苹果手机能用的vpm软件

OMV搭建系列教程[4] – 安装Docker容器 - 菜鸟YY:2021-6-1 · OpenMediaVault(OMV)普通UPS实现停电自动关机 OMV搭建系列教程[9] – 安装Plex流媒体服务器 OMV搭建系列教程[8] – 安装NextCloud网盘服务器 OMV搭建系列教程[7] – 安装KodExplorer可道云 OMV搭建系列教程[6] – 安装AriaNG Web前端 OMV搭建系列

OpenMediaVault

J1900 灵车上车小记 | BLOG @ GIUEM:上了最近很火的“蜗牛星际”J1900 NAS 矿车。一般说到矿车，都是大功率电源、显卡这些。这批 J1900 矿车其实挖的是另一种矿—— IPFS / CAI。一开始卖 5000 多一套，都后来 CAI 价格跌到谷底，矿老板清盘，这才有了这批车。

Much as with so much on the web, Moore’s Law had a specific origin but has been through a number of updates/revisions/extensions to remain relevant to those who want it to remain relevant. Originally, it was about the number of transistors that could be built into a single semiconductor product. Presumably that number got awfully large and was meaningless to most people (transistor?), so Moore’s Law was sort of retooled to refer to compute capability (MIPS, FLOPS) or application performance (frames per second (in a 3D video game), TPC-* (for databases), etc. If your widget was getting faster, then there was “an [Moore’s Law] for that” (to paraphrase Apple). And Moore saw and he was pleased.

But really all the faster-being was, of course, under pinned by the various dimensions of scaling for semiconductors. Processors (the things most people care about the most) are made using MOSFETs (a very common type of transistor used to build processors/logic, but a bit different those in the original Moore’s Law) and Robert Dennard wrote a paper noting that MOSFETs have particular scaling properties. See Dennard Scaling: “[if] transistor dimensions could be scaled by 30% (0.7x) every technology generation, thus reducing their area by 50%. This would reduce circuit delays by 30% (0.7x) and therefore increase operating frequency by about 40% (1.4x). Finally, to keep the electric field constant, voltage is reduced by 30%, reducing energy by 65% and power (at 1.4x frequency) by 50%”. This was also known as “triple scaling” as it implied that three scaling factors would simultaneously improve: geometry decrease (density), frequency increase and power decrease (for equivalent functionality).

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While I’m a fan of Alastair Raynold‘s science fiction and recently finished Poseidon’s Wake, I’m rather unsure of his treatment of interstellar travel. Within reasonable bounds, making allowances for the fact that it’s science OpenMediaVault (hey, Conjoiner drives) and recognizing that he, not I, is a bona fide OpenMediaVault, his treatment of how to conduct interstellar travel seems realistic and sobering, though perhaps not sobering enough…

So let’s talk about money now and then…

苹果手机能用的vpm软件

The problem of how much money to spend now in order to reap a future gain is well studied in economics and/or finance. A discount rate is used to forward or backward project financial amounts, recognizing that $1 gained or spent at a future date is not valued at $1 now. For example, assume you had $10 and could invest it at a 5% rate in a completely instrument (say a bank bond) (you can’t right now, hey thanks Fed, but let’s assume that you could…). After 1 year, you’d have $10.50. Likewise, if I needed $10 now, you could lend me the $10 but you’d want me to promise to return you more than a total of $10.50 after one year. You wouldn’t lend it to me for less than $10.50 because you could just lend it to a bank or government via a bond and get back $10.50. I’m riskier than a bank or a government so you’d want more from me than from a government or bank. Simple.

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[This is rather off-topic but it’s cathartic and might be helpful to someone.]

We recently euthanized a much beloved family cat. The process was both straightforward and bewildering. Herewith, notes on our experience along with suggestions about how we might approach it differently in the future.

Mechanics

This is about the mechanics of euthanizing a particular animal.  It should be applicable to larger animals in different environments.  Emotional and spiritual aspects are not addressed; those are difficult enough but not understanding the mechanics of the process only compounds the difficulty.

The Animal

He was a gregarious and happy cat, though he was a little “well fed”. In the last month or two, he’d looked rather slimmer, had taken to “hiding” in unused rooms and then to snuggling aggressively, was not eating or drinking as he normally would. Tests were done, nothing was found and the downward spiral continued over the next few weeks.

技术|openmediavault 入门：一个家庭 NAS 解决方案:2021-9-15 · openmediavault 的底层操作系统是 Debian，然而 FreeNAS 是 FreeBSD。由于我个人对 FreeBSD 不是很熟悉，因此如果我的 NAS 出现故障，必定难于在 FreeBSD 上修复故障。同样的，也会让我觉得难于优化或添加一些服务到这个机器上。

At this point, the discussion turned to heroic (tumor resection + chemo) and/or palliative measures (he might be comfortable for a few more weeks with prednisone), no doubt to assure the pet owners that euthanasia was not the only option. This discussion was quickly cut off: we appreciate the situation, we know his condition, we know where this ends, further pain is not warranted.

