# Why use the C# class System.Random at all instead of System.Security.Cryptography.RandomNumberGenerator?

Why would anybody use the "standard" random number generator from System.Random at all instead of always using the cryptographically secure random number generator from System.Security.Cryptography.RandomNumberGenerator (or its subclasses because RandomNumberGenerator is abstract)?

Nate Lawson tells us in his Google Tech Talk presentation "Crypto Strikes Back" at minute 13:11 not to use the "standard" random number generators from Python, Java and C# and to instead use the cryptographically secure version.

I know the difference between the two versions of random number generators (see question 101337).

But what rationale is there to not always use the secure random number generator? Why use System.Random at all? Performance perhaps?

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Which would you rather type? –  Macha Aug 10 '09 at 21:28
Too many people seriously use that as a justification for what they do (usually not out loud). Code is read more than it's written, who cares about trivial length differences? –  Mark Sowul Mar 21 '12 at 2:08
But anyway why should you use cryptographic RNGs if you are not doing cryptography? –  Mark Sowul Mar 21 '12 at 2:10

Speed and also intent. If you are generating a random # and have no need for security why use a crypto function? You don't need security so why make a coder think that there may be some secure reason for it when there isn't...

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I very much like the intent argument. –  Lernkurve Aug 10 '09 at 21:35
It should be noted that Random.GetNext is far from good at "spreading" the random numbers over the spectrum, especially in a threaded environment. I ran across this problem when writing a program to test different solutions to the Rand7 from Rand5 problem. In a quick threaded test just now of 100000 random numbers between 0 and 10, 82470 of the generated numbers were 0. I saw similar discrepancies in my previous tests. Crytpography random is very even in its distribution of numbers. I guess the lesson is to always test your random data to see that it is "random enough" for your needs. –  Kristoffer L May 31 '11 at 12:14
@Kristoffer I think you misused `Random`. Let me guess: You created a new instance of the `Random` class for each number, which since it's seeded by a coarse timer will be seeded with the same value for an interval of about 1-16ms. –  CodesInChaos Jun 17 '11 at 10:33
@CodesInChaos: Besides that, there is a race-condition with `Random` that causes it to return all 0's when the same object is used from multiple threads. –  BlueRaja - Danny Pflughoeft Oct 25 '12 at 22:25
@KristofferL: See above comment, also see this answer –  BlueRaja - Danny Pflughoeft Oct 25 '12 at 22:25

Apart from the speed and the more useful interface (`NextDouble()` etc) it is also possible to make a repeatable ramdom sequence by using a fixed seed value. That is quite useful, amongst others during Testing.

``````Random gen1 = new Random();     // auto seeded by the clock
Random gen2 = new Random(0);    // Next(10) always yields 7,8,7,5,2,....
``````
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Great hint about testing. –  Lernkurve Aug 10 '09 at 21:34
And there's the BitConverter.ToInt32(Byte[] value, int startIndex) which may be easier to understand. ;) –  Simon Svensson Oct 25 '09 at 9:17
Ian Bell and David Braben used a random generator in the computer game Elite to create a vast list of planets and their attributes (size, etc), with very limited memory. This also relies on the generator creating a deterministic pattern (from a seed) - which the Crypto one obviously doesn't provide (by design.) There's some more information on how they did it here: wiki.alioth.net/index.php/Random_number_generator and the book "Infinite Game Universe: Mathematical Techniques" ISBN:1584500581 has a more general discussion on such techniques. –  Daniel James Bryars Sep 26 '10 at 12:34
Do keep in mind that MSDN does not guarantee this property to hold across .NET versions: "The implementation of the random number generator in the Random class is not guaranteed to remain the same across major versions of the .NET Framework." –  romkyns Jan 25 at 19:01

System.Random is much more performant since it does not generate cryptographically secure random numbers.

A simple test on my machine filling a buffer of 4 bytes with random data 1,000,000 times takes 49 ms for Random, but 2845 ms for RNGCryptoServiceProvider. Note that if you increase the size of the buffer you are filling, the difference narrows as the overhead for RNGCryptoServiceProvider is less relevant.

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Thank you for demonstrating it with an actual test. –  Lernkurve Aug 10 '09 at 21:50

First of all the presentation you linked only talks about random numbers for security purposes. So it doesn't claim `Random` is bad for non security purposes.

But I do claim it is. The .net 4 implementation of `Random` is flawed in several ways. I recommend only using it if you don't care about the quality of your random numbers. I recommend using better third party implementations.

