236 lines
13 KiB
Markdown
236 lines
13 KiB
Markdown
---
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title: "Our Home Server Build-Out Log Part 1: Speccing It Out"
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date: 2022-10-31T17:00:00+11:00
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draft: false
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showSummary: true
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summary: "We've wanted to build a home lab for a long time. Here's how it went."
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---
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# Part One: Specification
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## Background
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We've wanted to build a home lab for a long, long time, but never got around to it.
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**(Selene)** However, a certain someone was complaining about disaster recovery and migrating workloads to us,
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and that turned out to be just the push we needed to get this rolling.
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Since we also want to do more blogging and community contribution, why not make this the inaugural post on our new blog?
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**(Lorelai)** So, let's get this show on the road, shall we?
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## The Use-Case
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So what did we need from this server? After talking over with friends, the following use-cases came to mind:
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- Storage Cluster (ZFS of some kind)
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- Foundry VTT Server
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- [chibisafe](https://github.com/chibisafe/chibisafe) Server
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- Modded Minecraft Server ?
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- Generic cloud host for friends
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## The Spec
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We wanted this server to be the basis for a home lab that could later be expanded, so we want it to have a decent amount of oomph.
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After deliberating on it for a while, we decided on the following:
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| Part | Spec |
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| ----------- | ----------------------------------------------------------- |
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| CPU | Min. 16 core/32 thread |
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| Motherboard | Must support large amounts of RAM and have BMC/IPMI |
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| RAM | Moderate speed, 128GB to start, more to be added |
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| Storage | At least 32 TB usable, 2 redundant disks min., 1 hot spare |
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| Networking | Min. 2 ✕ 1Gbps management, 2 ✕ 40Gbps data |
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### But Why?
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**(Selene)** I'm no techie, but this all seems rather excessive for a home server. Especially compared to people we know.
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**(Ashe)** You're not wrong there, Selene. I could wax lyrical about how I want this server to last a long time and be
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useful for many different things and so on and so forth, but if we're being honest, the main reason is "Tech shiny!"
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**(Tammy)** So the same reason we've always gotten high spec PCs, really.
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## Fulfilling the Spec
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Now that we have a spec, we need to figure out the best way to fulfill it.
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### The Case
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This would normally be something to consider carefully, but a good friend was getting rid of a 3U server case with
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12 3.5" bays, so we'll nick that off of him, and move on. He also donated us a few
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[Arctic P12s](https://www.arctic.de/en/P12/ACFAN00118A) for cooling as they'll be quieter than the jet engines
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that came with the case.
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### The PSU
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We have a spare 750W Silverstone 80+ Platinum PSU lying around the house from an old PC, so we'll just repurpose that here.
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### The Storage
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It's probably strange to start with the storage, but we'll need to know how much storage we have to spec out
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the ZFS instance properly.
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#### The Goal
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The goal is to have a scaleable template that can be expanded in sets without breaking the bank each time,
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while maintaining favourable failure characteristics. We'll budget out 3000 AUD for each expansion.
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**(Doll)** That sounds like a lot, Miss...
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**(Ashe)** It's a good chunk, yes. But this should, ideally, only happen every few years, so we can amortise this
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over the life of the storage.
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We have 12 3.5" slots in our 3U compute case, and most storage arrays are either 24 or 36 bay, so planning around
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12 unit slices seems logical.
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If we round up and call it 3600 AUD per slice, we get ~300 AUD per HDD.
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At time of writing, the best $/GB is 16TB Seagate Exos drives. We picked up 6 a year ago when exchange rates
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weren't so miserable, and will be picking up another 6 to round out this cluster after the new year.
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This overshoots our budget by about 25%, but there's little to be done about exchange rates.
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We can, however, expect these to fall in price over time,
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so this will likely be within budget by the time we need another slice.
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#### RAID Layout
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[dRAID](https://openzfs.github.io/openzfs-docs/Basic%20Concepts/dRAID%20Howto.html) came to OpenZFS a while back,
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and has improved resilver times compared to Z1/Z2/Z3, as well as allowing for much more granular redundancy design,
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so we'll be using that.
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The Seagate Exos drives are specc'd at ~200MB/s peak write rate, which gives us a resilver time of just over 22 hours in
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traditional Z1/Z2/Z3. And that's 22 hours of every other drive in the array getting hammered. This is the main reason
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we're going to be using dRAID. Under dRAID, we specify a number of data, parity, and spare slices, which are distributed
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amongst the physical drives.
