This is probably a common question over the Internet, but I couldn't find an answer that neatly explains how you can convert a byte array to a hexadecimal string, and vice versa.
There are even more variants of doing it, for example here.
The reverse conversion would go like this:
Note: new leader as of 2015-08-20.
I ran each of the various conversion methods through some crude
WARNING: Do not rely on these stats for anything concrete; they are simply a sample run of sample data. If you really need top-notch performance, please test these methods in an environment representative of your production needs with data representative of what you will use.
Lookup tables have taken the lead over byte manipulation. Basically, there is some form of precomputing what any given nibble or byte will be in hex. Then, as you rip through the data, you simply look up the next portion to see what hex string it would be. That value is then added to the resulting string output in some fashion. For a long time byte manipulation, potentially harder to read by some developers, was the top-performing approach.
Your best bet is still going to be finding some representative data and trying it out in a production-like environment. If you have different memory constraints, you may prefer a method with fewer allocations to one that would be faster but consume more memory.
Feel free to play with the testing code I used. A version is included here but feel free to clone the repo and add your own methods. Please submit a pull request if you find anything interesting or want to help improve the testing framework it uses.
Added Waleed's answer to analysis. Quite fast.
Test repo includes more variants such as
Added CodesInChaos's byte manipulation answer, which took over first place (by a large margin on large blocks of text).
Added Nathan Moinvaziri's lookup answer and the variant from Brian Lambert's blog. Both rather fast, but not taking the lead on the test machine I used (AMD Phenom 9750).
Added @CodesInChaos's new byte-based lookup answer. It appears to have taken the lead on both the sentence tests and the full-text tests.
Added airbreather's optimizations and
There's a class called SoapHexBinary that does exactly what you want.
When writing crypto code it's common to avoid data dependent branches and table lookups to ensure the runtime doesn't depend on the data, since data dependent timing can lead to side-channel attacks.
It's also pretty fast.
Ph'nglui mglw'nafh Cthulhu R'lyeh wgah'nagl fhtagn
An explanation of the weird bit fiddling:
Some further considerations:
If you want more flexibility than
Or, if you're using .NET 4.0:
(The latter from a comment on the original post)
I just encountered the very same problem today and I came across this code:
Source: http://social.msdn.microsoft.com/Forums/en-US/csharpgeneral/thread/3928b8cb-3703-4672-8ccd-33718148d1e3/ (see the post by PZahra) I modified the code a little to remove the 0x prefix
I did some performance testing to the code and it was almost 8 times faster than using BitConverter.ToString() (the fastest according to patridge's post)
You can use BitConverter.ToString Method:
Another lookup table based approach. This one uses only one lookup table for each byte, instead of a lookup table per nibble.
I also tested variants of this using
Depending on the compilation target (x86, X64) those either had the approximately same performance or were slightly slower than this variant.
And for even higher performance, its
Or if you consider it acceptable to write into the string directly:
This problem could also be solved using a look-up table, this would require a small amount of static memory for both encoder and decoder, this method will however be fast:
My solution uses 1024B for the encoding table, and 256B for decoding.
* this solution
During decoding IOException and IndexOutOfRangeException could occur (if a character has a too high value > 256). Methods for de/encoding streams or arrays should be implemented, this is just a proof of concept.
This is a great post. I like Waleed's solution. I haven't run it through patridge's test but it seems to be quite fast. I also needed the reverse process, converting a hex string to a byte array, so I wrote it as a reversal of Waleed's solution. Not sure if it's any faster than Tomalak's original solution. Again, I did not run the reverse process through patridge's test either.
I'll make the case that this edit is wrong, shouldn't have been approved, and should reverted. Along the way, you might learn a thing or two about some internals, and see yet another example of what premature optimization really is and how it can bite you.
tl;dr: Just use
warning: This answer may become obsolete if a
As a general rule, I don't much like to say "don't optimize prematurely", because nobody knows when "premature" is. The only thing you must consider when deciding whether to optimize or not is: "Do I have the time and resources to investigate optimization approaches properly?". If you don't, then it's too soon, wait until your project is more mature or until you need the performance (if there is a real need, then you will make the time). In the meantime, do the simplest thing that could possibly work instead.