Flaw 1: The seeding

The default constructor seeds with the current time. Thus all instances of `Random` created with the default constructor within a short time-frame return the sequence. This is documented and "by-design". This is particularly annoying if you want to multi-thread your code, since you can't simply create an instance of `Random` at the beginning of each threads execution.

The workaround is to be extra careful when using the default constructor and manually seed when necessary.

Another problem here is that the seed space is rather small. So if you generate 50k instances of `Random` with perfectly random seeds you will probably get one sequence of random numbers twice(See birthday paradox). So manual seeding isn't easy to get right either.

Flaw 2: The distribution of random numbers returned by `Next(int maxValue)` is biased

There are parameters for which `Next(int maxValue)` is clearly not uniform. For example if you calculate `r.Next(1431655765)%2` you will get `0` in about 2/3 of the samples (Sample code at the end of the answer).

Flaw 3: The `NextBytes()` method is inefficient.

The per byte cost of `NextBytes()` is about as big as the cost to generate a full integer sample with `Next()`. From this I suspect that they indeed create one sample per byte.

A better implementation using 3 bytes out of each sample would speed `NextBytes()` up by almost a factor 3.

Thanks to this flaw `Random.NextBytes()` is only about 25% faster than `System.Security.Cryptography.RNGCryptoServiceProvider.GetBytes` on my machine (Win7, Core i3 2600MHz)

I'm sure if somebody inspected the source/decompiled byte code he'd find even more flaws than I found with my black box analysis.

Code samples:

`r.Next(1431655765)%2` is strongly biased:

``````Random r=new Random();
const int mod=2;
int[] hist=new int[mod];
for(int i=0;i<10000000;i++)
{
int num=r.Next(1431655765);
int num2=num % 2;
hist[num2]++;
}
for(int i=0;i<mod;i++)
Console.WriteLine(hist[i]);
``````

Performance:

``````byte[] bytes=new byte[8*1024];
var cr=new System.Security.Cryptography.RNGCryptoServiceProvider();
Random r=new Random();

// Random.NextBytes
for(int i=0;i<100000;i++)
{
r.NextBytes(bytes);
}

//One sample per byte
for(int i=0;i<100000;i++)
{
for(int j=0;j<bytes.Length;j++)
bytes[j]=(byte)r.Next();
}

//One sample per 3 bytes
for(int i=0;i<100000;i++)
{
for(int j=0;j+2<bytes.Length;j+=3)
{
int num=r.Next();
bytes[j+2]=(byte)(num>>16);
bytes[j+1]=(byte)(num>>8);
bytes[j]=(byte)num;
}
//Yes I know I'm not handling the last few bytes, but that won't have a noticeable impact on performance
}

//Crypto
for(int i=0;i<100000;i++)
{
cr.GetBytes(bytes);
}
``````
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+1 for sharing your knowledge, and code –  Half_Baked May 9 '13 at 20:24
Interesting, can confirm your finding: on my machine Next(1431655765) also gives 2/3 with any seeding. What is the magic of 1431655765? How did you arrive at this number? –  citykid Mar 2 at 18:06
@citykid Look at the number as hex or bits. It's magic arises from the dubious way `Random` uses to transform a 31 bit integer into a number with the specified upper bound. I forgot the details, but it's something like `randomValue * max / 2^{31}`. –  CodesInChaos Mar 3 at 9:00

The most obvious reasons have already been mentioned, so here's a more obscure one: cryptographic PRNGs typically need to be continually be reseeded with "real" entropy. Thus, if you use a CPRNG too often, you could deplete the system's entropy pool, which (depending on the implementation of the CPRNG) will either weaken it (thus allowing an attacker to predict it) or it will block while trying to fill up its entropy pool (thus becoming an attack vector for a DoS attack).

Either way, your application has now become an attack vector for other, totally unrelated applications which – unlike yours – actually vitally depend on the cryptographic properties of the CPRNG.

This is an actual real world problem, BTW, that has been observed on headless servers (which naturally have rather small entropy pools because they lack entropy sources such as mouse and keyboard input) running Linux, where applications incorrectly use the `/dev/random` kernel CPRNG for all sorts of random numbers, whereas the correct behavior would be to read a small seed value from `/dev/urandom` and use that to seed their own PRNG.

