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The port4me tool:
finds a free TCP port in [1024,65535] that the user can open
is designed to work in multi-user environments
gives different users, different ports
gives the user the same port over time with high probability
gives different ports for different software tools
requires no configuration
can be reproduced perfectly on all operating systems and in all common programming languages
There are many tools to identify a free TCP port, where most of them return a random port. Although it works technically, it might add a fair bit of friction if a new random port number has to be entered by the user each time they need to use a specific tool.
In contrast, port4me attempts, with high
probability, to provide the user with the same port each time, even when
used on different days. It achieves this by scanning the same
deterministic, pseudo-random sequence of ports and return the first free
port detected. Each user gets their own random port sequence, lowering
the risk for any two users to request the same port. The randomness is
initiated with a random seed that is a function of the user’s name
(USER
), and, optionally, the name of the software where we
use the port.
The port4me algorithm can be implemented in most known programming languages, producing perfectly reproducible sequencing regardless of implementation language.
Assuming we’re logged in as user alice
, calling
port4me::port4me()
without arguments gives us a free
port:
## [1] "alice"
## [1] 30845
As we will see later, each user on the system is likely to get their own unique port. Because of this, it can be used to specifying a port that some tool should use, e.g.
As long as this port is available, alice
will always get
the same port across R sessions and over time. For example, if they
return next week and retry, it’s likely they still get:
## [1] 30845
## [1] 30845
However, if port 30845 is already occupied, the next port in the pseudo-random sequence is considered, e.g.
## [1] 19654
To see the first five ports scanned, run:
## [1] 30845 19654 32310 63992 15273
This random sequence is initiated by a random seed that can be set
via the hashcode of a seed string. By default, it is based on the name
of the current user (e.g. environment variable $USER
). For
example, when user bob
uses the port4me
tool,
they see another set of ports being scanned:
## [1] "bob"
## [1] 54242 4930 42139 14723 55707
For testing and demonstration purposes, one can emulate another user
by specifying argument user
, e.g.
## [1] "alice"
## [1] 30845
## [1] 54242
## [1] 34307
Sometimes a user would like to use two, or more, ports at the same
time, e.g. two ports for two different Shiny apps. In such case, they
can specify argument tool
, which results in a port sequence
that is unique to both the user and the tool. For example,
## [1] 30845
## [1] 55578
## [1] 32273
This allows us to do:
and
Since there is a limited set of ports available (1024-65535), there
is always a risk that another process occupies any given port. The more
users there are on the same machine, the higher the risk is for this to
happen. If a user is unlucky, they might experience this frequently. For
example, alice
might find that the first port (30845) works
only one out 10 times, the second port (19654) works 99 out 100 times,
and the third one (32310) works rarely. If so, they might choose to
exclude the ports that are most likely to be used by specifying them as
a comma-separated values via option --exclude
, e.g.
[1] 19654
An alternative to specify them via a command-line option, is to
specify them via environment variable PORT4ME_EXCLUDE
,
e.g.
To set this permanently, append:
## port4me customization
## https://github.com/HenrikBengtsson/port4me
PORT4ME_EXCLUDE=30845,32310
export PORT4ME_EXCLUDE
to the shell startup script, e.g. ~/.bashrc
.
Alternatively, it can be set specifically for R in
~/.Renviron
as:
This increases the chances for the user to end up with the same port over time, which is convenient, because then they can reuse the same call, which is available in the command-line history, each time without having to change the port parameter.
The environment variable PORT4ME_EXCLUDE
is intended to
be used by the individual user. To specify a set of ports to be excluded
regardless of user, set PORT4ME_EXCLUDE_SITE
. For example,
the systems administrator, can choose to exclude an additional set of
ports by adding the following to file
/etc/profile.d/port4me.sh
:
## port4me: always exclude commonly used ports
## https://github.com/HenrikBengtsson/port4me
PORT4ME_EXCLUDE_SITE=
## MySQL
PORT4ME_EXCLUDE_SITE=$PORT4ME_EXCLUDE_SITE,3306
## ZeroMQ
PORT4ME_EXCLUDE_SITE=$PORT4ME_EXCLUDE_SITE,5670
## Redis
PORT4ME_EXCLUDE_SITE=$PORT4ME_EXCLUDE_SITE,6379
## Jupyter
PORT4ME_EXCLUDE_SITE=$PORT4ME_EXCLUDE_SITE,8888
export PORT4ME_EXCLUDE_SITE
In addition to ports excluded via above mechanisms,
port4me excludes ports that are considered unsafe by
the Chrome and Firefox web browsers. This behavior can be controlled by
environment variable PORT4ME_EXCLUDE_UNSAFE
, which defaults
to {chrome},{firefox}
. Token {chrome}
expands
to the value of PORT4ME_EXCLUDE_UNSAFE_CHROME
, which
defaults to the
set of ports that Chrome blocks and {firefox}
expands
to to the value of PORT4ME_EXCLUDE_UNSAFE_FIREFOX
, which
defaults to the
set of ports that Firefox blocks.
