)	336 [=]	334	400	485	We start with no improvement over ZEN+
	Native Dhrystone Long (GIPS)	339 [=]	335	393	485	With a 64-bit integer workload nothing much changes.
	Native FP32 (Float) Whetstone (GFLOPS)	202 [+2%]	198	236	262	Floating-point performance does not change delta either – only 2% faster
	Native FP64 (Double) Whetstone (GFLOPS)	170 [=]	169	196	223	With FP64 nothing much changes again.
In the legacy integer/floating-point benchmarks ZEN2 is not any faster than ZEN+ despite the change in clocks. Perhaps future microcode updates will help?

	Native Integer (Int32) Multi-Media (Mpix/s)	1023 [+78%]	574	985	1590	ZEN2 is ~80% faster than ZEN+ despite what we’ve seen before.
	Native Long (Int64) Multi-Media (Mpix/s)	374 [+2x]	187	414	581	With a 64-bit AVX2 integer vectorised workload, ZEN2 is now 2x faster.
	Native Quad-Int (Int128) Multi-Media (Mpix/s)	6.56 [+13%]	5.8	6.75	7.56	This is a tough test using Long integers to emulate Int128 without SIMD; here ZEN2 is still 13% faster.
	Native Float/FP32 Multi-Media (Mpix/s)	100 [+68%]	596	914	1760	In this floating-point AVX/FMA vectorised test, ZEN2 is ~70% faster.
	Native Double/FP64 Multi-Media (Mpix/s)	618 [+84%]	335	535	533	Switching to FP64 SIMD code, ZEN2 is now ~90% faster than ZEN+
	Native Quad-Float/FP128 Multi-Media (Mpix/s)	24.22 [+55%]	15.6	23	40.3	In this heavy algorithm using FP64 to mantissa extend FP128, ZEN2 is still 55% faster
With its brand-new 256-bit SIMD units, ZEN2 is anywhere from 55% to 100% faster than ZEN+/ZEN1 a huge upgrade from one generation to the next. For SIMD loads upgrading to ZEN2 gives a huge performance uplift.

	Crypto AES-256 (GB/s)	18 [+12%]	16.1	17.63	23	With AES/HWA support all CPUs are memory bandwidth bound but ZEN2 manages a 12% improvement.
	Crypto AES-128 (GB/s)	18.76 [+17%]	16.1	17.61	23	What we saw with AES-256 just repeats with AES-128; ZEN2 is now 17% faster.
	Crypto SHA2-256 (GB/s)	20.21 [+9%]	18.6	12	26	With SHA/HWA ZEN2 similarly powers through hashing tests leaving Intel in the dust – and is still ~10% faster than ZEN+
	Crypto SHA1 (GB/s)	20.41 [+6%]	19.3	22.9	38	The less compute-intensive SHA1 does not change things due to acceleration.
	Crypto SHA2-512 (GB/s)		3.77	9	21	–
ZEN2 with AES/SHA HWA is memory bound like all other CPUs, but it still manages 6-17% better performance than ZEN+ using the same memory. But as ZEN2 is rated for faster memory – using such memory would greatly improve the results.

	Black-Scholes float/FP32 (MOPT/s)	–	257	276	309	–
	Black-Scholes double/FP64 (MOPT/s)	229 [+5%]	219	238	277	Switching to FP64 code, ZEN2 is just 5% faster.
	Binomial float/FP32 (kOPT/s)	–	107	59.9	70.5	Binomial uses thread shared data thus stresses the cache & memory system;
	Binomial double/FP64 (kOPT/s)	57.98 [-4%]	60.6	61.6	68	With FP64 code ZEN2 is 4% slower.
	Monte-Carlo float/FP32 (kOPT/s)	–	54.2	56.5	63	Monte-Carlo also uses thread shared data but read-only thus reducing modify pressure on the caches;
	Monte-Carlo double/FP64 (kOPT/s)	46.34 [+13%]	41	44.5	50.5	Switching to FP64 nothing much changes, ZEN2 is 13% faster.
Ryzen always did well on non-SIMD floating-point algorithms and here it does not disappoint: ZEN2 does not improve much and is pretty much tied with ZEN+ – thus for non SIMD workloads you might as well stick with the older versions.

	SGEMM (GFLOPS) float/FP32	263 [-12%]	300	375	413	In this tough vectorised algorithm ZEN2 is strangely slower.
	DGEMM (GFLOPS) double/FP64	193 [+63%]	119	209	212	With FP64 vectorised code, ZEN2 comes back to be over 60% faster.
	SFFT (GFLOPS) float/FP32	22.78 [+2.5x]	9	22.33	28.6	FFT is also heavily vectorised but stresses the memory sub-system more; ZEN2 is 2.5x (times) faster.
	DFFT (GFLOPS) double/FP64	11.16 [+41%]	7.92	11.21	14.6	With FP64 code, ZEN2 is ~40% faster.
	SNBODY (GFLOPS) float/FP32	612 [+2.2x]	280	557	638	N-Body simulation is vectorised but fewer memory accesses; ZEN2 is over 2x faster.
	DNBODY (GFLOPS) double/FP64	220 [+2x]	113	171	195	With FP64 precision ZEN2 is almost 2x faster.
With highly vectorised SIMD code ZEN2 improves greatly over ZEN2 sometimes managing to be over 2x faster using the same memory.