The revision avoids
Well, looking at the reference code for
It does allocate a new string however, but then you need to allocate one to pass to
But then, why call
What you're left with is a string reader whose only added "value" is a parallel index (internal
If you wonder how
So, remove the string reader already, and call
Do you really need a
What does the solution look like now? Exactly like it was at the beginning, only instead of using
In fact, if you look at
Conclusion? If you want to use
Note that using
If there was a
I suspect that people who report better performance by "avoiding
Disclaimer: I haven't decompiled the latest version of the framework to verify that the reference source is up-to-date, I assume it is.
Now, it all sounds good and logical, hopefully even obvious if you've managed to get so far. But is it true?
Of course it is.
Props to Partridge for the bench framework, it's easy to hack. The input used is the following SHA-1 hash repeated 5000 times to make a 100,000 bytes long string.
Have fun! (But optimize with moderation.)
Not to pile on to the many answers here, but I found a fairly optimal (~4.5x better than accepted), straightforward implementation of the hex string parser. First, output from my tests (first batch is my impl.):
The base64 and 'BitConverter'd' lines are there to test for correctness. Note that they are equal.
I tried some stuff w/
(I concede that this answers half the question. I felt that the string->byte conversion was underrepresented, while the byte->string angle seems to be well covered. Thus, this answer.)
Complement to answer by @CodesInChaos (reversed method)
for '0'..'9' it is the same as
for 'A'..'F' it is
for 'a'..'f' we have to big numbers so we must subtract 32 from default version by making some bits
65 is code for
48 is code for
7 is the number of letters between
Why make it complex. This is simple in visual studio.net 2008:
And to steal Tomalak's thunder... EXTENSION METHODS :) [disclaimer: completely untested code, btw .. just thought i'd add a quick post]
etc.. use either of his three solutions (with the last one being an extension method on a string)
Unsafe versions For those who prefer performance and do not afraid of unsafeness. About 35% faster ToHex and 10% faster FromHex.
BTW For benchmark testing initializing alphabet every time convert function called is wrong, alphabet must be const (for string) or static readonly (for char). Then alphabet-based conversion of byte to string becomes as fast as byte manipulation versions.
And of course test must be compiled in Release (with optimization) and with debug option "Suppress JIT optimization" turned off (same for "Enable Just My Code" if code must be debuggable).
In terms of speed, this seems to be better than anything here:
From Microsoft's developers, a nice, simple conversion:
While the above is clean an compact, performance junkies will scream about it using enumerators. You can get peak performance with an improved version of Tomolak's original answer:
This is the fastest of all the routines I've seen posted here so far. Don't just take my word for it... performance test each routine and inspect it's IL code for yourself.
I did not get the code you suggested to work, Olipro.
I did, however have some success by taking some hints from Waleeds code and hammering this together. It's ugly as hell but it seems to work and performs at 1/3 of the time compared to the others according to my tests (using patridges testing mechanism). Depending on input size. Switching around the ?:s to separate out 0-9 first would probably yield a slightly faster result since there are more numbers than letters.
This version of ByteArrayToHexViaByteManipulation could be faster.
From my reports:
And I think this one is an optimization:
I'll enter this bit fiddling competition as I have an answer that also uses bit-fiddling to decode hexadecimals. Note that using character arrays may be even faster as calling
Converted from Java code.
And for inserting into an SQL string (if you're not using command parameters):
For performance I would go with drphrozens solution. A tiny optimization for the decoder could be to use a table for either char to get rid of the "<< 4".
Clearly the two method calls are costly. If some kind of check is made either on input or output data (could be CRC, checksum or whatever) the
This is just off the top of my head and has not been tested or benchmarked.
Yet another variation for diversity:
Not optimized for speed, but more LINQy than most answers (.NET 4.0):
Two mashups which folds the two nibble operations into one.
Probably pretty efficient version:
Decadent linq-with-bit-hacking version:
If performance matters, here's an optimized solution:
It's about 2.5 times faster that
if you want to get the "4x speed increase" reported by wcoenen, then if it's not obvious: replace
you could also take it a step further and get rid of the
This works to go from string to byte array...
I guess its speed is worth 16 extra bytes.
protected by Sheridan Feb 6 at 10:03
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