Algorithms like GCRA and leaky bucket don’t allow you to separate
these two points because they don’t measure the client’s rate as a
concrete number.
A moving average allows more flexible policy enforcement because the
rate measurement is meaningful even when you don’t apply
back-pressure. For example, it’s useful in a dry run mode, or when
diverting messages to a quarantine.
An exponential rate limiter stores, for each client:
last update time
average rate
This is a similar amount of space as leaky bucket. GCRA uses less
space because it only needs to store a time.
The main disadvantage is that an exponential rate limiter needs fairly
complicated floating point arithmetic.
GCRA is the “generic cell rate algorithm”, a rate-limiting algorithm
that came from ATM. GCRA does the same job as the better-known
leaky bucket algorithm, but using half the storage and with much less
code.
GCRA only stores one time stamp per sender, whereas leaky buckets need
to store a time stamp and a quota.
GCRA needs less arithmetic, and makes it trivial to tell a client how
long it should wait before the next request is permitted.
no, because the C abstract machine is a (large) finite state
machine,
or maybe yes, if you believe that unaddressable local variables
can exist outside the finite address space, and you can have an
unbounded number of them, i.e. no.
My answer is definitely yes, if you include the standard IO library.
And using IO is much closer to Turing’s original model of a finite
state machine working on unbounded peripheral storage.
I’m pleased that so many people enjoyed my previous blog post on
tolower() with AVX-512. Thanks for all the great comments and
discussion!
One aspect that needed more work was examining the performance for
small strings. The previous blog post had a graph for strings up to
about 1000 bytes long, mainly because it illustrated some curious
behaviour – but that distracted me from what I really care about,
which is strings up to about 100 bytes long, 10x smaller.
Eventually I managed to get some numbers that I think are plausible.
A couple of years ago I wrote about tolower() in bulk at speed using
SWAR tricks. A couple of days ago I was interested by Olivier
Giniaux’s article about unsafe read beyond of death, an
optimization for handling small strings with SIMD instructions, for a
fast hash function written in Rust.
I’ve long been annoyed that SIMD instructions can easily eat short
strings whole, but it’s irritatingly difficult to transfer short
strings between memory and vector registers. Oliver’s post caught my
eye because it seemed like a fun way to avoid the problem, at least
for loads. (Stores remain awkward!)
Semaphores are one of the oldest concurrency primitives in
computing, invented over 60 years ago. They are weird: usually the
only numbers of concurrent processes we care about are zero, one, or
many – but semaphores deal with those fussy finite numbers in
between.
Yesterday I was writing code that needed to control the number of
concurrent operating system processes that it spawned so that it
didn’t overwhelm the computer. One of those rare situations when a
semaphore is just the thing!
a Golang channel is a semaphore
A Golang channel has a buffer size – a number of free slots – which
corresponds to the initial value of the semaphore. We don’t care about
the values carried by the channel: any type will do.
var semaphore := make(chan any, MAXPROCS)
The acquire operation uses up a slot in the channel. It is
traditionally called P(), and described as decrementing the value of
the semaphore, i.e. decrementing the number of free slots in the
channel. When the channel is full this will block, waiting for another
goroutine to release the semaphore.
func acquire() {
semaphore <- nil
}
The release operation, traditionally called V(), frees a slot in
the channel, incrementing the value of the semaphore.
func release() {
<-semaphore
}
That’s it!
the GNU make jobserver protocol is a semaphore
The GNU make -j parallel builds feature uses a semaphore in the
form of its jobserver protocol. Occasionally, other programs
support the jobserver protocol too, such as Cargo. BSD make -j
uses basically the same semaphore implementation, but is not
compatible with the GNU make jobserver protocol.
The make jobserver semaphore works in a similar manner to a Golang
channel semaphore, but:
instead of a channel, make uses a unix pipe;
because make can’t control the amount of free space in a
pipe’s buffer, the value of the semaphore is represented as the
amount of used space in the pipe’s buffer;
the value of the semaphore can’t be more than PIPE_BUF, to
ensure that release() will never block.
