Ultra Ramdisk
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Before: Everything stays in memory until you leave the area, then it gets written to the rolling cache. So if you just fly in different locations all the time, the rolling cache had no benefits for you and only meant more work and wear on the SSD
I was able to get a manual cache area to work. It made the area at least presentable. Without it I cannot even get enough bandwidth to load in much of the photogrammetry and bing satellite imagery. It looks horrid!
But as long as the ram usage is stalled by the game itself an ramdisk is an very good idea. I never mind that this classic would become important once again. I think the last time I used an ramdisk was on my Atari falcon (I owned the 14MB RAM card so I could allow myself that ).
Download ImDisk Toolkit for free. Ramdisk for Windows and mounting of image files. This tool will let you mount image files of hard drive, cd-rom or floppy, and create one or several ramdisks with various parameters. This all-in-one package includes...
Starting the game after clearing the ramdisk also disabled the rollingcache with this message
Simply go back to options and set it at 3.8 again (or whatever value worked with the size you made it). I guess the game rounds it up when creating a new rolling cache. However as long as the ramdisk stays up you can exit and start the game as many times as you want and it will continue using the rollingcache as created.
@BafflingBerry63 - as above - this is functionally identical, but should be much faster than loading the cache from disk. I would especially not recommend using a physical hard disk (HDD) for the rolling cache as that will be slower than SSD. So in order of speed we should have: RamDisk faster than SSD faster than HDD faster than redownload - but that last will depend on bandwidth and servers.
RAM-Disks are created out of the system memory. All read and write requests to RAM-disks are processed in memory, resulting in a huge improvement in overall performance with ultra-fast speed and ultra-low latency.
Capable of rapidly imaging the RAM-disk contents to a persistent file and restoring contents when needed. In this way RAM-disks perform like persistent storage and retain contents across computer restarts, even though the system memory is volatile. Various imaging functions and options are offered.
FAT, FAT32, exFAT and NTFS file systems are built-in, thus RAM-disks can be formatted and ready to use at very early stage during the computer boot, without the need of format scripts or imaging files.
Able to recognize the system's invisible memory and use it for RAM-disks, overcoming the Windows memory limits, especially the 4GB issue in 32-bit Windows, while allowing all installed physical memory to be fully utilized.
For a high end plotter forget nvme, lots of money that are going to waste, in my setup I have a HPE DL-580 G8 with 1TB of DDR3 to act as ramdisk for the temp1 folder, the same motherboard as you, the Asus Sage and a TR Pro 3975 and 256GB (fully manual tuned 3200 ram), the temp2 resides on local ramdisk, between the ramdisk and the plotter I have a direct infiniband connection of 100Gbit, I can plot in 18minutes, I was about to try 2 plots simultaneously but I ran out of space, soon I will be expanding the farm and do more tests but withjj your CPU and 512 you can probably do 4 at a time for most likely 20 min each, giving a beastly output, and most important you can plot an infinite number of plot for less money than all that nvmes
I understand what your saying. I originally went with the 3955x over other AMD/Intel builds based on the TDP and expansion. Now that i climbed into the 95, xch is childs play to what you can actually accomplish with it. I wouldnt say go out and buy high end 64c cpus just to plot. You can get a k32 a day on a RPi lmao. 20min plots on 2697 v3 headless with 128g+ ddr4 ram is well under 2k.
You both are rational & pretty spot on re: choices between systems. I might add that I found the 3955x underwhelming using the authentic chia plot GUI in Windows. I went from 11 PPD on a Ryzen 3600 to only 30 PPD on the TR 3955 pro, even with 144GB memory. It made more plots possible, but not so very impressive considering the TR was >$2K. Plus too much effort to manage getting even that.
A small program that allows you to create a new drive on your hard drive by using the RAM on your computer. The hardware setup impacts the speed with which various applications execute on your computer.
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The memory-optimized machine family provides the most compute and memoryresources of any Compute Engine machine family offering. They areideal for workloads that require higher memory-to-vCPU ratios than thehigh-memory machine types in the general-purpose machine series.
The X4, M3, M2, and M1 machine series offer the lowest cost per GB of memory onCompute Engine, making them a great choice for workloads that utilizehigher memory configurations with low compute resources requirements.Additionally, M2 and M1 offer savings of up to 30% with sustained use discounts.X4, M3, M2, and M1 are also eligible forcommitted use discounts (CUDs),that bring savings of greater than 60% in exchange for 3-year commitments.
