Medo's Home Page

Hashing It Out

2023-03-122023-03-11 Josip Medved Leave a comment

While .NET finally includes CRC-32 and CRC-64 algorithms, it stops at bare minimum and offers only a single standard polynomial for each. Perfectly sufficient if one wants to create something from scratch but woefully inadequate when it comes to integrating with other software.

You see, CRC is just the method of computation and it's not sufficient to fully describe the result. What you need is polynomial and there's a bunch of them. At any useful bit length you will find many "standard" polynomials. While .NETs solution gives probably most common 32 and 64 bit variant, it doesn't cover shorter bit lengths nor does it allow for custom polynomial.

Well, for that purpose I created a library following the same inheritance-from-NonCryptographicHashAlgorithm-class pattern. Not only does it allow for 8, 16, 32, and 64 bit widths, but it also offers a bunch of well-known polynomials in addition to custom polynomial support.

Below is the list of currently supported variants and, as always, code is available on GitHub.

CRC-8	CRC-16	CRC-32	CRC-64
ATM	ACORN	AAL5	ECMA-182
AUTOSAR	ARC	ADCCP	GO-ECMA
BLUETOOTH	AUG-CCITT	AIXM	GO-ISO
C2	AUTOSAR	AUTOSAR	MS
CCITT	BUYPASS	BASE91-C	REDIS
CDMA2000	CCITT	BASE91-D	WE
DARC	CCITT-FALSE	BZIP2	XZ
DVB-S2	CCITT-TRUE	CASTAGNOLI
GSM-A	CDMA2000	CD-ROM-EDC
GSM-B	CMS	CKSUM
HITAG	DARC	DECT-B
I-432-1	DDS-110	IEEE-802.3
I-CODE	DECT-R	INTERLAKEN
ITU	DECT-X	ISCSI
LTE	DNP	ISO-HDLC
MAXIM	EN-13757	JAMCRC
MAXIM-DOW	EPC	MPEG-2
MIFARE	EPC-C1G2	PKZIP
MIFARE-MAD	GENIBUS	POSIX
NRSC-5	GSM	V-42
OPENSAFETY	I-CODE	XFER
ROHC	IBM-3740	XZ
SAE-J1850	IBM-SDLC
SMBUS	IEC-61158-2
TECH-3250	IEEE 802.3
WCDMA2000	ISO-HDLD
	ISO-IEC-14443-3-A
	ISO-IEC-14443-3-B
	KERMIT
	LHA
	LJ1200
	LTE
	MAXIM
	MAXIM-DOW
	MCRF4XX
	MODBUS
	NRSC-5
	OPENSAFETY-A
	OPENSAFETY-B
	PROFIBUS
	RIELLO
	SPI-FUJITSU
	T10-DIF
	TELEDISK
	TMS37157
	UMTS
	USB
	V-41-LSB
	V-41-MSB
	VERIFONE
	X-25
	XMODEM
	ZMODEM

Mikrotik Upgrade via SSH

2023-03-042023-03-02 Josip Medved Leave a comment

New Mikrotik version came out and my firewall was just a bit too tight
to allow remote WinBox connection. But I did have SSH...

And yes, upgrading to new version is easy enough from command line too. It's
just that one needs to execute two (you can omit the check) commands for the
same GUI experience.

/system/package/update check-for-updates 
/system/package/update download 
/system/reboot

And that's it, the new version is in.

Start Application Without the X Bit Set

2023-02-252023-02-25 Josip Medved Leave a comment

When one plays in many environments, ocassionally you can expect issues. For me one of those issues was starting Linux application from a shared drive. For reasons I won't get into now, except to say security-related, executable (aka X) bit was removed. Thus it wasn't possible to start application.

But, as always in Linux, there are multiple ways to skin a cat. For me the method that did wonders was usage of ld-linux library. For example, to start a.out application, one could use the following command:

/usr/lib64/ld-linux-x86-64.so.2 ./a.out

PS: This is for applications (e.g. files with ELF header). If you want to run a script without executable bit set, just call the interpreter directly, e.g.:

bash ./a.sh

Sleep Until the Next Full Second

2023-01-222023-01-22 Josip Medved Leave a comment

For a bash script of mine I had to execute a certain command every second. While this command lasted less than a second, its duration was not always the same. Sometimes it would be done in 0.1 seconds, sometime in 0.5, and rarely in more than 1 second (that's curl download for you). This variance made using a simple sleep command a bit suboptimal.

What I needed was a command that would wait until the next full second. What I needed up with was this

SLEEP_SEC=`printf "0.%03d" $((1000 - 10#$(date +%N | head -c 3)))`
if [[ "$SLEEP_SEC" == "0.000" ]]; then SLEEP_SEC="1.000"; fi
sleep $SLEEP_SEC

The first line is just taking the current nano-second count and trimming it to the first three digits that are then subtracted from 1000 and prefixed with 0.. This essentially gives millisecond precision count until the next full second. For example, if current nanosecond counter is 389123544, this would result in 0.611. And yes, you lose a bit of precision here as number gets truncated but the result will be precise enough.

If you wonder what is 10# doing here, it's just ensuring numbers starting with 0 are not misdetected by bash as octal numbers.

The if conditional that follows is just to ensure there is at least 1 second of sleep if the previous command took less than 1 ms. Rare occurrence but cheap enough to protect against.

Finally, we send this to the sleep command which will do its magic and allow the script to continue as the next second starts. And yes, it's not a millisecond precise despite all this calculation as sleep is not meant to be precise to start with. However, it is consistent and it triggers within the same 2-3 milliseconds almost every time. And that was plenty precise for me.