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In our case, we want at least one, maybe two, hot-spare slices to make best use of dRAID.
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This leaves us with 10 or 11 slices to play with.
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With 11 usable slices our best bet would probably be 8/3/1 (8 data, 3 parity, 1 hot-spare), where as with 10 usable slices,
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we'd probably want to go for either 7/3/2, or 8/2/2.
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7/3/2 is certainly the safest set-up, as it gives us 3 parity slices and two hot-spares, potentially allowing for
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5 HDD failures before data-loss occurs. However this is over-conservative for the pool that we'll be building out initially.
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This pool won't be the only storage location for critical data, so we can afford to be a little more aggressive
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with our dRAID setup, so we're left with 8/2/2, or 8/3/1.
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These can both tolerate 4 sequential drive failures, however 8/2/2 has a slightly higher write and resilver speed
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at the cost of tolerating less concurrent failures (2 at a time vs 3 at a time).
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With how large spinning rust drives can get these days (18 - 20 TB each), two parity slices feels a little sketchy, so
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we'll go with 8/3/1 as our template.
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#### ZIL/L2ARC
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We'll also need a ZIL and L2ARC device, which we can use some SSDs for.
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We can also use these drives as a read cache. The recommendation is two use two mirrored drives for this
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for resilience reasons, so we'll do that too. We'll want something with relatively high IOPS for this, as well as
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good random IO speeds.
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In theory, we could go hog wild and get Intel Optane and never worry about it again, but that's...
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prohibitively expensive to put it lightly.
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Again, balancing cost and performance, 2 ✕ 500GB Seagate FireCuda 530s does the job well. Relatively high endurance,
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good random IO performance, and not too expensive. Two of these sets us back 600 AUD.
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#### Final Storage Configuration
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Our final storage array consists of 12 ✕ 16 TB Seagate Exos Drives, and 2 ✕ 500GB Seagate FireCuda 530s.
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With 8 data slices, 3 parity slices, and 1 hot spare slice, we should end up with approximately 110 TB of usable space.
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### The CPU
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We're going to make an executive decision and go with an AMD EPYC CPU, because we've always wanted to use one.
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That said, we have a few options:
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| Model | Generation | RRP (USD) | Cores (threads) | Clock (GHz) | L3 Cache (MB) | TDP (W) |
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| -------- |:----------:|:---------:|:---------------:|:-------------:|:-------------:|:-------:|
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| 7272 | Rome | 625 | 12 (24) | 2.9 - 3.2 | 64 | 120 |
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| 7302 | Rome | 978 | 16 (32) | 3.0 - 3.3 | 128 | 155 |
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| **7352** | **Rome** | **1350** | **24 (48)** | **2.3 - 3.2** | **128** | **155** |
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| 7402 | Rome | 1783 | 24 (48) | 2.8 - 3.35 | 128 | 180 |
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| 7F72 | Rome | 2450 | 24 (48) | 3.5 - 3.9 | 192 | 240 |
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| 7452 | Rome | 2025 | 32 (64) | 2.35 - 3.35 | 128 | 155 |
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| 7453 | Milan | 1570 | 28 (56) | 2.75 - 3.45 | 64 | 225 |
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| 7413 | Milan | 1825 | 24 (48) | 2.85 - 4.00 | 128 | 200 |
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| 7513 | Milan | 2840 | 32 (64) | 2.6 - 3.65 | 128 | 200 |
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The odd one out here is the `7F72`, which is a frequency-optimised model, designed for maximum performance per core,
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to get around per-core licensing issues in enterprise applications. While cool, it being nearly double the price
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of the comparable `7352` puts it outside our budget for this particular build.
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Balancing Price and Performance, we've decided to go with a `AMD EPYC 7352`, as 24/48 exceeds our spec, and doesn't break
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the bank while doing so. We miss out on some of the performance of the Milan line, but that's acceptable here.
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The SP3 socket also allows us to upgrade to Milan(-X) down the line if we need more performance (with a BIOS update).
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Shipped to a friend, this sets us back ~1500 AUD.
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### The Motherboard
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With our CPU chosen, we need a motherboard that fulfills our purposes.