	Blur (3×3) Filter (MPix/s)	2049 [+42%]	1440	2560	4880	In this vectorised integer workload ZEN2 starts over 40% faster than ZEN+.
	Sharpen (5×5) Filter (MPix/s)	950 [+52%]	627	1000	1920	Same algorithm but more shared data makes ZEN2 over 50% faster.
	Motion-Blur (7×7) Filter (MPix/s)	495 [+52%]	325	519	1000	Again same algorithm but even more data shared still 50% faster
	Edge Detection (2*5×5) Sobel Filter (MPix/s)	826 [+67%]	495	827	1500	Different algorithm but still vectorised workload ZEN2 is almost 70% faster.
	Noise Removal (5×5) Median Filter (MPix/s)	89.68 [+24%]	72.1	78	221	Still vectorised code now ZEN2 drops to just 25% faster.
	Oil Painting Quantise Filter (MPix/s)	25.05 [+5%]	23.9	42.2	66.7	This test has always been tough for Ryzen so ZEN2 does not improve much.
	Diffusion Randomise (XorShift) Filter (MPix/s)	1763 [+76%]	1000	4000	4070	With integer workload, Intel CPUs seem to do much better but ZEN2 is still almost 80% faster.
	Marbling Perlin Noise 2D Filter (MPix/s)	321 [+32%]	243	596	777	In this final test again with integer workload ZEN2 is 32% faster
As we’ve seen before, the new SIMD units are anywhere from 5% (worst-case) to 2x faster than ZEN+/1, a huge performance improvement.

	Aggregate Score (Points)	8,200 [+40%]	5,850	7,930	11,810	Across all benchmarks, ZEN2 is ~40% faster than ZEN+.
Aggregating all the various scores, the result was never in doubt: ZEN2 (3700X) is 40% faster than the old ZEN+ (2700X) that itself improved over the original 1700X.

ZEN2’s 256-bit wide SIMD units are a big upgrade and show their power in every SIMD workload; otherwise there is only minor improvement.

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

Executive Summary: For SIMD workloads you really have to upgrade to Ryzen2; otherwise stick with Ryzen+ unless lower power is preferred. 9/10 overall.

The big change in Ryzen2 are the 256-bit wide SIMD units and all vectorised workloads (Multi-Media, Scientific, Image processing, AI/Machine Learning, etc.) using AVX/FMA will greatly benefit – anything between 50-100% which is a significant increase from just one generation to the next.

But for all other workloads (e.g. Financial, legacy, etc.) there is not much improvement over Ryzen+/1 which were already doing very well against competition.

Naturally it all comes at lower TDP (65W vs 95) which may help with overclocking and also lower noise (from the cooling system) and power consumption (if electricity is expensive or you are running it continuously) thus the performance/W(att) is still greatly improved.

Overall the 3700X does represent a decent improvement over the old 2700X (which is no slouch and was a nice upgrade over 1700X due to better Turbo speeds) and should still be usable in older AM4 300/400-series mainboards with just a BIOS upgrade (without PCIe 4.0).

However, while 2700X (and 1700X/1800X) were top-of-the-line, 3700X is just middle-ground, with the new top CPUs being the 3900X and even the 3950X with twice (2x) more cores and thus potentially huge performance rivaling HEDT Threadripper. The goad-posts have thus moved and thus far higher performance can be yours with just upgrading the CPU. The future is bright…

AMD Ryzen2 3900X Review & Benchmarks – CPU 12-core/24-thread Performance

By Adrian Silasi | 7th July 2019 - 12:00 am |17th July 2019 Reviews

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What is “Ryzen2” ZEN2?

The list of changes vs. previous ZEN/ZEN+ is extensive thus performance delta is likely to be very different also:

Built around “chiplets” of up to 2 CCX (“core complexes”) each of 4C/8T and 8MB L3 cache (7nm)
Central I/O hub with memory controller(s) and PCIe 4.0 bridges connected through IF (“Infinity Fabric”) (12nm)
Up to 2 chiplets on desktop platform thus up to 2x2x4C (16C/32T 3950X) (same amount as old ThreadRipper 1950X/2950X)
2x larger L3 cache per CCX thus up to 2x2x16MB (64MB) L3 cache (3900X+)
24 PCIe 4.0 lanes (2x higher transfer rate over PCIe 3.0)
2x DDR4 memory controllers up to 4266Mt/s

What’s new in the Ryzen2 core?

Micro-architecturally there are more changes that should improve performance:

256-bit (single-op) SIMD units 2x Fmacs (fixing a major deficiency in ZEN/ZEN+ cores)
TLB (2nd level) increased (should help out-of-page access latencies that are somewhat high on ZEN/ZEN+)
Memory latencies claim to be reduced through higher-speed memory (note all requests go through IF to Central I/O hub with memory controllers)
Load/Store 32bytes/cycle (2x ZEN/ZEN+) to keep up with the 256-bit SIMD units (L1D bandwidth should be 2x)
L3 cache is 2x ZEN/ZEN+ but higher latency (cache is exclusive)
Infinity Fabric is 512-bit (2x ZEN/ZEN+) and can run 1x or 1/2x vs. DRAM clock (when higher than 3733Mt/s)
AMD processors have thankfully not been affected by most of the vulnerabilities bar two (BTI/”Spectre”, SSB/”Spectre v4″) that have now been addressed in hardware.
HWM-P (hardware performance state management) transitions latencies reduced (ACPI/CPPCv2)

In this article we test CPU core performance; please see our other articles on:

Hardware Specifications

We are comparing the top-of-the-range Ryzen2 (3900X, 3700X) with previous generation Ryzen+ (2700X) and competing architectures with a view to upgrading to a mid-range high performance design.

