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I have a system that needs to schedule some stuff and return identifiers to the scheduled tasks to some foreign objects. The user would basically do this:
identifier = MyLib.Schedule(something)
# Nah, let's unschedule it.
MyLib.Unschedule(identifier)
I use this kind of pattern a lot in internal code, and I always use plain integers as the identifier. But if the identifiers are used by untrusted code, a malicious user could break the entire system by doing a single Unschedule(randint()).
I need the users of the code to be able to only unschedule identifiers they have actually scheduled.
The only solution I can think of is to generate i.e 64-bit random numbers as identifiers, and keep track of which identifiers are currently handed out to avoid the ridiculously unlikely duplicates. Or 128-bit? When can I say "this is random enough, no duplicates could possibly occur", if ever?
Or better yet, is there a more sensible way to do this? Is there a way to generate identifier tokens that the generator can easily keep track of (avoiding duplicates) but is indistinguishable from random numbers to the recipient?
EDIT - Solution based on the accepted answer:
from Crypto.Cipher import AES
import struct, os, itertools
class AES_UniqueIdentifier(object):
def __init__(self):
self.salt = os.urandom(8)
self.count = itertools.count(0)
self.cipher = AES.new(os.urandom(16), AES.MODE_ECB)
def Generate(self):
return self.cipher.encrypt(self.salt +
struct.pack("Q", next(self.count)))
def Verify(self, identifier):
"Return true if identifier was generated by this object."
return self.cipher.decrypt(identifier)[0:8] == self.salt
Depending on how many active IDs you have, 64 bits can be too little. By the birthday paradox, you'd end up with essentially the level of protection you might expect from 32 bit identifiers.
Besides, probably the best way to create these is to use some salted hash function, such as SHA-1 or MD5 or whatever your framework already has, with a randomly chosen salt (kept secret), and those generate at least 128 bits anyway, exactly for the reason mentioned above. If you use something that creates longer hash values, I don't really see any reason to truncate them.
To create identifiers you can check without storing them, take something easy to detect, such as having the same 64 bit patterns twice (giving a total of 128 bits) and encrypt that with some constant secret key, using AES or some other cipher with a block size of 128 bits (or whatever you picked). If and when the user sends some alleged key, decrypt and check for your easy-to-spot pattern.
It sounds to me like you might be over thinking this problem. This sounds 100% like an application for a GUID/UUID. Python even has a built in way to generate them. The whole point of GUID/UUIDs is that the odds of collision are astronomical, and by using a string instead of an encrypted token you can skip the decrypting operation in the verify step. I think this would also eliminate a whole slew of problems you might encounter regarding key management, and increase the speed of the whole process.
EDIT:
With a UUID, your verify method would just be a comparison between the given UUID and the stored one. Since the odds of a collision between two UUIDs is incredibly low, you shouldn't have to worry about false positives. In your example, it appears that the same object is doing both encryption and decryption, without a third party reading the stored data. If this is the case, you aren't gaining anything by passing around encrypted data except that the bits your passing around aren't easy to guess. I think a UUID would give you the same benefits, without the overhead of the encryption operations.
You make your identifier long enough, so it can't be reasonable guessed. In addition, let Unschedule wait for 1 second, if the token is not in use, so a brute force attack is not feasible anymore. Like the other answer said, session IDs in Webapplications are exactly the same problem, and I already saw session IDs which where 64 random characters long.
This is the same problem as dealing with session identifiers in ordinary web applications. Predictable session ids can easily lead to session hijacking.
Have a look at how session ids are generated. Here the content of a typical PHPSESSID cookie:
bf597801be237aa8531058dab94a08a9
If you want to be dead sure no brute-force attack is feasible, do the calculations backward: How many attempts can a cracker do per second? How many different unique id's are used at a random point in time? How many id's are there in total? How long would it take for the cracker to cover, say 1 % of the total space of ids? Adjust number of bits accordingly.
Do you need this pattern in a distributed or local environment?
