The MSI X299 Gaming Pro Carbon AC Motherboard Review
by Patrick MacMillan on September 21, 2017 9:00 AM ESTTest Bed
As per our testing policy, we take a high end CPU suitable for the motherboard that was released during the socket’s initial launch, and equip the system with a suitable amount of memory running at the processor maximum supported frequency. This is also typically run at JEDEC subtimings where possible. It is noted that some users are not keen on this policy, stating that sometimes the maximum supported frequency is quite low, or faster memory is available at a similar price, or that the JEDEC speeds can be prohibitive for performance. While these comments make sense, ultimately very few users apply memory profiles (either XMP or other) as they require interaction with the BIOS, and most users will fall back on JEDEC supported speeds - this includes home users as well as industry who might want to shave off a cent or two from the cost or stay within the margins set by the manufacturer. Where possible, we will extend out testing to include faster memory modules either at the same time as the review or a later date.
| Test Setup | |
| Processor | Intel Core i9-7900X ES 10 Cores, 20 Threads, 3.3 GHz (4.3 GHz Turbo) |
| Motherboards | MSI X299 Gaming Pro Carbon AC |
| Cooling | Prolimatech Mega Shadow 1 x Thermalright FDB-12-1600 120mm fan |
| Power Supply | Antec CP-1000 1000W |
| Memory | G.Skill Ripjaws V DDR4-2666 C15 4x8 GB 1.2V |
| Memory Settings | JEDEC @ 2666 |
| Video Cards | ASUS GTX 980 Strix 4GB |
| Hard Drive | Crucial MX200 1TB |
| Optical Drive | LG GH22NS50 |
| Case | Open Test Bed |
| Operating System | Windows 10 Pro 64-bit |
Readers of our motherboard review section will have noted the trend in modern motherboards to implement a form of MultiCore Enhancement / Acceleration / Turbo (read our report here) on their motherboards. This does several things, including better benchmark results at stock settings (not entirely needed if overclocking is an end-user goal) at the expense of heat and temperature. It also gives in essence an automatic overclock which may be against what the user wants. Our testing methodology is ‘out-of-the-box’, with the latest public BIOS installed and XMP enabled, and thus subject to the whims of this feature. It is ultimately up to the motherboard manufacturer to take this risk – and manufacturers taking risks in the setup is something they do on every product (think C-state settings, USB priority, DPC Latency / monitoring priority, overriding memory sub-timings at JEDEC). Processor speed change is part of that risk, and ultimately if no overclocking is planned, some motherboards will affect how fast that shiny new processor goes and can be an important factor in the system build.
For reference, on the MSI X299 Gaming Pro Carbon AC, BIOS version 1.12 had MCT enabled by default.
Many thanks to...
We must thank the following companies for kindly providing hardware for our multiple test beds. Some of this hardware is not in this test bed specifically, but is used in other testing.
Thank you to ASUS for providing us with GTX 980 Strix GPUs. At the time of release, the STRIX brand from ASUS was aimed at silent running, or to use the marketing term: '0dB Silent Gaming'. This enables the card to disable the fans when the GPU is dealing with low loads well within temperature specifications. These cards equip the GTX 980 silicon with ASUS' Direct CU II cooler and 10-phase digital VRMs, aimed at high-efficiency conversion. Along with the card, ASUS bundles GPU Tweak software for overclocking and streaming assistance.
The GTX 980 uses NVIDIA's GM204 silicon die, built upon their Maxwell architecture. This die is 5.2 billion transistors for a die size of 298 mm2, built on TMSC's 28nm process. A GTX 980 uses the full GM204 core, with 2048 CUDA Cores and 64 ROPs with a 256-bit memory bus to GDDR5. The official power rating for the GTX 980 is 165W.
The ASUS GTX 980 Strix 4GB (or the full name of STRIX-GTX980-DC2OC-4GD5) runs a reasonable overclock over a reference GTX 980 card, with frequencies in the range of 1178-1279 MHz. The memory runs at stock, in this case 7010 MHz. Video outputs include three DisplayPort connectors, one HDMI 2.0 connector and a DVI-I.