CPU Specifications	AMD Ryzen 9 3900X (Matisse)	AMD Ryzen 7 3700X (Matisse)	AMD Ryzen 7 2700X (Pinnacle Ridge)	Intel i9 9900K (Coffeelake-R)	Intel i9 7900X (Skylake-X)	Comments
Cores (CU) / Threads (SP)	12C / 24T	8C / 16T	8C / 16T	8C / 16T	10C / 20T	Matching core-count with CFL (3800X) but 3900X has 50% more cores – more than SKL-X.
Topology	2 chiplets, each 2 CCX, each 3 cores (1 disabled) (12C)	1 chiplet, 2 CCX, each 4 cores (8C)	2 CCX, each 4 cores (8C)	Monolithic die	Monolithic die	AMD uses discrete dies/chiplets unlike Intel
Speed (Min / Max / Turbo)	3.8 / 4.6GHz	3.6 / 4.4GHz	3.7 / 4.2GHz	3.6 / 5GHz	3.3 / 4.3GHz	Base clock and turbo are competitive with 3800X having higher base while 3900X higher turbo.
Power (TDP / Turbo)	105 / 135W	65 / 90W	105 / 135W	95 / 135W	140 / 308W	TDP remains the same but 3900X may exceed that having more cores.
L1D / L1I Caches	12x 32kB 8-way / 12x 32kB 8-way	8x 32kB 8-way / 8x 32kB 8-way	8x 32kB 8-way / 8x 64kB 4-way	8x 32kB 8-way / 8x 32kB 8-way	10x 32kB 8-way / 10x 32kB 8-way	ZEN2 matches L1I with CFL/SKL-X (1/2x ZEN+ but 8-way), L1D is unchanged (also matches Intel)
L2 Caches	12x 512kB (6MB) 8-way	8x 512kB (4MB) 8-way	8x 512kB (4MB) 8-way	8x 256kB (2MB) 16-way	10x 1MB (10MB) 16-way	No changes to L2, still 2x CFL. Only SKL-X has its massive 1MB L2 per core which 3900X almost matches!
L3 Caches	2x2x 16MB (64MB) 16-way	2x 16MB (32MB) 16-way	2x 8MB (16MB) 16-way	16MB 16-way	13.75MB 11-way	L3 is 2x ZEN/ZEN+ and thus 2x CFL (3800X) with 3900X having a massive 64MB unheard of on the desktop platform! SKL-X can’t match it either.
Mitigations for Vulnerabilities	BTI/”Spectre”, SSB/”Spectre v4″ hardware	BTI/”Spectre”, SSB/”Spectre v4″ hardware	BTI/”Spectre”, SSB/”Spectre v4″ software/firmware	RDCL/”Meltdown”, L1TF hardware, BTI/”Spectre”, MDS/”Zombieload”, software/firmware	RDCL/”Meltdown” , L1TF, BTI/”Spectre”, MDS/”Zombieload”, all software/firmware	Ryzen2 addresses the remaining 2 vulnerabilities while Intel was forced to add MDS to its long list…
Microcode	MU-8F7100-11	MU-8F7100-11	MU-8F0802-04	MU-069E0C-9E	MU-065504-49	The latest microcodes included in the respective BIOS/Windows have been loaded.
SIMD Units	256-bit AVX/FMA3/AVX2	256-bit AVX/FMA3/AVX2	128bit AVX/FMA3/AVX2	256-bit AVX/FMA3/AVX2	512-bit AVX512	ZEN2 finally matches Intel/CFL but SKL-X’s secret weapon is AVX512 with even consumer CPUs able to do 2x 512-bit FMA ops.

Native Performance

Results Interpretation: Higher values (GOPS, MB/s, etc.) mean better performance.

Native Benchmarks		AMD Ryzen 9 3900X (Matisse)	AMD Ryzen 7 2700X (Pinnacle Ridge)	Intel i9 9900K (Coffeelake-R)	Intel i9 7900X (Skylake-X)	Comments

	Native Dhrystone Integer (GIPS)	551 [+38%]	334	400	485	Right off Ryzen2 demolishes all CPUs, it is 40% faster than CFL-R!
	Native Dhrystone Long (GIPS)	556 [+41%]	335	393	485	With a 64-bit integer workload nothing much changes.
	Native FP32 (Float) Whetstone (GFLOPS)	331 [+40%]	198	236	262	Floating-point performance does not change delta either – still 40% faster!
	Native FP64 (Double) Whetstone (GFLOPS)	280 [+43%]	169	196	223	With FP64 nothing much changes again.
Ryzen2 starts with an astonishing display, with 3900X demolishing both 9900X and 7900X winning all tests by a large margin 38-43%! It does have 50% more cores (12 vs. 8) but it is not easy to realise gains just by increasing core counts. Intel will need to add far more cores in future CPUs in order to compete!

	Native Integer (Int32) Multi-Media (Mpix/s)	1449 [+47%]	574	985	1590	Ryzen2 starts off by blowing CFL-R away by 47% and almost matching SKL-X with AVX512!
	Native Long (Int64) Multi-Media (Mpix/s)	553 [+34%]	187	414	581	With a 64-bit AVX2 integer vectorised workload, Ryzen2 is still 34% faster!
	Native Quad-Int (Int128) Multi-Media (Mpix/s)	9.52 [+41%]	5.8	6.75	7.56	This is a tough test using Long integers to emulate Int128 without SIMD; here Ryzen2 is again 41% faster!
	Native Float/FP32 Multi-Media (Mpix/s)	1480 [+62%]	596	914	1760	In this floating-point AVX/FMA vectorised test, Ryzen2 is now over 60% faster than CFL-R and not far off SKL-X!
	Native Double/FP64 Multi-Media (Mpix/s)	906 [+69%]	335	535	533	Switching to FP64 SIMD code, Ryzen2 is now 70% faster even beating SKL-X!!!
	Native Quad-Float/FP128 Multi-Media (Mpix/s)	35.23 [+53%]	15.6	23	40.3	In this heavy algorithm using FP64 to mantissa extend FP128, Ryzen2 is still 53% faster!
With its brand-new 256-bit SIMD units, Ryzen2 finally goes toe-to-toe with Intel, soundly beating CFL-R in all benchmarks (+34-69%) sometimes by more than just core count increase (+50%). Only SKL-X with AVX512 manages to be faster (but also with its extra 2 cores). Intel had better release AVX512 for desktop soon but even that will not be enough without increasing core counts to match AMD.