If you're local, most OO languages should support the notion of object identity, so if you create an opaque handle - just create a new object.
handle = new Object(); // in Java
No other client can fake this.
If you need to use this in distributes environments, you may keep a pool of handles per session, so that a foreign session can never use a stolen handle.
GUIDs are typically used for uniquely identifying all kinds of entities - requests from external systems, files, whatever. Work like magic - you call a "GiveMeGuid()" (UuidCreate() on Windows) function - and a fresh new GUID is here at your service.
Given my code really calls that "GiveMeGuid()" function each time I need a new GUID is there any not so obvious way to misuse it?
Just found an answer to an old question: How deterministic Are .Net GUIDs?. Requoting it:
It's not a complete answer, but I can tell you that the 13th hex digit is always 4 because it denotes the version of the algorithm used to generate the GUID (id est, v4); also, and I quote Wikipedia:
Cryptanalysis of the WinAPI GUID generator shows that, since the sequence of V4 GUIDs is pseudo-random, given the initial state one can predict up to the next 250 000 GUIDs returned by the function UuidCreate. This is why GUIDs should not be used in cryptography, e.g., as random keys.
So, if you got lucky and get same seed, you'll break 250k mirrors in sequence. To quote another Wikipedia piece:
While each generated GUID is not guaranteed to be unique, the total number of unique keys (2128 or 3.4×1038) is so large that the probability of the same number being generated twice is extremely small.
Bottom line: maybe a misuse form it's to consider GUID always unique.
It depends. Some implementations of GUID generation are time dependant, so calling CreateGuid in quick succession MAY create clashing GUIDs.
edit: I now remember the problem. I was once working on some php code where the GUID generating function was reseeding the RNG with the system time each call. Don't do this.
The only way I can see of misusing a Guid is trying to interpret the value in some logical manner. Not that it really invites you to do so, which is one of the characteristics around Guid's that I really like.
Some GUIDs include some identifier of the machine it was generated on, so it can be used in client/server environments, but some can't. Be sure if yours doesn't to not use them in, for instance, a database multiple clients access.
Maybe the entropy could be manipulated by playing with some parameters used to generate the GUIDs in the first place (e.g. interface identifiers).
I'm building a web application where the front end is a highly-specialized search engine. Searching is handled at the main URL, and the user is passed off to a sub-directory when they click on a search result for a more detailed display. This hand-off is being done as a GET request with the primary key being passed in the query string. I seem to recall reading somewhere that exposing primary keys to the user was not a good idea, so I decided to implement reversible encryption.
I'm starting to wonder if I'm just being paranoid. The reversible encryption (base64) is probably easily broken by anybody who cares to try, makes the URLs very ugly, and also longer than they otherwise would be. Should I just drop the encryption and send my primary keys in the clear?
What you're doing is basically obfuscation. A reversible encrypted (and base64 doesn't really count as encryption) primary key is still a primary key.
What you were reading comes down to this: you generally don't want to have your primary keys have any kind of meaning outside the system. This is called a technical primary key rather than a natural primary key. That's why you might use an auto number field for Patient ID rather than SSN (which is called a natural primary key).
Technical primary keys are generally favoured over natural primary keys because things that seem constant do change and this can cause problems. Even countries can come into existence and cease to exist.
If you do have technical primary keys you don't want to make them de facto natural primary keys by giving them meaning they didn't otherwise have. I think it's fine to put a primary key in a URL but security is a separate topic. If someone can change that URL and get access to something they shouldn't have access to then it's a security problem and needs to be handled by authentication and authorization.
Some will argue they should never be seen by users. I don't think you need to go that far.
On the dangers of exposing your primary key, you'll want to read "autoincrement considered harmful", By Joshua Schachter.
URLs that include an identifier will
let you down for three reasons.
The first is that given the URL for
some object, you can figure out the
URLs for objects that were created
around it. This exposes the number of
objects in your database to possible
competitors or other people you might
not want having this information (as
famously demonstrated by the Allies
guessing German tank production levels
by looking at the serial numbers.)