Further Reading: AnandTech's NVIDIA GTX 980 Review
Thank you to Crucial for providing us with MX200 SSDs. Crucial stepped up to the plate as our benchmark list grows larger with newer benchmarks and titles, and the 1TB MX200 units are strong performers. Based on Marvell's 88SS9189 controller and using Micron's 16nm 128Gbit MLC flash, these are 7mm high, 2.5-inch drives rated for 100K random read IOPs and 555/500 MB/s sequential read and write speeds. The 1TB models we are using here support TCG Opal 2.0 and IEEE-1667 (eDrive) encryption and have a 320TB rated endurance with a three-year warranty.
Further Reading: AnandTech's Crucial MX200 (250 GB, 500 GB & 1TB) Review
Benchmark Overview
For our testing, depending on the product, we attempt to tailor the presentation of our global benchmark suite down into what users who would buy this hardware might actually want to run. For CPUs, our full test suite is typically used to gather data and all the results are placed into Bench, our benchmark database for users that want to look at non-typical benchmarks or legacy data. For motherboards we run our short form CPU tests and our system benchmark tests which focus on non-typical and non-obvious performance metrics that are the focal point for specific groups of users.
The benchmarks fall into several areas:
Short Form CPU
Our short form testing script uses a straight run through of a mixture of known apps or workloads, and requires about four hours. These are typically the CPU tests we run in our motherboard suite, to identify any performance anomalies.
| CPU Short Form Benchmarks | |
| Three Dimensional Particle Movement v2.1 (3DPM) | 3DPM is a self-penned benchmark, derived from my academic research years looking at particle movement parallelism. The coding for this tool was rough |
| The second version of this benchmark is similar to the first, however it has been re-written in VS2012 with one major difference: the code has been written to address the issue of false sharing. If data required by multiple threads, say four, is in the same cache line, the software cannot read the cache line once and split the data to each thread - instead it will read four times in a serial fashion. The new software splits the data to new cache lines so reads can be parallelized and stalls minimized. | |
| WinRAR 5.4 | WinRAR is a compression based software to reduce file size at the expense of CPU cycles. We use the version that has been a stable part of our benchmark database through 2015, and run the default settings on a 1.52GB directory containing over 2800 files representing a small website with around thirty half-minute videos. We take the average of several runs in this instance. |
| POV-Ray 3.7.1 b4 | POV-Ray is a common ray-tracing tool used to generate realistic looking scenes. We've used POV-Ray in its various guises over the years as a good benchmark for performance, as well as a tool on the march to ray-tracing limited immersive environments. We use the built-in multithreaded benchmark. |
| HandBrake v1.0.2 | HandBrake is a freeware video conversion tool. We use the tool in to process two different videos into x264 in an MP4 container - first a 'low quality' two-hour video at 640x388 resolution to x264, then a 'high quality' ten-minute video at 4320x3840, and finally the second video again but into HEVC. The low-quality video scales at lower performance hardware, whereas the buffers required for high-quality tests can stretch even the biggest processors. At current, this is a CPU only test. |
| 7-Zip 9.2 | 7-Zip is a freeware compression/decompression tool that is widely deployed across the world. We run the included benchmark tool using a 50MB library and take the average of a set of fixed-time results. |
| DigiCortex v1.20 | The newest benchmark in our suite is DigiCortex, a simulation of biologically plausible neural network circuits, and simulates the activity of neurons and synapses. DigiCortex relies heavily on a mix of DRAM speed and computational throughput, indicating that systems which apply memory profiles properly should benefit and those that play fast and loose with overclocking settings might get some extra speed up. |
System Benchmarks
Our system benchmarks are designed to probe motherboard controller performance, particularly any additional USB controllers or the audio controller. As general platform tests we have DPC Latency measurements and system boot time, which can be difficult to optimize for on the board design and manufacturing level.