	Crypto AES-256 (GB/s)	15.44 [-12%]	16.1	17.63	23	With AES/HWA support all CPUs are memory bandwidth bound – thus Ryzen2 scores less than Ryzen+ and CFL-R.
	Crypto AES-128 (GB/s)	15.44 [-12%]	16.1	17.61	23	What we saw with AES-256 just repeats with AES-128; Ryzen2 is again slower by 12%.
	Crypto SHA2-256 (GB/s)	29.84 [+2.5x]	18.6	12	26	With SHA/HWA Ryzen2 similarly powers through hashing tests leaving Intel in the dust – 2.5x faster than CFL-R and beating SKL-X with AVX512!
	Crypto SHA1 (GB/s)		19.3	22.9	38	–
	Crypto SHA2-512 (GB/s)		3.77	9	21	–
Ryzen2 with AES/SHA HWA is memory bound thus needs faster memory than 3200Mt/s in order to feed all the cores; otherwise due to increased contention for the same bandwidth it may end up slower than Ryzen+ and Intel designs. Here you see the need for HEDT platforms and thus ThreadRipper but at much increased cost.

	Black-Scholes float/FP32 (MOPT/s)		257	276	309	–
	Black-Scholes double/FP64 (MOPT/s)	379 [+55%]	219	238	277	Switching to FP64 code, nothing much changes, Ryzen2 55% faster than CFL-R.
	Binomial float/FP32 (kOPT/s)		107	59.9	70.5	Binomial uses thread shared data thus stresses the cache & memory system;
	Binomial double/FP64 (kOPT/s)	95.73 [+55%]	60.6	61.6	68	With FP64 code Ryzen2 is still 55% faster!
	Monte-Carlo float/FP32 (kOPT/s)		54.2	56.5	63	Monte-Carlo also uses thread shared data but read-only thus reducing modify pressure on the caches;
	Monte-Carlo double/FP64 (kOPT/s)	76.72 [+72%]	41	44.5	50.5	Switching to FP64 nothing much changes, Ryzen2 is 70% faster than CFL-R and still beating SKL-X.
Ryzen always did well on non-SIMD floating-point algorithms and here it does not disappoint: Ryzen2 is over 50% faster than CFL-R (+55-72%) and soundly beats SKL-X too! As before for financial algorithms there is only one choice and that is Ryzen, be it Ryzen1, Ryzen+ or Ryzen2!

	SGEMM (GFLOPS) float/FP32		300	375	413	In this tough vectorised algorithm Ryzen2.
	DGEMM (GFLOPS) double/FP64	212 [+1%]	119	209	212	With FP64 vectorised code, Ryzen2 matches CFL-R and SKL-X.
	SFFT (GFLOPS) float/FP32		9	22.33	28.6	FFT is also heavily vectorised but stresses the memory sub-system more;
	DFFT (GFLOPS) double/FP64	12.69 [+13%]	7.92	11.21	14.6	With FP64 code, Ryzen2 is 13% faster than CFL-R.
	SNBODY (GFLOPS) float/FP32		280	557	638	N-Body simulation is vectorised but fewer memory accesses;
	DNBODY (GFLOPS) double/FP64	332 [+94%]	113	171	195	With FP64 precision Ryzen2 is almost 2x faster than CFL-R.
With highly vectorised SIMD code Ryzen2 remains competitive but finds some algorithms tougher than others. The new 256-bit SIMD units help but it seems the cores are starved of bandwidth (especially due to SMT) and some workloads may perform better with SMT off.

	Blur (3×3) Filter (MPix/s)	3056 [+20%]	1440	2560	4880	In this vectorised integer workload Ryzen2 is 20% faster than CFL-R.
	Sharpen (5×5) Filter (MPix/s)	1499 [+50%]	627	1000	1920	Same algorithm but more shared data makes Ryzen2 50% faster!
	Motion-Blur (7×7) Filter (MPix/s)	767 [+48%]	325	519	1000	Again same algorithm but even more data shared still 50% faster
	Edge Detection (2*5×5) Sobel Filter (MPix/s)	1298 [+57%]	495	827	1500	Different algorithm but still vectorised workload Ryzen2 is almost 60% faster.
	Noise Removal (5×5) Median Filter (MPix/s)	136 [+74%]	72.1	78	221	Still vectorised code now Ryzen2 is 70% faster.
	Oil Painting Quantise Filter (MPix/s)	38.23 [-9%]	23.9	42.2	66.7	This test has always been tough for Ryzen but Ryzen2 is competitive.
	Diffusion Randomise (XorShift) Filter (MPix/s)	1384 [-65%]	1000	4000	4070	With integer workload, Intel CPUs seem to do much better.
	Marbling Perlin Noise 2D Filter (MPix/s)	487 [-18%]	243	596	777	In this final test again with integer workload Ryzen2 is 20% slower.
Thanks to AVX512 SKL-X does win all tests but Ryzen2 beats CFL-R between 20-74% with a few test mixing integer & floating-point SIMD instructions seemingly heavily favouring Intel but nothing to worry about. Overall for image processing Ryzen2 should be your 1st choice.

	Aggregate Score (Points)	10,250 [+29%]	5,850	7,930	11,810	Across all benchmarks, Ryzen2 is ~30% faster than CFL-R!
Aggregating all the various scores, the result was never in doubt: Ryzen2 (3900X) is almost 2x faster than Ryzen+ (2700X) and 30% faster than CFL-R, almost catching up HEDT SKL-X.