Here’s a C-flavoured sketch of how it works. To create a semaphore and
initialize its value, create a pipe and write that many characters to
it, which are buffered in the kernel:
int fd[2];
pipe(fd);
char slots[MAXPROCS] = {0};
write(fd[1], slots, sizeof(slots));
To acquire a slot, read a character from the pipe. When the pipe is
empty this will block, waiting for another process to release the
semaphore.
char slot;
read(fd[0], &slot, 1);
To release a slot, the worker must write the same character back to
the pipe:
write(fd[1], &slot, 1);
Error handling is left as an exercise for the reader.
bonus: waiting for concurrent tasks to complete
If we need to wait for everything to finish, we don’t need any extra
machinery. We don’t even need to know how many tasks are still
running! It’s enough to acquire all possible slots, which will block
until the tasks have finished, then release all the slots again.
func wait() {
for range MAXPROCS {
acquire()
}
for range MAXPROCS {
release()
}
}
Lemire’s nearly-divisionless algorithm unbiased bounded random
numbers has a fast path and a slow path. In the
fast path it gets a random number, does a multiplication, and a
comparison. In the rarely-taken slow path, it calculates a remainder
(the division) and enters a rejection sampling loop.
When Lemire’s algorithm is coupled to a small random number generator
such as PCG, the fast path is just a handful of instructions. When
performance matters, it makes sense to inline it. It makes less sense
to inline the slow path, because that just makes it harder for the
compiler to work on the hot code.
Lemire’s algorithm is great when the limit is not a constant (such as
during a Fisher-Yates shuffle) or when the limit is not a power of
two. But when the limit is a constant power of two, it ought to be
possible to eliminate the slow path entirely.
more lenient handling of trailing . in domain names on the command line
avoid dividing by zero when the refresh interval is less than 10 seconds
do not error out when in TCP mode and debug mode and the refresh timer expires
explain how to fix incomplete github forks
Many thanks to Lars-Johann Liman, JP Mens, and Jonathan Hewlett for
the bug reports. I like receiving messages that say things like,
thanks for nsnotifyd, is a great little program, and a good
example of a linux program, does one thing well.
(There’s more like that in the nsnotifyd-2.0 release annoucement.)
I have also included a little dumpaxfr program, which I wrote when
fiddling around with binary wire format DNS zone transfers. I used the
nsnotifyd infrastructure as a short cut, though dumpaxfr doesn’t
logically belong here. But it’s part of the family, so I wrote a
dumpaxfr(1) man page and included it in this release.
I will be surprised if anyone else finds dumpaxfr useful!
Yesterday I received a bug report for regpg, my program that
safely stores server secrets encrypted with gpg so they can be
commited to a git repository.
The bug was that I used the classic shell pipeline find | xargs grep
with the classic Unix “who would want spaces in filenames?!” flaw.
I have pushed a new release, regpg-1.12, containing the bug fix.
There’s also a gendnskey subcommand which I used when doing my
algorithm rollovers a few years ago. (It’s been a long time since the
last regpg release!) It’s somewhat obsolete, now I know how to use
dnssec-policy.
A bunch of minor compatibility issues have crept in, which mostly
required fixing the tests to deal with changes in Ansible, OpenSSL,
and GnuPG.
My most distressing discovery was that Mac OS crypt(3)
still supports only DES. Good grief.
There are a couple of version control commands that deserve wider
appreciation: SCCS what and RCS ident. They allow
you to find out what source a binary was built from, without having to
run it – handy if it is a library! They basically scan a file looking
for magic strings that contain version control metadata and print out
what they discover.
Here are some miscellaneous unsorted notes about BIND9’s
dnssec-policy that turned out not to be useful in my previous blog
posts, but which some readers might find informative. Some of them I
learned the hard way, so I hope I can make it easier for others!
Here are some notes on migrating a signed zone from BIND’s old
auto-dnssec to its new dnssec-policy.
I have been procrastinating this migration for years, and I avoided
learning anything much about dnssec-policy until this month. I’m
writing this from the perspective of a DNS operator rather than a BIND
hacker.
As is typical for static site generators, each page on this web site
is generated from a file containing markdown with YAML frontmatter.