Secondly, at some point some jerk will
get the idea to write a shell script
with a for-loop and try to fetch every
single object from your system; this
is definitely no fun.
Finally, in the case of users, it
allows people to derive some sort of
social hierarchy. Witness the frequent
hijacking and/or hacking of
high-prestige low-digit ICQ ids.
If you're worried about someone altering the URL to try and look at other values, then perhaps you need to look at token generation.
For instance, instead of giving the user a 'SearchID' value, you give them a SearchToken, which is some long unique psuedo-random value (Read: GUID), which you then map to the SearchID internally.
Of course, you'll also need to apply session security and soforth still - because even a unique URL with a non-sequential ID isn't protected against sniffing by anything between your server and the user.
If you're obscuring the primary keys for a security reason, don't do it. That's called security by obscurity and there is a better way. Having said that, there is at least one valid reason to obscure primary keys and that's to prevent someone from scraping all your content by simply examining a querystring in a URL and determining that they can simply increment an id value and pull down every record. A determined scraper may still be able to discover your means of obsuring and do this despite your best efforts, but at least you haven't made it easy.
PostgreSQL provides multiple solutions for this problem, and that could be adapted for others RDBMs:
hashids : https://hashids.org/postgresql/
Hashids is a small open-source library that generates short, unique, non-sequential ids from numbers.
It converts numbers like 347 into strings like “yr8”, or array of numbers like [27, 986] into “3kTMd”.
You can also decode those ids back. This is useful in bundling several parameters into one or simply using them as short UIDs.
optimus is similar to hashids but provides only integers as output: https://github.com/jenssegers/optimus
skip32 at https://wiki.postgresql.org/wiki/Skip32_(crypt_32_bits):
It may be used to generate series of unique values that look random, or to obfuscate a SERIAL primary key without loosing its unicity property.
pseudo_encrypt() at https://wiki.postgresql.org/wiki/Pseudo_encrypt:
pseudo_encrypt(int) can be used as a pseudo-random generator of unique values. It produces an integer output that is uniquely associated to its integer input (by a mathematical permutation), but looks random at the same time, with zero collision. This is useful to communicate numbers generated sequentially without revealing their ordinal position in the sequence (for ticket numbers, URLs shorteners, promo codes...)
this article gives details on how this is done at Instagram: https://instagram-engineering.com/sharding-ids-at-instagram-1cf5a71e5a5c and it boils down to:
We’ve delegated ID creation to each table inside each shard, by using PL/PGSQL, Postgres’ internal programming language, and Postgres’ existing auto-increment functionality.
Each of our IDs consists of:
41 bits for time in milliseconds (gives us 41 years of IDs with a custom epoch)
13 bits that represent the logical shard ID
10 bits that represent an auto-incrementing sequence, modulus 1024. This means we can generate 1024 IDs, per shard, per millisecond
Just send the primary keys. As long as your database operations are sealed off from the user interface, this is no problem.
For your purposes (building a search engine) the security tradeoffs benefits of encrypting database primary keys is negligible. Base64 encoding isn't encryption - it's security through obscurity and won't even be a speedbump to an attacker.
If you're trying to secure database query input just use parametrized queries. There's no reason at all to hide primary keys if they are manipulated by the public.
When you see base64 in the URL, you are pretty much guaranteed the developers of that site don't know what they are doing and the site is vulnerable.
URLs that include an identifier will
let you down for three reasons.
Wrong, wrong, wrong.
First - every request has to be validated, regardless of it coming in the form of a HTTP GET with an id, or a POST, or a web service call.
Second - a properly made web-site needs protection against bots which relies on IP address tracking and request frequency analysis; hiding ids might stop some people from writing a shell script to get a sequence of objects, but there are other ways to exploit a web site by using a bruteforce attack of some sort.