Ryzen2 (unlike Ryzen1/+) has no trouble with SIMD code due to its widened SIMD units (256-bit) and thus soundly beats the opposition into dust (CFL-R 9900K flagship) sometimes more than just core count increase alone (+50% i.e. 12 cores vs. 8). Sometimes it even beats the AVX512 opposition (SKL-X 7900K) with more cores (10 cores vs. 12).

The only “problematic” algorithms are the memory bound ones where the cores/threads (due to SMT we have 24!) are starved for data and due to contention we see performance lower than less-core devices. While larger caches help (thus the massive 4x 16MB L3 caches) higher clocked memory should be used to match the additional core requirements.

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

Executive Summary: Ryzen2 is phenomenal and a huge upgrade over Ryzen1/+ that (most) AM4 users can enjoy and Intel has no answer to. 10/10.

Just as original Ryzen forced Intel to increase (double really) core counts to match (from 4 to 6 then 8), Ryzen2 will force Intel to come up with even more (and better) cores in order to compete. 3900X with its 12-cores soundly beats CFL-R 9900K (8-cores) in just about all benchmarks and in some tests goes toe-to-toe with HEDT SKL-X AVX512-enabled (10-cores) except in memory-bound algorithms where the 4 DDR4 memory channels with 2x more bandwidth count. For that you need ThreadRipper!

Ryzen1/+ was already competitive with Intel on integer and floating-point (non-SIMD) workloads but would fare badly on SIMD (AVX/FMA3/AVX2) workloads due to its 128-bit units; Ryzen2 “fixes” this issue, with its 256-bit units matching Intel. Only SKL-X with its 512-bit units (AVX512) is faster and Intel will have to finally include AVX512 for consumer CPUs in order to compete (IceLake?).

For compute-bound workloads, the forthcoming 3950X with its 16-cores/32-threads brings unprecedented performance to the consumer/desktop segment pretty much unheard of just a few years ago when 4-core/8-threads (e.g. 7700K) were all you could hope for – unless paying a lot more for HEDT where 8/10-core CPUs were far far more expensive. Naturally we shall see how the reduced memory bandwidth affects its performance with likely very fast DDR4 memory (4300Mt/s+) required for best performance.

Let’s also remember than Ryzen2 adds hardware mitigation to its remaining 2 vulnerabilities while Intel has been forced to add MDS/”Zombieload” even to its very latest CFL-R that now loses its trump card: hardware RDCL/”Meltdown” fix not to forget the recommendation to disable SMT/Hyperthreading that would mean a sizeable performance drop.

What is astonishing is that TDP has remained similar and with a BIOS/firmware upgrade, owners of older 300-series boards can now upgrade to these CPUs – and likely not even change the cooler unit! Naturally for PCIe4.0 a 500-series board is recommended and 400-series boards do support more features in Ryzen2/+ but let’s remember than on Intel you can only go back/forward 1 generation even though there is pretty much no core difference from Skylake (Gen 6) to Coffeelake-R (Gen 9)!

From top-end (3950X), high-end (3800X) to low-end/APU (3200G) Ryzen2 is such a compelling choice it is hard to recommend anything else… at least at this time…

The new Neural Networks (AI/ML) Benchmarks: RNN Architecture

By Adrian Silasi | 2nd July 2019 - 2:22 pm |2nd July 2019 Releases

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What is a Recurrent Neural Network (RNN/LSTM)?

A RNN is a type of neural network that is primarily made of of neurons that store their previous states thus are said to ‘have memory’. In effect this allows them to ‘remember’ patterns or sequences.

However, they can still be used as ‘classifiers’ i.e. recognising visual patterns in images and thus can be used in visual recognition software.

What is VGG(net) is why use it now?

VGGNet is the baseline (or benchmark) CNN-type network that while did not win the ILSVRC 2014 competition (won by GoogleNet/Inception) it is still the preferred choice in the community for classification due to its uniform and thus relatively simple architecture.

While it is generally implemented using CNN layers, either directly or combination like ResNet, it can also be implemented using RNN layers which is what we have done here.

We believe this is a good test scenario and thus a relevant benchmark for today’s common systems.

We are considering much complex neurons, like LSTM, for future tests specifically designed for high-end systems as those used in research and academia.

What is the MNIST dataset and why use it now?

The MNIST database (https://en.wikipedia.org/wiki/MNIST_database) is a decently sized dataset of handwritten digits used for training and testing image processing systems like neural networks. It contains 60K training and 10K testing images of 28×28 pixel anti-aliased gray levels. The number of classes is only 10 (digits ‘0’ to ‘9’).

While they are only 28×28 and not colour, they can be up-scaled to any size by common up-scaling algorithms to test neural networks with little source data.

Today (2019) the digits would be captured in much higher resolution similar to the standard input resolution of the image processing networks of today (between 200×200 and 300×300 pixels).

As Sandra is designed to be small and easily downloadable, it is not possible to include gigabytes (GB) of data for either inference or training. Even the low-resolution (32x32x3) ILSVRC is 3GB thus unusable for our purpose.

What is Sandra’s RNN network architecture and why was it designed this way?

Due to the low complexity of the data and in order to maintain good performance even on low-end hardware, a standard RNN was chosen as the architecture. The features are:

Input is 224x224x1 as MNIST images are grey-scale only (up-scaled from 28×28)
Output is 10 as there are only 10 classes
4 layer network, 1 RNN, 3 fully connected layers

What are the implementation details of the network?

The CPU version of the neural network supports all common instruction sets and precision and will be continuously updated as the industry moves forward.

