Recently, I found a site that show all the addresses in a huge list, divided in 904625697166532776746648320380374280100293470930272690489102837043110636675 pages.

The site's link is http://directory.io/ and I want to know if I can find a certain address from the whole list. I already tried to merge all those pages into one list and then search for the address with the browser, but I'm not sure how to do it (because I don't know much about HTML).

So, if you know a way to do this, please tell me and explain me how. Thanks!

  • 7
    That's hilarious. Sep 28 '14 at 15:24
  • @DavidSchwartz It's hilarious if it's a malcontent scallywag- perhaps its for noble causes! Op check answer #2 Sep 28 '14 at 18:20
  • 3
    I wonder how far Google's crawler has gotten into this site. Sep 28 '14 at 20:32
  • @Michael Apparently, not an insignificant amount of it (if you assume Google indexes linearly)
    – user6561
    Sep 28 '14 at 21:05
  • If you know the private key, yes you can. If not, you'll need roughly an eternity to find it.
    – Tim S.
    Sep 29 '14 at 20:27

As Arturo and Aussie already said, directory.io shows all Bitcoin addresses sorted by private key. Also, the author explains his intent on directory.io/faq.

The first page has 11.302 Byte. Assuming they all are about the same size, 1TiB would just store 97,284,695 pages. Yet, there are 904625697166532776746648320380374280100293470930272690489102837043110636675 pages. That is approximately 9.05 × 1074, i.e. ~1066 TiB.

There is not enough memory to store them, and it is infeasible to search for one address in them in reasonable time.

Concluding, everyone's bitcoins are still safe. :)


The site Directory.io is an insider joke; it's simply making the statement that there's 2^256 - 1 (ie X combinations, where X = 115792089237316195423570985008687907852837564279074904382605163141518161494336 ) private keys.

A private key can be a large number like 904625697166532776746648320380374280100293470930272690489102837043110636601 or small like 0.

So what's been done is each page is essentially a list of hashed numbers in order, starting at n=0, then next n=1, 2, 3, etc ad nauseum

Similarly, a hashed number called the secret exponent - a hexadecimal number up to 2^160 in size - represents the public key. You can see the public key for yourself with the secret exponent field at BrainWallet.org and the private key proof at the Directory.io FAQ.

  • It's actually 115792089237316195423570985008687907852837564279074904382605163141518161494336 private keys! blog.richardkiss.com/?p=371 ... 1 Mississippi, 2 Mississippi... Sep 29 '14 at 1:22
  • Tiny nit: 0 is not a valid private key. 1 is. Oct 16 '17 at 4:45

I don't think you understand that site. It 'lists' all possible addresses and you do NOT want to search your own address in there (even if that were possible).

I don't know of the site is a joke or a troll, but best just to avoid it.

  • 2
    There is not bad faq section there directory.io/faq
    – amaclin
    Sep 28 '14 at 15:48
  • Those a too much private keys! just try it. It will take too long to search. directory.io is not available anymore. But there seems to be a new site: allprivatekeys.com. I don't know if its serious so DO NOT CHECK YOUR PRIVATE KEYS THERE but you can check your Bitcon Addresses. Aug 19 '18 at 18:35
  • But you also should not post there any bitcoin addresses with your email address. This would be a good combination for an attack ;) Aug 24 '18 at 19:14

Also important to note is that Directory.io doesn't actually store any private key (because that would be physically imposible, for a reason similar to this). Rather, you tell it which page you want to see, and then it shows you the private keys [n*128, (n+1)*128-1], which it calculates on the fly. Your private keys are never compromised by this website.

  • 2
    UNLESS of course you search for your private key or public key in the list. A malicious webmaster could actually exploit that now I think of it. Oct 1 '14 at 6:22
  • Actually, the theoretical minimum energy to perform any reversible computing operation is zero. Yapping about thermodynamics doesn't change that. Sources: cise.ufl.edu/research/revcomp/faq.html and en.wikipedia.org/wiki/Reversible_computing
    – ike
    Oct 14 '14 at 1:30
  • The link I provided about counting and thermodynamics was an example. The actual storing of such numbers is a different problem that depends on the smallest physical storage posible for a bit. If we take this to be an atom, then we're on a similar scale. We would need almost all atoms in the observable universe to store all of them. Oct 14 '14 at 1:40
  • Also, I would like to know about a real-life computer that actually uses 0 energy (how would it work, anyway?) Oct 14 '14 at 1:43
  • @WizardOfOzzie lol dont ever do that , u will give the site's owner shortcut right to your wallet
    – K3rnel31
    Jun 16 '17 at 4:04

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