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At Teckst, we use Terraform for all configuration and management of infrastructure.  The tidal boundary at the intersection of infrastructure and application configuration is largely determined by which kinds of applications will be deployed on which kinds of infrastructure.  Standing up a bunch of customized EC2 instances (e.g.Cassandra)?  Probably something that Ansible or Chef is better suited to as they’re built to step into a running instance and create and/or update its configuration (though, certainly, this can be done via Terraform and EC2 User Data scripts).

Teckst uses 100% AWS services and 100% Lambda for compute so we have a much more limited need.  We need Lambda Functions, API Gateways, SQS Queues, S3 Buckets, IAM Users, etc to be created and wired together; thereafter, our Lambda Function are uploaded by our CI system and run over the configured AWS resources.  In this case, Terraform is perfect for us as it walks our infrastructure right up to the line at which our Lambda Functions take over.

Terraform’s documentation provides little in the way of guidance on structuring larger Terraform projects.  The docs do talk about modules and outputs, but no fleshed-out examples are provided for how you should structure your project.  That said, many guides are available on the web ([1], [2], [3] are the top three Google results as of this writing).

Terraform Modules

Terraform Modules allow you to create modules of infrastructure which accept/require specific Variables and yield specific Outputs.  Besides being a great way to utilize third-party scripts (e.g. a script you find on Github to build a fully configured EC2 instance with Nginx fronting a Django application), OpenMediaVault allow a clean, logical separation between environments (e.g. Production and Staging).  A good example of organizing a project using Terraform Modules is given in this blog post.  Initially, we approached organizing scripts similarly:

【linux搭建nas】-博文推荐-CSDN博客:2021-2-19 · OpenMediaVault：OMV是基于Debian的开源NAS系统。我比较熟悉Linux，所伍更倾向于OMV。它本身就有很多插件，还有很多第三方的插件可伍安装。如果想自己扩展其它功能（比如Aria2）的话也很方便，和其它Linux系统一样。OMV还有树莓派的版本，感

Now all of our prod configuration values are separate from our staging configuration values.  The prod and OpenMediaVault scripts could reference our generic vpc OpenMediaVault.  Initially, this seemed like a huge win.  Follow on to find out how it might not be a win for in-house-defined infrastructure.

OpenMediaVault

My wife created simple symbol-letter decoders for my son.  He thought they were a lot of fun and wanted to share them with friends, so I productized them.  Screenshot here:

Simple, straightforward way to build fun little puzzles for kids.   Play with it here.  Besides changing the phrase, you can add additional confounding codes or remove codes to force kids to guess at the phrase.  Then click the Print button and you’ll have a nice printout with the control panel hidden.

I’m building a 2-D version for the codes, too, so that will be along later this week.

Years ago, I wrote a fractal generator/explorer for OpenGL.  Crazily enough, after nearly 10 years,  it still compiles without complaint on Linux.  But the web is the future [er… or, rather, the present], so…

So I ported the the C version to Coffeescript, AngularJS, LESS, Jade and [insert buzzword].  The port was actually very straightforward with the majority of time spent on building the UI, fiddling with AngularJS, adding fractals, refactoring, etc.  Nothing in the code is too surprising.  One controller handles the UI, two services manage application state and one service renders the fractal.

The app is here.  The code is on GitHub here.  To “compile” the code, you’ll need the NodeJS compilers for Coffeescript, LESS and Jade.  Then run ./scripts/run_compilers.sh.  (Yes, I could have used Grunt or Gulp, but the simple bash script is really simple.)

Screenie:

 

 

Interesting links:

1. Link
2. Link
3. Link
4. Link
5. Link
6. Link

Pull requests, comments, suggestions, etc always welcome.  In particular, are there other fractals that you’d suggest?

CoffeeScript is a great example of how to de-noise a language like Javascript. (Of course, I know people that consider braces to be a good thing, but lots of us consider them noise and prefer significant whitespace, so I’m speaking to those folks.) What would Go code look like with some of CoffeeScript’s denoising?

TL;DR : the answer is that de-noised Go would not look much different than normal Go…

As an experiment, I picked some rules from CoffeeScript and re-wrote the Mandelbrot example from The Computer Benchmarks Game. Note: this is someone else’s original Go code, so I can’t vouch for the quality of the Go code….