Both inference/forward and train/back-propagation tested and supported.
Precision: single and double floating-point supported with future half/FP16.
SIMD Instruction Sets: CPU, SSE2, SSE4.x, AVX, AVX2/FMA and AVX512 with future VNNI.
Threads/Cores: Up to the maximum operating system 384 threads in 64-thread groups are supported with hard affinity as all other benchmarks.
NUMA: NUMA is supported up to 16 nodes with data allocated to the closest node.

What kind of BTT (Back-propagation Through Time) is used?

Unfortunately as we only know the output (digit) at the end of the sequence (i.e. once all pixels have been presented) we cannot calculate intermediate errors in order to use TBTT (Truncated BTT) which relies on known output at intermediate sequence time-steps.

What kind of detection rate and error does Sandra’s implementation achieve?

Naturally due to the low source resolution, a much shallower/simpler network would have sufficed. However due to up-scaling and the relatively large number of training images there is no danger of over-fitting.

It achieves a % detection rate (over the 10K testing images) after just 1 epoch (Epoch 0) and % after 30 epochs.

Training (30 epochs) took just X* hours on an i9-7900X (10C/20T) using AVX512/single-precision.

Does Sandra fully infer or train the full image set when benchmarking?

As with all other Sandra benchmarks the tests are limited to 30 seconds (in order to complete reasonably quickly) – within this time as many images at random from the data-sets (60K train, 10K test) will be processed.

The new Neural Networks (AI/ML) Benchmarks: CNN Architecture

By Adrian Silasi | 2nd July 2019 - 2:13 pm |2nd July 2019 Releases

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What is a Convolution Neural Network (CNN/ConvNet)?

A CNN is a type of neural network that is primarily made of of neuron layers connected in such a way that they perform convolution over the previous layers: in effect they are filters over the input – the same way a blur/sharpen/edge/etc filter would be applied over a picture.

They are used as ‘classifiers’ i.e. recognising visual patterns in images and thus are used in visual recognition software.

What is VGG(net) is why use its architecture now?

Thus while today (2019) there are far deeper and more complex neural networks, as Sandra is intended to run on common systems we had to choose the most common but relatively simple network.

We believe this is a good test scenario and thus a relevant benchmark for today’s common systems.

We are considering much deeper networks, like ResNet, for future tests specifically designed for high-end systems as those used research and academia.

Why not use Tensorflow, Caffee, etc. as back-end?

As with all Sandra benchmarks we develop our own code which is optimised in the conjunction with the community which includes hardware makers. This allows us to control all the benchmark stack adding new features and support as required which we would not be able to do when using a back-end.

Using a specific vendor’s libraries (e.g. cuDNN, MKL, etc.) would lock-us into a specific platform while we provide implementation for all platforms including all CPU SIMD instruction sets (SSE2, SSE4, AVX, AVX2/FMA, AVX512) and major GP (GPGPU) run-times (CUDA, OpenCL, DirectX 11/12 Compute and future Vulkan*).

What is the MNIST dataset and why use it now?

The MNIST database (https://en.wikipedia.org/wiki/MNIST_database) is a decently sized dataset of handwritten digits used for training and testing image processing systems like neural networks. It contains 60k (thousand) training and 10k testing images of 28×28 pixel anti-aliased gray levels. The number of classes is only 10 (digits ‘0’ to ‘9’).

While they are only 28×28 and not colour (1 channel), they can be up-scaled to any size by common up-scaling algorithms to test neural networks with little source data. Here we up-scale them 8x to 224x224x1.

Today (2018) the digits would be captured in much higher resolution similar to the standard input resolution of the image processing networks of today (between 200×200 and 300×300 pixels).

As Sandra is designed to be small and easily downloadable, it is not possible to include gigabytes (GB) of data for either inference or training. Even the low-resolution ImageNet ILSVRC is 3GB thus unusable for our purpose.

What are the CIFAR datasets and why use them now?

The CIFAR datasets (https://www.cs.toronto.edu/~kriz/cifar.html) are also decently sized datasets of objects used for training and testing image processing systems like neural networks. They both consists of 50k (thousand) training and 10k testing images of 32x32x3 pixel colour images with CIFAR-10 having 10 classes and CIFAR-100 having 100 classes.

Unlike MNIST the pictures are colour (3 channels RGB) and can also be up-scaled to any size by common up-scaling algorithms to test neural networks with little source data. Here we up-scale them 7x to 224x224x3.

Again, just as with MNIST this allows us to include more datasets while processing them in high resolution similar to modern neural networks without including a large dataset like ImageNet ILSVRC dataset.

What are ImageNet ILSVRC datasets and why not use them?

The ImageNet (ImageNet Large Scale Visual Recognition Challenge) datasets (http://www.image-net.org/challenges/LSVRC/) are used in the yearly challenge for researchers in object detection, image classification at large scale. They are used to measure progress in computer vision in the World today.

The yearly challenge/competition has thus yielded many recent advancements in the field with winners (and in some cases runner-ups) providing the classical neural networks of today: AlexNet, VGG, ResNet, Inception, etc.

Naturally the task is non-trivial and requires cutting-edge complex neural networks that generally require similarly high-end hardware that is not the domain of mass-market. While old(er) neural networks like AlexNet, VGG or ResNet can today (2018) work on consumer hardware – they are usually deployed in inference/classification mode. Training them (from scratch) would still require significant processing power and time which does not make sense for our benchmark.

Due to the nature of our software (mass-market, small, fast) the size of the datasets (about 3GB for 32x32x3 1.2 million training images) makes them unsuitable to be included either as standard or downloadable. As we aready use low-resolution datasets, it would not make sense to include another – and the high resolution versions (e.g. 256x256x3) are far larger (about 137GB train, 6.3GB test).

Another issue is the licensing: they are licensed for research which Sandra as a commercial product – even though we provide the benchmarks free of charge – would likely not qualify.