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I read the Wikipedia article and some other Internet sources on entropy and entropy depletion, and I don't quite understand it. How can I be depleting the entropy pool when the random number generator is fed with system time, number of free bytes etc.? How can others use it as a attack vector to predict random numbers? Can you provide an easy example? Perhaps this discussion must be taken offline. en.wikipedia.org/wiki/Entropy_%28computing%29 –  Lernkurve Aug 11 '09 at 9:27
System time is not an entropy source, because it's predictable. I'm not sure about the number of free bytes, but I doubt it's a high-quality entropy source either. By sending more requests to the server, the attacker can cause the number of free bytes to decrease, making it partially deterministic. You application becomes an attack vector because by depleting the entropy pool, it forces the other, security-critical application to use less-random random numbers -- or wait until the entropy source is replenished. –  quant_dev Oct 25 '09 at 9:05
I understand that if one has a pseudo-random generator fed with e.g. a 32-bit seed, a brute-force attack will often be fairly easy; even a 64-bit seed may be subject to birthday attacks. Once the seed gets much larger than that, though, I don't quite see the risk. If one has a random generator which for each byte of output takes passes a 128-bit state through a block encryption algorithm and then outputs the bottom 8 bits, how could an attacker even with gigs of consecutive output bytes infer the state, absent weaknesses in the encryption algorithm itself? –  supercat Nov 15 '13 at 19:14

If you're programming an online card game or lotter then you would want to make sure the sequence is next to impossible to guess. However, if you are showing users, say, a quote of the day the performance is more important than security.

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+1 for a good easy example. –  Jastill Feb 17 '13 at 22:35

This has been discussed at some length, but ultimately, the issue of performance is a secondary consideration when selecting a RNG. There are a vast array of RNGs out there, and the canned Lehmer LCG that most system RNGs consists of is not the best nor even necessarily the fastest. On old, slow systems it was an excellent compromise. That compromise is seldom ever really relevant these days. The thing persists into present day systems primarily because A) the thing is already built, and there is no real reason to 'reinvent the wheel' in this case, and B) for what the vast bulk of people will be using it for, it's 'good enough'.

Ultimately, the selection of an RNG comes down to Risk/Reward ratio. In some applications, for example a video game, there is no risk whatsoever. A Lehmer RNG is more than adequate, and is small, concise, fast, well-understood, and 'in the box'.

If the application is, for example, an on-line poker game or lottery where there are actual prizes involved and real money comes into play at some point in the equation, the 'in the box' Lehmer is no longer adequate. In a 32-bit version, it only has 2^32 possible valid states before it begins to cycle at best. These days, that's an open door to a brute force attack. In a case like this, the developer will want to go to something like a Very Long Period RNG of some species, and probably seed it from a cryptographically strong provider. This gives a good compromise between speed and security. In such a case, the person will be out looking for something like the Mersenne Twister, or a Multiple Recursive Generator of some kind.

If the application is something like communicating large quantities of financial information over a network, now there is a huge risk, and it heavily outweights any possible reward. There are still armored cars because sometimes heavily armed men is the only security that's adequate, and trust me, if a brigade of special ops people with tanks, fighters, and helicopters was financially feasible, it would be the method of choice. In a case like this, using a cryptographically strong RNG makes sense, because whatever level of security you can get, it's not as much as you want. So you'll take as much as you can find, and the cost is a very, very remote second-place issue, either in time or money. And if that means that every random sequence takes 3 seconds to generate on a very powerful computer, you're going to wait the 3 seconds, because in the scheme of things, that is a trivial cost.

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I think you are wrong about your magnitudes; sending financial data needs to be extremely quick; if your trading algorithm can get to the result 0.1ms quicker than the competition, you end up better in the queue of buy/sell/stop-loss/quote commands. 3 seconds is an eternity. This is why traders invest in insanely good computers. See the previous answer; Crypt.RNG takes only 0,0028 ms per new number; 0.0000028 seconds, so you are off by 9 orders of magnitude in terms of how much processing it takes, and also on how important speed is. –  Henrik Jan 21 '10 at 1:25

Not everyone needs cryptographically secure random numbers, and they might benefit more from a speedier plain prng. Perhaps more importantly is that you can control the sequence for System.Random numbers.

In a simulation utilizing random numbers you might want to recreate, you rerun the simulation with the same seed. It can be handy for tracking bugs when you want to regenerate a given faulty scenario as well - running your program with the exact same sequence of random numbers that crashed the program.

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If I don't need the security, i.e., I just want a relatively indeterminate value not one that's cryptographically strong, Random has a much easier interface to use.

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