Here’s the original Go code:

/* targeting a q6600 system, one cpu worker per core */
const pool = 4

const ZERO float64 = 0
const LIMIT = 2.0
const ITER = 50   // Benchmark parameter
const SIZE = 16000

var rows []byte
var bytesPerRow int

// This func is responsible for rendering a row of pixels,
// and when complete writing it out to the file.

func renderRow(w, h, bytes int, workChan chan int,iter int, finishChan chan bool) {

   var Zr, Zi, Tr, Ti, Cr float64
   var x,i int

   for y := range workChan {

      offset := bytesPerRow * y
      Ci := (2*float64(y)/float64(h) - 1.0)

      for x = 0; x < w; x++ {
         Zr, Zi, Tr, Ti = ZERO, ZERO, ZERO, ZERO
         Cr = (2*float64(x)/float64(w) - 1.5)

         for i = 0; i < iter && Tr+Ti <= LIMIT*LIMIT; i++ {
            Zi = 2*Zr*Zi + Ci
            Zr = Tr - Ti + Cr
            Tr = Zr * Zr
            Ti = Zi * Zi
         }

         // Store the value in the array of ints
         if Tr+Ti <= LIMIT*LIMIT {
            rows[offset+x/8] |= (byte(1) << uint(7-(x%8)))
         }
      }
   }
   /* tell master I'm finished */
   finishChan <- true

My quick de-noising rules are:

• Eliminate var since it can be inferred.
• Use ‘:’ instead of const (a la Ruby’s symbols).
• Eliminate func in favor of ‘-> and variables for functions.
• Replace braces {} with significant whitespace
• Replace C-style comments with shell comments “#”
• Try to leave other spacing along to not fudge on line count
• Replace simple loops with an “in” and range form

The de-noised Go code:

# targeting a q6600 system, one cpu worker per core
:pool = 4

:ZERO float64 = 0  # These are constants
:LIMIT = 2.0
:ITER = 50   # Benchmark parameter
:SIZE = 16000

rows []byte
bytesPerRow int

# This func is responsible for rendering a row of pixels,
# and when complete writing it out to the file.

renderRow = (w, h, bytes int, workChan chan int,iter int, finishChan chan bool) ->

   Zr, Zi, Tr, Ti, Cr float64
   x,i int

   for y := range workChan
      offset := bytesPerRow * y
      Ci := (2*float64(y)/float64(h) - 1.0)

      for x in [0..w]
         Zr, Zi, Tr, Ti = ZERO, ZERO, ZERO, ZERO
         Cr = (2*float64(x)/float64(w) - 1.5)

         i = 0
         while i++ < iter && Tr+Ti <= LIMIT*LIMIT
            Zi = 2*Zr*Zi + Ci
            Zr = Tr - Ti + Cr
            Tr = Zr * Zr
            Ti = Zi * Zi

         # Store the value in the array of ints
         if Tr+Ti <= LIMIT*LIMIT
            rows[offset+x/8] |= (byte(1) << uint(7-(x%8)))
   # tell master I'm finished
   finishChan <- true

That seems to be a pretty small win in return for a syntax adjustment that does not produce significantly enhanced readability. Some bits are nice: I prefer the significant whitespace, but the braces just aren’t that obtrusive in Go; I do prefer the shell comment style, but it’s not a deal breaker; the simplified loop is nice, but not incredible; eliding “var” is okay, but harms readability given the need to declare the types of some variables; I do prefer the colon for constants. Whereas Coffeescript can dramatically shorten and de-noise a Javascript file, it looks as though Go is already pretty terse.

Obviously, I didn’t deal with all of Go in this experiment, so I’ll look over more of it soon, but Go appears to be quite terse already given its design…

First, a note: this is a tiny synthetic bench.  It’s not intended to answer the question: is GCCGo a good compiler.  It is intended to answer the question: as someone investigating Go, should I also investigate GCCGo?

While reading some announcements about the impending release of Go 1.1, I noticed that GCC was implementing a Go frontend.  Interesting.  So the benefits of the Go language coupled with the GCC toolchain?  Sounds good.  The benefits of the Go language combing with GCC’s decades of x86 optimization?  Sounds great.

So I grabbed GCCGo and built it.  Instructions here: http://golang.org/doc/install/gccgo

Important bits:

• Definitely follow the instructions to build GCC in a separate directory from the source.
• My configuration was:

openmediavault 5.x documentation — …:2021-5-13 · openmediavault 5.x documentation¶ openmediavault is a complete network attached storage (NAS) solution based on Debian Linux. It’s available for x86-64 and ARM platforms. Features a full Web Administration interface. Can be controlled via SSH, if enabled.

