CPU Tests: Encoding

One of the interesting elements on modern processors is encoding performance. This covers two main areas: encryption/decryption for secure data transfer, and video transcoding from one video format to another.

In the encrypt/decrypt scenario, how data is transferred and by what mechanism is pertinent to on-the-fly encryption of sensitive data - a process by which more modern devices are leaning to for software security.

Video transcoding as a tool to adjust the quality, file size and resolution of a video file has boomed in recent years, such as providing the optimum video for devices before consumption, or for game streamers who are wanting to upload the output from their video camera in real-time. As we move into live 3D video, this task will only get more strenuous, and it turns out that the performance of certain algorithms is a function of the input/output of the content.

HandBrake 1.32: Link

Video transcoding (both encode and decode) is a hot topic in performance metrics as more and more content is being created. First consideration is the standard in which the video is encoded, which can be lossless or lossy, trade performance for file-size, trade quality for file-size, or all of the above can increase encoding rates to help accelerate decoding rates. Alongside Google's favorite codecs, VP9 and AV1, there are others that are prominent: H264, the older codec, is practically everywhere and is designed to be optimized for 1080p video, and HEVC (or H.265) that is aimed to provide the same quality as H264 but at a lower file-size (or better quality for the same size). HEVC is important as 4K is streamed over the air, meaning less bits need to be transferred for the same quality content. There are other codecs coming to market designed for specific use cases all the time.

Handbrake is a favored tool for transcoding, with the later versions using copious amounts of newer APIs to take advantage of co-processors, like GPUs. It is available on Windows via an interface or can be accessed through the command-line, with the latter making our testing easier, with a redirection operator for the console output.

We take the compiled version of this 16-minute YouTube video about Russian CPUs at 1080p30 h264 and convert into three different files: (1) 480p30 ‘Discord’, (2) 720p30 ‘YouTube’, and (3) 4K60 HEVC.

(5-1a) Handbrake 1.3.2, 1080p30 H264 to 480p Discord(5-1b) Handbrake 1.3.2, 1080p30 H264 to 720p YouTube(5-1c) Handbrake 1.3.2, 1080p30 H264 to 4K60 HEVC

7-Zip 1900: Link

The first compression benchmark tool we use is the open-source 7-zip, which typically offers good scaling across multiple cores. 7-zip is the compression tool most cited by readers as one they would rather see benchmarks on, and the program includes a built-in benchmark tool for both compression and decompression.

The tool can either be run from inside the software or through the command line. We take the latter route as it is easier to automate, obtain results, and put through our process. The command line flags available offer an option for repeated runs, and the output provides the average automatically through the console. We direct this output into a text file and regex the required values for compression, decompression, and a combined score.

(5-2c) 7-Zip 1900 Combined Score

AES Encoding

Algorithms using AES coding have spread far and wide as a ubiquitous tool for encryption. Again, this is another CPU limited test, and modern CPUs have special AES pathways to accelerate their performance. We often see scaling in both frequency and cores with this benchmark. We use the latest version of TrueCrypt and run its benchmark mode over 1GB of in-DRAM data. Results shown are the GB/s average of encryption and decryption.

(5-3) AES Encoding

WinRAR 5.90: Link

For the 2020 test suite, we move to the latest version of WinRAR in our compression test. WinRAR in some quarters is more user friendly that 7-Zip, hence its inclusion. Rather than use a benchmark mode as we did with 7-Zip, here we take a set of files representative of a generic stack

  • 33 video files , each 30 seconds, in 1.37 GB,
  • 2834 smaller website files in 370 folders in 150 MB,
  • 100 Beat Saber music tracks and input files, for 451 MB

This is a mixture of compressible and incompressible formats. The results shown are the time taken to encode the file. Due to DRAM caching, we run the test for 20 minutes times and take the average of the last five runs when the benchmark is in a steady state.

For automation, we use AHK’s internal timing tools from initiating the workload until the window closes signifying the end. This means the results are contained within AHK, with an average of the last 5 results being easy enough to calculate.

(5-4) WinRAR 5.90 Test, 3477 files, 1.96 GB

CPU Tests: Rendering CPU Tests: Legacy and Web
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  • lmcd - Monday, November 9, 2020 - link

    A great dane weighs twice as much as a bulldog so... Reply
  • Xyler94 - Thursday, November 5, 2020 - link

    Even if Intel could... I highly doubt they'd be able to legally speaking, since that would literally be burning out competition in terms of CPU, and even Silicon productions... Reply
  • Morawka - Friday, November 6, 2020 - link

    Intel would be better served luring TSMC's process engineers over. Most of the good ones have already been scooped up by China though. Reply
  • bmacsys - Monday, November 9, 2020 - link

    Really dude. I suppose you know this firsthand? Reply
  • lmcd - Monday, November 9, 2020 - link

    China's mainland fab efforts would not be as far as they are otherwise. Reply
  • Qasar - Monday, November 9, 2020 - link

    and you have proof of this ? or is it just your opinion ? Reply
  • ze_banned_because_at - Tuesday, November 10, 2020 - link

    Not that hard to google for "tsmc engineers poached by china". Reply
  • RogerAndOut - Thursday, November 5, 2020 - link

    Well before any bid premium, TSMC has a market value of over $400B and so is far larger than Intel's total worth of around $240B. It would be somewhat cheaper for Intel to just buy up all of the TSMC production capacity that it can for a few years. This would allow Intel to limit the production of other players, while also giving them a chance to produce some chips that are worth buying. Reply
  • Thanny - Thursday, November 5, 2020 - link

    TMSC would never allow that while Intel was a competitor. Buy up all their capacity, getting rid of their customers? Then what happens when Intel stops buying their capacity? Unless Intel spun off its fabs (which is extremely unlikely), TSMC will treat them as a competitor. Intel can make some things at TSMC, but not to the extent that it erodes TSMC's customer base. Reply
  • Spunjji - Sunday, November 8, 2020 - link

    Exactly this. Amazing how fee pro-Intel commenters can do big picture thinking. Reply

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