| System Benchmarks | |
| Power Consumption | One of the primary differences between different motherboards is power consumption. Aside from the base defaults that every motherboard needs, things like power delivery, controller choice, routing and firmware can all contribute to how much power a system can draw. This increases for features such as PLX chips and multi-gigabit ethernet. |
| Non-UEFI POST Time | The POST sequence of the motherboard becomes before loading the OS, and involves pre-testing of onboard controllers, the CPU, the DRAM and everything else to ensure base stability. The number of controllers, as well as firmware optimizations, affect the POST time a lot. We test the BIOS defaults as well as attempt a stripped POST. |
| Rightmark Audio Analyzer 6.2.5 | Testing onboard audio is difficult, especially with the numerous amount of post-processing packages now being bundled with hardware. Nonetheless, manufacturers put time and effort into offering a 'cleaner' sound that is loud and of a high quality. RMAA, with version 6.2.5 (newer versions have issues), under the right settings can be used to test the signal-to-noise ratio, signal crossover, and harmonic distortion with noise. |
| USB Backup | USB ports can come from a variety of sources: chipsets, controllers or hubs. More often than not, the design of the traces can lead to direct impacts on USB performance as well as firmware level choices relating to signal integrity on the motherboard. |
| DPC Latency | Another element is deferred procedure call latency, or the ability to handle interrupt servicing. Depending on the motherboard firmware and controller selection, some motherboards handle these interrupts quicker than others. A poor result could lead to delays in performance, or for example with audio, a delayed request can manifest in distinct audible pauses, pops or clicks. |
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Dr. Swag - Thursday, September 21, 2017 - link
Typo on the first page, under the skylake x CPU table. It should say the gaming pro carbon not the gaming i9 :)nevcairiel - Thursday, September 21, 2017 - link
I've had the X299 Gaming Pro Carbon with a 7900X since early July when the X299 platform launched, and I'm quite happy with it. The latest BIOS update has resolved the last small annoyance I had with it, as well.Juliebattery - Saturday, September 23, 2017 - link
Have you find the correct battery for X299 in good quality and reasonable price?vgray35@hotmail.com - Thursday, September 21, 2017 - link
A PCIe 3.0 x4 interface for the DMI 3.0 link means the chipset's 24 lanes of PCIe 3.0 are being pushed though this narrow x4 link, which is really a joke as this is not a PCIe switch interface, so to think 24 lanes squished over a x4 lane DMI does not limit bandwidth is pie in the sky. The fiasco of thermal paste in the CPU causing heat problems is also a joke, so why would anybody consider the x299 platform is a viable HEDT worth considering with such poor cooling performance. VRM power delivery.using multi-phase Buck converters is pushing it beyond its realistic capabilities with 88% full load efficiency, and certainly cannot be heralded as a viable HEDT platform power supply with currents exceeding 150 Amps. All these factors combined yield a less than ideal product right out of the gate, whose cost is sky rocketing because of expensive power delivery solution, and outlandish Intel prices. To be frank, the PC industry has lost its marbles.TEAMSWITCHER - Thursday, September 21, 2017 - link
So ... you've analyzed the thermal paste yourself? Did a complete chemical work up? Used an alternative thermal compound and got 6 GHZ on air?DanNeely - Thursday, September 21, 2017 - link
Please don't feed the troll again. He created an ~40 message flamewar on the recent x399 article over his pet favorite power topology.MajGenRelativity - Thursday, September 21, 2017 - link
While I agree with Dan on feeding the troll, it is widely known that thermal paste is not as thermally conductive as solder. I refuse to comment on the rest of vgray's comment.BrokenCrayons - Thursday, September 21, 2017 - link
I don't see a problem with thermal paste between the CPU and the IHS as long as you're not pushing the CPU beyond its OEM specifications. Overclocking is done at your own risk and I see no reason why Intel should get taken to task over not supporting a person that by all rights should know they're trying to operate outside of the envelope to eek out a slightly higher benchmark score while reaping little to no real world benefit for all their effort and expenses.MajGenRelativity - Thursday, September 21, 2017 - link
Because Intel downgraded their performance that way. It also affects regular users, because lower thermal conductivity makes the fans run harder even when not overclocking. Furthermore, even without overclocking, Skylake-X can consume quite a bit of power, as mentioned in this article.MajGenRelativity - Thursday, September 21, 2017 - link
To break out my second response, overclocking isn't just for the benchmarks. In CPU limited applications, overclocking will increase your performance. A good example would be financial traders, but there are many other CPU limited applications.