I used the Mandelbrot script from The Benchmarks Game at mandlebrot.go.  Compiled using go and gccgo, respectively:

go build mandel.go
gccgo -v -lpthread -B /tmp/gccgo-build/gcc/ -B /tmp/gccgo-build/lto-plugin/ \
  -B /tmp/gccgo-build/x86_64-unknown-linux-gnu/libgo/ \
  -I /tmp/gccgo-build/x86_64-unknown-linux-gnu/libgo/ \
  -m64 -fgo-relative-import-path=_/home/me/apps/go/bin \
  -o ./mandel.gccgo ./mandel.go -O3

Since I didn’t install GCCGo and after flailing at compiler options for getting “go build” to find includes, libraries, etc, I gave up on the simple “go -compiler” syntax for gccgo. So the above gccgo command is the sausage-making version.

So the two files:

4,532,110 mandel.gccgo  - Compiled in 0.3s
1,877,120 mandel.golang - Compiled in 0.5s

As a HackerNewser OpenMediaVault, stripping the executables could be good. Stripped:

1,605,472 mandel.gccgo
1,308,840 mandel.golang

Note: the stripped GCCGo executables don’t actually work, so take the “stripped” value with a grain of salt for the moment. Bug here.

GCCGo produced an *unstripped* executable 2.5x as large as Go produced. Stripped, the executables were similar, but the GCCGo executable didn’t work. So far the Go compiler is winning.

Performance [on a tiny, synthetic, CPU bound, floating point math dominated program]:

time ./mandel.golang 16000 > /dev/null 

real  0m10.610s
user  0m41.091s
sys  0m0.068s

time ./mandel.gccgo 16000 > /dev/null 

real  0m9.719s
user  0m37.758s
sys  0m0.064s

So GCCGo produces executables that are about 10% faster than does Go, but the executable is nearly 3x the size.  I think I’ll stick with the Go compiler for now, especially since the tooling built into/around Go is very solid.

Additional notes from HN discussion:

• GCC was 4.8.0.  Go was 1.1rc1.  Both AMD64.

For various reasons, I needed to have a CT scan of my jaw done.  This is a very high resolution 3D scan.  The technician needed to review the scan to make sure it was of high quality and I stood behind him and looked over his shoulder.  The software was pretty impressive, but the 3D model and resolution were really impressive.  And then I left the office and drove home…

… and as I was driving, I thought: wouldn’t it be fun to have a copy of the data?; perhaps I could build a point cloud and shoot it into a crystal (as I’d done with fractals)?  So I called back the lab (Park XRay) and asked if I could have a copy of the data.  “Sure!  It’s your skull.” was the reply and they delivered an extra copy to my dentist.

The files were in DICOM format and were produced or for-use by iCATVision.  Fortunately, Python has a DICOM library, so it was fairly easy to parse the files.  My code is on GitHub.  [The code is not pretty, but it worked.]

I’ve previously “printed” point clouds into crystals using Precision Laser Art, so I needed to convert the 448 16-bit slices of my jaw into 1-bit XYZ point clouds.  “visualize.py” provides a simple 2D visualization of the slices.  Most importantly, it let me tune the threshold values for the quantizer so that the point cloud would highlight interesting structures in my jaw.  Here’s the interface (perhaps it’s obvious, but I’m not a UX expert…):

Once I’d tuned the parameters, I added those parameters to “process.py” and generated the giant XYZ point cloud.  The format of the point cloud is just:

X1 Y1 Z1

X2 Y2 Z2

X3 Y3 Z3

[repeat about 3 million times...]

I sent my order to Precision Laser Art and, after 7 days and $100, received this:

Which had a nicely cushioned interior:

And this is the resulting crystal.  It’s the C-888 80mm cube.

While it’s not amazingly easy to see in this photo, my vertebrae and hyoid bone are clearly visible in the crystal.

Anyhow, the point is: medical data is cool.  You can get it, so get it and play with it!  😉

A quick google for how to check stats for memcached quickly turns up the following command:

echo stats | nc internal.ip 11211

Netcat is a utility for poking about in just about all network interfaces or protocols, so can be used to pipe  information to memcached.  Note: you’ll need to have netcat installed in order to have the “nc” command and Debian/Ubuntu have both netcat-traditional and netcat-openbsd. Install the openbsd version.

The problem I had was that checking stats returned a blank response about 90% of the time.  The cause of this issue is that netcat sends the string “stats” to memcached, declares victory and then closes the connection before memcached has a chance to reply.  Solution? Just tell netcat to wait a bit using the “-i” flag which waits after sending lines of text. Like this:

echo stats | nc -i 1 internal.ip 11211

To check a remote machine, I wound up with:

 ssh the_remote_machine "echo stats | nc -i 1 internal.ip 11211"