Neither markdown nor YAML are good. Markdown is very much the
worse-is-better of markup languages; YAML, on the other hand, is more
like better-is-worse. YAML has too many ways of expressing the same
things, and the lack of redundancy in its syntax makes it difficult to
detect mistakes before it is too late. YAML’s specification is
incomprehensible.
But they are both very convenient and popular, so I went with the flow.
The top-level value in a YAML document does not have to be an array or
object: you can use its wild zoo of string syntax too,
so for example,
--- |
here is a preformatted
multiline string
frontmatter and markdown
Putting these two features together, the right way to do YAML
frontmatter for markdown files is clearly,
---
frontmatter: goes here
...
--- |
markdown goes here
The page processor can simply:
feed the contents of the file to the YAML parser
use the first document for metadata
feed the second document to the markdown processor
check that’s the end of the file
No need for any ad-hoc hacks to separate the two parts of the file:
the YAML acts as a lightweight wrapper for the markdown.
markdown inside YAML
The crucial thing that makes this work is that the markdown after the
--- | delimiter does not need to be indented.
Markdown is very sensitive to indentation, so all the tooling (most
importantly my editor) gets righteously confused if markdown is placed
in a container that introduces extra indentation.
YAML in Perl
The static site generator for www.dns.cam.ac.uk
uses --- | to mark the start of the markdown in its source files.
This worked really nicely.
The web site was written in Perl, because most of the existing DNS
infrastructure was Perl and I didn’t want to change programming
languages. YAML was designed by Perl hackers, and the Perl YAML
modules are where it all went wrong started.
I soon discovered that, unlike the original YAML implementations,
serde-yaml requires top-level strings following --- | to be
indented. This bug seems to be common in YAML implementations for
languages other than Perl.
start and end delimiters
So I changed the syntax for my frontmatter so it looks like,
---
frontmatter: goes here
...
markdown goes here
That is, the file starts with a complete YAML document delimited by
--- start and ... end markers, and the rest of the file is the
markdown.
The idea is that a page processor should be able to:
feed the contents of the file to the YAML parser
read one document containing the metadata
feed the rest of the file to the markdown processor
However, I could not work out how to get serde-yaml to read just the
prefix of a file successfully and return the remainder for further
processing.
I know, I’ll use regexps
(Might as well, I’m already way past two problems…)
As a result I had to add a bodge to the page processor:
split the file using a regex
feed the first part to the YAML parser
feed the second part to the markdown processor
mainstream frontmatter
My choice to mark the end of the frontmatter with the YAML ... end
delimiter is not entirely mainstream. As I understand it, the YAML +
markdown convention came from Jekyll, or at least Jekyll
popularized it. Jekyll uses the YAML --- start delimiter to mark the
end of the YAML, or maybe to mark the start of the markdown, but
either way it doesn’t make sense.
Fortunately my ... bodge is compatible with Pandoc YAML
metadata, and Emacs markdown mode
supports Pandoc-style YAML metadata, so the road to hell is at least
reasonably well paved.
grump
It works, but it doesn’t make me happy. I suppose I deserve the
consequences of choosing technology with known deficiencies. But it
requires minimal effort, and is by and large good enough.
My opinion is not mainstream, but I think if you really examine the
practices and security processes that use and recommend sudo, the
reasons for using it are mostly bullshit.
Our net connection at home is not great: amongst its several
misfeatures is a lack of IPv6. Yesterday I (at last!) got around to
setting up a wireguard IPv6 VPN tunnel
between my workstation and my Mythic Beasts virtual private
server.
The Dreamwidth feed has not caught this afternoon’s newly added
links, so I am not sure if it is actually working…
There is a lengthy backlog of links to be shared, which will be added
to the public log a few times each day.
The backlog will be drained in a random order, but the link log’s web
page and atom feed are sorted in date order, so the most-recently
shared link will usually not be the top link on the web page.
I might have to revise how the atom feed is implemented to avoid
confusing feed readers, but this will do for now.
The code has been rewritten from scratch in Rust, alongside the static
site generator that runs my blog. It’s less of a disgusting hack than
the ancient Perl link log that grew like some kind of fungus, but it
still lacks a sensible database and the code is still substantially
stringly typed. But, it works, which is the important thing.
edited to add …
I’ve changed the atom feed so that newly-added entries have both a
“published” date (which is the date displayed in the HTML, reflecting
when I saved the link) plus an “updated” date indicating when it was
later added to the public log.