What is Sandra’s CNN network architecture and why was it designed this way?

Due to the low complexity of the data and in order to maintain good performance even on low-end hardware, VGG-16 was chosen as the architecture. The features are:

For MNIST dataset
- Input is 224x224x1 as MNIST images are grey-scale (upscaled from 28×28)
- Output is 10* as there are only 10 classes
- 8 convolution (3×3 step 1), 5 pooling (2×2 step 2), 3 full-connect layers
Network/Engine features
- Layers: Fully Connected/Dense, Convolution, Max Pooling, Recurrent, Dropout.
- Activation: ReLU, Leaky ReLU, Smooth ReLU, Sigmoid, TanH. Activation functions are fused to the layers for reduced memory size/bandwidth footprint.
- Back-propagation Optimiser: 2nd order Hessian.
- Alignment: For performance, some layer sizes may be increased (e.g. output) to match SIMD alignment; the performance due to SIMD is higher than the overhead due to more un-needed neurons.
- SIMD Float Width: Up to 64 single-precision pixels per cycle when using AVX512.
- SIMD Half Width: Up to 128 half-precision pixels per cycle when using AVX512/BFloat16*.
- SIMD Int8 Width: Up to 256 int8 pixels per cycle when using AVX512/VNNI*.

What are the implementation details of the network?

The CPU version of the neural network supports all common instruction sets and precision and will be continuously updated as the industry moves forward.

Both inference/forward and train/back-propagation tested and supported.
Processor:
- Precision: single/FP32 and double/FP64 supported.
- SIMD Instruction Sets: FPU, SSE2, SSE4.x, AVX, AVX2/FMA, AVX512 with future VNNI*.
- Threads/Cores: Up to the maximum operating system 384 threads in 64-thread groups are supported with hard affinity as all other benchmarks.
- Atomic Updates: TSX/RTE used where supported otherwise 128/64/32-bit interlock/update.
- NUMA: NUMA is supported up to 16 nodes with data allocated to the closest node.
- Large Pages: Large (2/4MB) pages used where supported and enabled.
GP (GPGPU):
- Precision: single/FP32 and half/FP16 supported.
- Run-Times: CUDA 10+, OpenCL 1.2+, DirectX 11/12 Compute.
- Multi-GPU: Up to 8 devices are supported including CPU pseudo-device.

How is the data stored/processed?

We use the CHW format for simple SIMD implementation and performance load/store.

What activation function do you use?

We use the Sigmoid activation function with a fast (but naturally somewhat low-precision) SIMD tanh/exp implementation; while many modern networks (and VGG itself) use ReLU (for speed reasons) we’ve found the Sigmoid to work “better” for us without appreciable performance impact. By better we mean fast convergence and no need for batch normalisation.

What kind of detection rate and error does Sandra’s implementation achieve?

Naturally due to the low source resolution, a much shallower/simpler network would have sufficed. However due to upscaling and the relatively large number of training images there is no danger of overfitting.

It achieves a 95.3% detection rate (over the 10k testing images) after just 1 epoch (Epoch 0) and 99.82% after 30 epochs.

Training (30 epochs) took just 7* hours on an i9-7900X (10C/20T) using AVX512/single-precision.

Does Sandra fully infer or train the full image set when benchmarking?

As with all other Sandra benchmarks the tests are limited to 30 seconds (in order to complete resonably quickly) – within this time as many images at random from the datasets (60k train, 10k test) will be processed.

SiSoftware Sandra Titanium (2018) SP4/a/c Update: Retpoline and hardware support

By Adrian Silasi | 10th June 2019 - 12:30 pm |13th June 2019 Releases, Updates

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Note: Updated 2019/June with information regarding MDS as well as change of recent CFL-R microcode vulnerability reporting.

We are pleased to release SP4/a/c (version 28.69) update for Sandra Titanium (2018) with the following updates:

Sandra Titanium (2018) Press Release

Reporting of Operating System (Windows) speculation control settings for the recently discovered vulnerabilities:
- Kernel Retpoline mitigation status (for RDCL) in recent Windows 10 / Server 2019 updates
- Kernel Address Table Import Optimisation (“KATI”) status (as above)
- L1TF – L1 data terminal fault mitigation status
- MDS – Microarchitectural Data Sampling/”ZombieLoad” mitigation status

Hardware Support:
- AMD Ryzen2 (Matisse), Stoney Ridge support
- Intel CometLake (CML), CannonLake (CNL), IceLake (ICL) support (based on public information)

CPU Benchmarks:
- Image Processing: SIMD code improvement (SSE2/SSE4/AVX/AVX2-FMA/AVX512)
- Multi-Media: Lock-up on NUMA systems (e.g. AMD ThreadRipper) thanks to Rob @ TechGage.

Memory/Cache Benchmarks
- Return memory controller firmware version to Ranker

GPGPU Benchmarks:
- CUDA SDK 10.1
- OpenCL: Processing (Fractals/Mandelbrot) variable vector width based on reported FP16/32/64 optimal SIMD width.

Ranker, Price & Information Engines
- HTTPS (encryption) support for all engines as well as the main website

What is Retpoline?

It is a mitigation against ‘Spectre‘ 2 variant (BTI – Branch Target Injection) that affects just about all CPUs (not just Intel but AMD, ARM, etc.). While ‘Spectre’ does not have the same overall performance impact degradation as ‘Meltdown‘ (RDCL – Rogue Data Cache Load) it can have a sizeable impact on some processors and workloads. At this time no CPUs contain hardware mitigation for Spectre without performance impact.

Retpoline (Return Trampoline) is a faster way to mitigate against it without restricting branch speculation in kernel mode (using IBRS/IBPB) and has recently been added to Linux and now Windows version 1809 builds with KB4482887. Note that it still needs to be enabled in registry via the Mitigation Features Override flags as by default it is not enabled.

