CFast (CompactFast), introduced in 2008, is a variant of CompactFlash (CF). The main update is the use of a Serial ATA (SATA) interface instead of PATA. The initial verion was based on SATA II and topped out at 300 MBps theoretically. In 2012, CFast 2.0 was introduced. It updated the electrical interface to SATA III (600 MBps). The transition from CF to CFast has been quite slow, with most camera manufacturers believing that CF cards still offer them enough performance. CFast slots are current found in a number of high-end camera and camcorder models .
SanDisk's Extreme PRO CFast 2.0 lineup has 64GB, 128GB, and 256GB versions. This section reviews the 64GB version.
Sequential Accesses
SanDisk claims speeds of up to 525 MBps writes and 450 MBps reads, but real-world speeds are bound to be lower. For most applications, that really doesn't matter as long as the card is capable of sustaining the maximum possible rate at which the camera it is used in dumps data. We use fio workloads to emulate typical camera recording conditions. We run the workload on a fresh card, and also after simulating extended usage. Instantaneous bandwidth numbers are graphed. This gives an idea of performance consistency (whether there is appreciable degradation in performance as the amount of pre-existing data increases and / or the card is subject to wear and tear in terms of amount and type of NAND writes). Further justification and details of the testing parameters are available here.
We find that the card is subject to severe slowdown after extended usage. Our only other comparison point is a 128GB CFast 2.0 card from Lexar, and comparing different capacity points doesn't provide us with the full picture. Suffice to say that the SanDisk CFast 2.0 card needs to provide better write consistency even in the out-of-the-box state.
AnandTech DAS Suite - Performance Consistency
The AnandTech DAS Suite involves transferring large amounts of photos and videos to and from the storage device using robocopy. This is followed by selected workloads from PCMark 8's storage benchmark in order to evaluate scenarios such as importing media files directly into multimedia editing programs such as Adobe Photoshop. Details of these tests from the perspective of memory cards are available here.
In this subsection, we deal with performance consistency while processing the robocopy segment. The graph below shows the read and write transfer rates to the memory card while the robocopy processes took place in the background. The data for writing to the card resides in a RAM drive in the testbed. The first three sets of writes and reads correspond to the photos suite. A small gap (for the transfer of the videos suite from the primary drive to the RAM drive) is followed by three sets for the next data set. Another small RAM-drive transfer gap is followed by three sets for the Blu-ray folder. The corresponding graphs for similar cards that we have evaluated before is available via the drop-down selection.
Here, we can see the difference in consistency in the beginning. The photos start getting transferred at around 175 MBps, but, even in the second repetition, we see that the transfer rates are slower. Thankfully, after the initial burst, the rates do hold up. The behavior is similar to the Lexar card, but, the absolute numbers are lower.
AnandTech DAS Suite - Bandwidth
The average transfer rates for each workload from the previous section is graphed below. Readers can get a quantitative number to compare the SanDisk Extreme PRO CFast 2.0 64GB CFast card against the ones that we have evaluated before.
We also look at the PCMark 8 storage bench numbers in the graphs below. Note that the bandwidth number reported in the results don't involve idle time compression. Results might appear low, but that is part of the workload characteristic. Note that the same testbed is being used for all memory cards. Therefore, comparing the numbers for each trace should be possible across different cards.
Performance Restoration
The traditional memory card use-case is to delete the files on it after the import process is completed. Some prefer to format the card either using the PC, or, through the options available in the camera menu. The first option is not a great one, given that flash-based storage devices run into bandwidth issues if garbage collection (processes such as TRIM) is not run regularly. Different memory cards have different ways to bring them to a fresh state.Based on our experience, CFast cards have to be formatted using the CFast Sanitize Tool from the card vendor.
In order to test out the effectiveness of the performance restoration process, we run the default sequential workloads in CrystalDiskMark before and after the formatting. Note that this is at the end of all our benchmark runs, and the card is in a used state at the beginning of the process. The corresponding screenshots for similar cards that we have evaluated before is available via the drop-down selection.
The CrystalDiskMark benchmark doesn't bring out the full extent of the performance loss in the used case. We saw that earlier in this section. The numbers above show that some of the loss is reclaimed, but, our traditional sequential access test reveals whether the performance restoration is really successful.
We see that the refreshed performance is very similar to the out of the box performance. This shows that it is important to regularly run the sanitize tool for the CFast cards.
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