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Of the options, we are looking for something with an
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IPMI/BMC, and dual Ethernet interfaces onboard, as our data port requirement can be fulfilled by a PCIe network card.
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8 SATA ports under one SATA controller would be nice, as it makes configuring passthrough for ZFS easier, but is not
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essential.
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The `AsRock Rack ROMED8U-2T` serves our purposes perfectly:
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- [X] 8 ✕ DIMM slots
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- [X] 11 ✕ SATA (2 ✕ mini-SAS)
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- [X] Some amount of PCIe Slots (3)
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- [X] 2 ✕ 10GbE + 1 ✕ IPMI
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We don't *need* 10GbE for our management network, but this allows us to build this out with 2 ✕ 10GbE for data, and
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upgrading to 2 ✕ 40GbE later, which may be what we end up doing.
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New from Newegg, this sets us back ~1100 AUD.
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### The RAM
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There are two ways we can estimate how much RAM we'll need.
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- Total RAM required by all planned VMs
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- RAM per vCPU
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#### RAM by VM
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1. Foundry Server
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* 8GB will be plenty for this
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2. Chibisafe
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* Chibisafe prides itself on running slim, so we should be able to go down to even 1 or 2 GB
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3. ZFS Storage Cluster
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* The extremely conservative guideline (as published by Sun back in the day) is 1GB RAM per TB of storage.
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This guideline was published with the idea that at the level you should *never* encounter any bottlenecks or issues.
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* We do not need such a strict performance guarantee.
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* We should be able to halve or even quarter this and not encounter bottlenecks.
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* We'll initially provision 32GB, and adjust as necessary.
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4. Modded Minecraft Server
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* 16 - 32 GB is the rough ballpark for good performance with 8 - 16 players
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* This is likely overkill for this, so we can dial it back to 12GB with some GC tuning on the server end
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So that totals up to 8 + 2 + 32 + 12 = 54 GB.
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We want to allow room for growth and for friends to start their own VMs, so the next logical stepping stones are 64 or 128 GB.
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#### Total Required RAM
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We have 48 vCPUs in our current setup (with no overcommit, but more on that later).
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Very broadly, most environments that we've had exposure to allocate approximately 4GB/vCPU, and adjust based on how
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CPU-hungry or memory-hungry a particular workload is.
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Since we're expecting mixed workloads (from friends), we'll follow the same guideline of 4GB RAM per vCPU,
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so we'll need at least 4 ✕ 48 = 192GB. With 8 slots on the mobo,
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that means we'll have to use 32GB modules (or 64GB modules if we feel like going overboard).
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Our motherboard comes with 8 RAM slots and the Rome EPYC CPUs support octo-channel RAM, so we'd get
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the best performance from fully populating the RAM slots.
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This however makes upgrading painful, so we're going to go with 4 ✕ 32GB @ 2400MHz for 128GB total for now, which sets
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us back ~1000 AUD.
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## The Damage
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All up, we've settled on:
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| Component | Selected Part | Cost (AUD) | Running Total (AUD) |
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|:--------------:|:----------------------------------------------------:|:---------------:|:-------------------:|
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| 3U Server Case | Who Even Knows? | FREE! | 0 |
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| PSU | SilverStone 750W Platinum <br /> (SST-SX750-PT) | FREE! | 0 |
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| CPU | AMD EPYC 7352 <br /> (24 core / 48 thread) | 1500 | 1500 |
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| RAM | 4 ✕ 32GB@2400MHz <br /> (M393A4K40CB1-CRC) | 4 ✕ 250 = 1000 | 2500 |
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| Mass Storage | 12 ✕ 16TB Seagate Exos <br /> (1ST16000NM001G) | 12 ✕ 400 = 4800 | 7300 |
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| ZIL/L2ARC SSDs | 2 ✕ 500GB Seagate FireCuda 530 <br /> (ZP500GM3A013) | 2 ✕ 300 = 600 | 7900 |
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| Motherboard | AsRock Rack ROMED8U-2T | 1100 | 9000 |
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So just shy of 10,000 AUD. It's a hefty price tag, but worth it in our opinion.
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## Next Time!
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With all that decided upon, ordered, all we have to do now is wait for it to arrive.
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Join us again next time for the actual build log!
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**(Doll)** This one is super excited to see Miss' build the nyoomy server!
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