The X4 machine series offers more storage and networking options to support yourmost demanding workloads. The X4 machine series offers three predefined machinetypes. These machine types provide you with the capability to provision baremetal instances with up to 1920 vCPUs and up to 32 TB of RAM.
X4 instances are powered by the 4th generation Intel Xeon Scalable processors(code-named Sapphire Rapids) and Titanium.X4 instances use only the NVMe disk interface for storage, and can be used withonly Google Cloud Hyperdisk storage. X4 instancesuse a version of the IntelInfrastructure Data Plane Function (IDPF) driverthat has been optimized for use with Google Cloud. VirtIO-net, gVNIC, and SCSIinterfaces are not supported.
X4 bare metal instances require theIntel IDPF LAN PF device driver.X4 supports up to 100 Gbps network bandwidth for standardnetworking and up to 200 Gbps with per VM Tier_1 networking performance.The gVNIC network interfaceisn't supported with bare metal instances.
Before migrating to X4 or creating X4 instances,make sure that theoperating system imagethat you use is fully supported for X4. Fully supported imagesinclude the IDPF network driver. If you create an X4 instance with anoperating system that doesn't support the IDPF driver, then you might not beable to connect to the instance.
The M3 machine series introduces two new OLAP shapes for 2 TiB and 1 TiBSAP HANA systems. These machine types allow you to provision up to 128 vCPUs andup to 4 TB of RAM. M3 VMs use only NVMe for storage, and supportHyperdisk Balanced storage. M3 machines use onlygVNIC for networking.VirtIO-net and SCSI interfaces are not supported.
Pricing for these VMs per vCPUhour and per GB of memory is similar to the pricing for M1 VMs. Disk usageand network usage is charged separately from machine type pricing.For details, see Disk and imagepricing and Network pricing.
M3 VMs support on-demand pricing, 1-year and 3-year CUDs. The commitment typethat you must use to purchase M3 VMs is separate fromthe one for M1 or M2 VMs. You can purchase a single commitment tocover both M1 and M2 VMs, but you can't group M3 VMs in that commitment.For more information, see theCommitment typessection for resource-based commitments.
The M2 series is available with on-demand pricing for anevaluation period only. Long running usage requires purchasing a committed usediscount. For more information, see theVM pricing page.Disk usage and network usage is charged separately from machine type pricing.For details, see Disk and imagepricing and Network pricing.
The M1 machine series is the older generation memory-optimized machine seriesthat offers 14.9 to 24 GB of memory per vCPU. This series offers them1-ultramem and m1-megamem machine types and are only available in specificregions and zones.
Except as otherwise noted, the content of this page is licensed under the Creative Commons Attribution 4.0 License, and code samples are licensed under the Apache 2.0 License. For details, see the Google Developers Site Policies. Java is a registered trademark of Oracle and/or its affiliates.
This driver provides support for four kinds of memory backed virtual disks: malloc, preload, vnode, swap. Disks may be created with the next command line tools: mdconfig and mdmfs. An example of how to use these programs follows.[3]
RapidDisk is a free and open source project containing a Linux kernel module and administration utility that functions similar to the Ramdiskadm of the Solaris (operating system). With the rxadm utility, the user is capable of dynamically attaching, removing, and resizing RAM disk volumes and treat them like any other block device.[4]
There are 2 differences between tmpfs and ramfs.[7]
1) the mounted space of ramfs is theorically infinite, as ramfs will grow if needed, which can easily cause system lockup or crash for using up all available memory, or start heavy swapping to free up more memory for the ramfs. For this reason limiting the size of a ramfs area can be recommendable.
2) tmpfs is backed by the computer's swap space
There are also many "wrappers" for the RAM disks for Linux as Profile-sync-daemon (psd) and many others allowing users to utilize RAM disk for desktop application speedup moving intensive IO for caches into RAM.
ImDisk Virtual Disk Driver is a disk image emulator created by Olof Lagerkvist. It is free and open-source software, and is available in 32- and 64-bit variants. It is digitally signed, which makes it compatible with 64-bit versions of Microsoft Windows without having to be run in Test mode. The 64-bit version has no practical limit to the size of RAM disk that may be created.
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