Analogously to excluding a set of ports, one can limit the range of
ports to be scanned by specifying command-line argument
include
, e.g.
## [1] 10451
where the default corresponds to include = 1024:65535
.
Analogously to exclude
, include
can be
specified via environment variables PORT4ME_INCLUDE
and
PORT4ME_INCLUDE_SITE
.
In addition to scanning the user-specific, pseudo-random port
sequence for a free port, it is possible to also consider a predefined
set of ports prior to the random ones by specifying command-line
argument prepend
, e.g.
## [1] 4321 11001 30845 19654 32310
An alternative to specify them via a command-line option, is to
specify them via environment variable PORT4ME_PREPEND
,
e.g.
{alice}$ PORT4ME_PREPEND=4321,11001 R
...
> port4me::port4me(list = 5)
[1] 4321 11001 30845 19654 32310
The environment variable PORT4ME_PREPEND
is intended to
be used by the individual user. To specify a set of ports to be
prepended regardless of user, set PORT4ME_PREPEND_SITE
.
To install the R port4me package, do:
To try it out, call:
## [1] 29525
or
It should be possible to implement the algorithm using 32-bit unsigned integer arithmetic. One must not assume that the largest represented integer can exceed \(2^{32} - 1\).
The pseudo-randomized port sequence should sample ports uniformly over \([1024, 65535]\).
At a minimum, it should be possible to implement the algorithm in
vanilla Sh*, Csh, Bash, C, C++, Fortran, Lua, Python, R, and Ruby, with
no need for add-on packages beyond what is available from their
core distribution. (*) Shells that do not support integer arithmetic may
use tools such as expr
, dc
, bc
,
and awk
for these calculations.
All programming languages should produce the exact same pseudo-random port sequences given the same random seed.
The implementations should be written such that they work also when sourced, or copy’and’pasted into source code elsewhere, e.g. in R and Python scripts.
The identified, free port should be outputted to the standard output (stdout) as digits only, without any prefix or suffix symbols.
The user should be able to exclude a pre-defined set of ports by
specifying environment variable PORT4ME_EXCLUDE
,
e.g. PORT4ME_EXCLUDE=8080,4321
.
The system administrator should be able to specify a pre-defined
set of ports to be excluded by specifying environment variable
PORT4ME_EXCLUDE_SITE
,
e.g. PORT4ME_EXCLUDE_SITE=8080,4321
. This works
complementary to PORT4ME_EXCLUDE
.
The user should be able to skip a certain number of random ports
at their will by specifying environment variable
PORT4ME_SKIP
, e.g. PORT4ME_SKIP=5
. The default
is to not skip, which corresponds to PORT4ME_SKIP=0
.
Skipping should apply after ports are excluding by
PORT4ME_EXCLUDE
and
PORT4ME_EXCLUDE_SITE
.
New implementations should perfectly reproduce the port sequences produced by already existing implementations.
A Linear congruential generator (LCG) will be used to generate the pseudo-random port sequence
the next seed, \(s_{n+1}\) is calculated based on the current seed \(s_n\) and parameters \(a, c, m > 1\) as \(s_{n+1} = (a * s_{n} + c) \% m\)
the LCG algorithm must not assume that the current LCG seed is within \([0,m-1]\), i.e. it should apply modulo \(m\) on the seed first to avoid integer overflow
the LCG algorithm may produce the same output seed as input seed, which may happen when the seed is \(s_n = m - (a - c)\). To avoid this resulting in a constant LCG stream, increment the seed by one and recalculate whenever this happens
LCG parameters should be \(m = 2^{16} + 1\), \(a = 75\), and \(c = 74\) (“ZX81”)
this requires only 32-bit integer arithmetic, because \(m < 2^{32}\)
if the initial seed is \(s_0 = m - (a - c)\), which here is \(m - 1 = 2^{16}\), then the next LCG seed will be the same, which is then handled by the above increment-by-one workaround
A 32-bit integer string hashcode will be used to generate an integer in \([0,2^{32}-1]\) from an ASCII string with any number of characters. The hashcode algorithm is based on the Java hashcode algorithm, but uses unsigned 32-bit integers in \([0,2^{32}-1]\), instead of signed ones in \([-2^{31},2^{31}-1]\)
The string hashcode is used as the initial LCG seed:
the LCG seed should be in \([0,m-1]\)
given hashcode \(h\), we can generate the initial LCG seed as \(h\) modulo \(m\)
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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