I think this should make it a little more friendly to feed readers.
Back in December, George Michaelson posted an item on the APNIC blog titled
“That OSI model refuses to die”,
in reaction to Robert Graham’s “OSI Deprogrammer”
published in September. I had discussed the OSI Deprogrammer on Lobsters,
and George’s blog post prompted me to write an email. He and I agreed
that I should put it on my blog, but I did not get a round tuit until
now…
The main reason that OSI remains relevant is Cisco certifications require
network engineers to learn it. This makes OSI part of the common technical
vocab and basically unavoidable, even though (as Rob Graham correctly
argues) it’s deeply unsuitable.
It would be a lot better if the OSI reference model were treated as a
model of OSI in particular, not a model of networking in general, as
Jesse Crawford argued in 2021. OSI ought to be taught
as an example alongside similar reference models of protocol stacks
that are actually in use.
One of OSI’s big problems is how it enshrines layering as the
architectural pattern, but there are other patterns that are at least
as important:
The hourglass narrow waist pattern, where a protocol stack provides a
simple abstraction and only really cares about how things work on one
side of the waist.
For instance, IP is a narrow waist and the Internet protocol stack
only really cares about the layers above it. And Ethernet’s addressing
and framing are another narrow waist, where IEEE 802 only really cares
about the layers below.
Recursive layering of entire protocol stacks. This occurs when
tunnelling, e.g. MPLS or IPSEC. It works in concert with narrow waists
that allow protocol stacks to be plugged together.
Tunneling starkly highlights what nonsense OSI’s fixed layers are,
leading to things like network engineers talking about “layer 2.5”
when talking about tunneling protocols that present Ethernet’s narrow
waist at their endpoints.
Speaking of Ethernet, it’s very poorly served by the OSI model. Ethernet
actually has three layers:
Then there’s WiFi which looks like Ethernet from IP’s point of view,
but is even more complicated. And almost everything non-ethernet has gone
away or been adapted to look more like ethernet…
Whereas OSI has too few lower layers, it has too many upper layers:
its session and presentation layers don’t correspond to anything in
the Internet stack. I think Rob Graham said that they came from IBM
SNA, and were related to terminal-related things like simplex or
block-mode, and character set translation. Jack Haverty said
something similar on the Internet History mailing list in
2019. The closest the ARPANET / Internet protocols get is
Telnet’s feature negotiation; a lot of the problem solved by the OSI
presentation layer is defined away by the Internet’s ASCII-only
network virtual terminal. Graham also said that when people assign
Internet functions to layers 5 and 6, they do so based on the names
not based on how the OSI describes what they do.
One of the things that struck me when reading
Mike Padlipsky’s
Elements of Networking Style
is the amount of argumentation that was directed at terminal handling
back then. I guess in that light it’s not entirely surprising that OSI
would dedicate two entire layers to the problem.
Padlipsky also drew the
ARPANET layering as a fan
instead of a skyscraper, with intermediate layers shared by some but
not all higher-level protocols, e.g. the NVT used by Telnet, FTP,
SMTP. I expect if he were drawing the diagram later there might be
layers for 822 headers, MIME, SASL – though they are more like design
patterns than layers since they get used rather differently by SMTP,
NNTP, HTTP. The notion of pick-and-mix protocol modules seems more
useful than fixed layering.
Anyway, if I could magically fix the terminology, I would prefer
network engineers to talk about specific protocols (e.g. ethernet,
MPLS) instead of bogusly labelling them as layers (e.g. 2, 2.5). If
they happen to be working with a more diverse environment than usual
(hello DOCSIS) then it would be better to talk about sub-IP
protocol stacks. But that’s awkwardly sesquipedalian so I can’t see it
catching on.
In my previous entry I wrote about constructing a four-point egg,
using curcular arcs that join where their tangents are at 45°.
I wondered if I could do something similar with ellipses.
As before, I made an interactive ellipse workbench to
experiment with the problem. I got something working, but I have questions…