What CPUs can Retpoline be used on?

Unfortunately Retpoline is only safe to use on some CPUs: AMD CPUs (though does not engage on Ryzen, see below), Intel Broadwell or older (v5 and earlier) – thus not Skylake (v6 or later).

Windows speculation control settings reporting:

Intel Haswell (Core v4), Broadwell (v5) – Retpoline enabled, KATI enabled
	Kernel Retpoline Speculation Control – Enabled Kernel Address Table Import Optimisation – Enabled (Note RDCL mitigations KVA, L1TF are also enabled as required)
Intel Skylake (Core v6), Kabylake (v7), Skylake/Kabylake-X (v6x) – no Retpoline, KATI can be enabled
	Kernel Retpoline Speculation Control – no Kernel Address Table Import Optimisation – no/yes (can be enabled) (Note RDCL mitigations KVA, L1TF are enabled as required)
*Intel Coffeelake-R (Core v8r), Whiskeylake/AmberLake (Core v8r), CometLake – no Retpoline, KATI not enabled**
	Kernel Retpoline Speculation Control – no Kernel Address Table Import Optimisation – Enabled Note 2019/June: Latest microcode (AEh) with MDS vulnerability support cause Windows to report KVA/L1TF mitigations as required despite CPU claiming to not be vulnerable to RDCL.
Intel Atom Braswell (Atom v5), GeminiLake/ApolloLake (Atom v6) – no Retpoline but KATI enabled
	Kernel Retpoline Speculation Control – no Kernel Address Table Import Optimisation – Enabled (Note RDCL mitigations KVA, L1TF are enabled as required)
AMD Ryzen (Threadripper) 1, 2 – no Retpoline, no KATI
	Kernel Retpoline Speculation Control – no (should be usable?) Kernel Address Table Import Optimisation – no (should be usable) *(Note CPU does not require RDCL mitigation thus no KVA, L1TF required)*

From our somewhat limited testing above it seems that:

Intel Haswell/Broadwell (Core v4/v5) and perhaps earlier (Ivy Bridge/Sandy Bridge Core v3/v2) users are in luck, Retpoline is enabled and should improve performance; unfortunately RDCL (“Meltdown” mitigation) remains.

Intel Coffeelake-R (Core v8r refresh), Whiskylake ULV (v8r) ~~users do benefit a bit more for their investment – while Retpoline is not enabled, KATI is enabled and should help. Not requiring KVA is the biggest gain of CFL-R.~~ 2019/June: latest microcode (AEh) causes Windows to require KVA/L1TF thus negating any benefit CFL-R had over original CFL/KBL/SKL.

Intel Skylake (Core v6), Kabylake (v7) and Coffeelake (v8) are not able to benefit from Retpoline but KATI can work on some systems (driver dependent). However, on our Skylake ULV, Skylake-X test systems KATI could not be enabled. We are investigating further.

Intel Atom (v4/v5+) users should be able to use Retpoline but it seems it cannot be enabled currently. KATI is enabled.

AMD Ryzen (Threadripper) 1/2 users should also be able to use Retpoline but it seems it cannot be enabled currently. While RDCL is not required, mitigations for Spectre v2 are required and should be enabled. We are investigating further.

Reviews using Sandra 2018 SP4:

Update & Download

Commercial version customers can download the free updates from their software distributor; Lite users please download from your favourite download site.

Download Sandra Lite

What is “CometLake”?

Why review it now?

Hardware Specifications

Native Performance

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

Reviews using Sandra 20/20:

Update & Download

What is “Navi”?

Hardware Specifications

Processing Performance

Memory Performance

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

What is “Vega2”?

Hardware Specifications

Processing Performance

Memory Performance

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

SiSoftware Sandra 20/20 (2020) Released: Brand-new benchmarks (AI/ML), hardware support

Broad Operating System Support

Processor Neural Networks (AI/ML)

GP (GPU) Neural Networks (AI/ML)

CNN (Convolution Neural Network) Architecture

RNN (Recurrent Neural Network) Architecture

Major changes

Key features of Sandra 20/20

What is “Ryzen2” ZEN2?

To upgrade from Ryzen+/Ryzen1 or not?

Hardware Specifications

Native Performance

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

What is “Ryzen2” ZEN2?

What’s new in the Ryzen2 core?

Hardware Specifications

Native Performance

SiSoftware Official Ranker Scores

Final Thoughts / Conclusions

What is a Recurrent Neural Network (RNN/LSTM)?

What is VGG(net) is why use it now?

What is the MNIST dataset and why use it now?

What is Sandra’s RNN network architecture and why was it designed this way?

What are the implementation details of the network?

What kind of BTT (Back-propagation Through Time) is used?

What kind of detection rate and error does Sandra’s implementation achieve?

Does Sandra fully infer or train the full image set when benchmarking?

What is a Convolution Neural Network (CNN/ConvNet)?

What is VGG(net) is why use its architecture now?

Why not use Tensorflow, Caffee, etc. as back-end?

What is the MNIST dataset and why use it now?

What are the CIFAR datasets and why use them now?

What are ImageNet ILSVRC datasets and why *not* use them?

What is Sandra’s CNN network architecture and why was it designed this way?

What are the implementation details of the network?

How is the data stored/processed?

What activation function do you use?

What kind of detection rate and error does Sandra’s implementation achieve?

Does Sandra fully infer or train the full image set when benchmarking?

What is Retpoline?

What CPUs can Retpoline be used on?

Reviews using Sandra 2018 SP4:

Update & Download

SiSoftware Sandra 20/20 (2020) Released:
Brand-new benchmarks (AI/ML), hardware support

What are ImageNet ILSVRC datasets and why not use them?