Third - ICQ ids are valuable but only because they're related to users and are a user's primary means of identification; it's a one-of-a-kind approach to user authentication, not used by any other service, program or web-site.
So, to conclude.. Yes, you need to worry about scrapers and DDOS attacks and data protection and a whole bunch of other stuff, but hiding ids will not properly solve any of those problems.
When I need a query string parameter to be able to identify a single row in a column, I normally add a GUID column to that table, and then pass the GUID in the connection string instead of the row's primary key value.
What exactly is GUID? Why and where I should use it?
I've seen references to GUID in a lot of places, and in wikipedia,
but it is not very clear telling you where to use it.
If someone could answer this, it would be nice.
Thanks
GUID technically stands for globally unique identifier. What it is, actually, is a 128 bit structure that is unlikely to ever repeat or create a collision. If you do the maths, the domain of values is in the undecillions.
Use guids when you have multiple independent systems or clients generating ID's that need to be unique.
For example, if I have 5 client apps creating and inserting transactional data into a table that has a unique constraint on the ID, then use guids. This prevents having to force a client to request an issued ID from the server first.
This is also great for object factories and systems that have numerous object types stored in different tables where you don't want any 2 objects to have the same ID. This makes caching and scavenging schemas much easier to implement.
A GUID is a "Globally Unique IDentifier". You use it anywhere that you need an identifier that guaranteed to be different than every other.
Usually, you only need a value to be "locally unique" -- the Primary Key identity in a database table,for example, needs only be different from the other rows in that table, but can be the same as the ID in other tables. (no need for a GUID here)
GUIDs are generally used when you will be defining an ID that must be different from an ID that someone else (outside of your control) will be defining. One such place in the Interface identifier on ActiveX controls. Anyone can create an ActiveX, and not know with what other control someone will be using them with --- and there's nothing to stop everyone from giving their controls the same name. GUIDs keep them distinct.
GUIDs are a combination of the time (in very small fractions of a second) (so it assured to be different from any GUID defined before or later), and a number defining your location (sometimes taken from the MAC address of you network card) (so it's assured to be different from any other GUID defined right now by someone else).
They are also sometimes known as UUIDs (universally unique ID).
As addition to all the other answers, here is an online GUID generator:
http://www.guidgenerator.com/
What is a GUID?
GUID (or UUID) is an acronym for
'Globally Unique Identifier' (or
'Universally Unique Identifier'). It
is a 128-bit integer number used to
identify resources. The term GUID is
generally used by developers working
with Microsoft technologies, while
UUID is used everywhere else.
How unique is a GUID?
128-bits is big enough and the
generation algorithm is unique enough
that if 1,0000,000,000 GUIDs per
second were generated for 1 year the
probability of a duplicate would be
only 50%. Or if every human on Earth
generated 600,000,000 GUIDs there
would only be a 50% probability of a
duplicate.
How are GUIDs used?
GUIDs are used in software development
as database keys, component
identifiers, or just about anywhere
else a truly unique identifier is
required. GUIDs are also used to
identify all interfaces and objects in
COM programming.
A GUID is a "Globally Unique ID". Also called a UUID (Universally Unique ID).
It's basically a 128 bit number that is generated in a way (see RFC 4112 http://www.ietf.org/rfc/rfc4122.txt) that makes it nearly impossible for duplicates to be generated. This way, I can generate GUIDs without some third party organization having to give them to me to ensure they are unique.
One widespread use of GUIDs is as identifiers for COM entities on Windows (classes, typelibs, interfaces, etc.). Using GUIDs, developers could build their COM components without going to Microsoft to get a unique identifier. Even though identifying COM entities is a major use of GUIDs, they are used for many things that need unique identifiers. Some developers will generate GUIDs for database records to provide them an ID that can be used even when they must be unique across many different databases.
Generally, you can think of a GUID as a serial number that can be generated by anyone at anytime and they'll know that the serial number will be unique.
Other ways to get unique identifiers include getting a domain name. To ensure the uniqueness of domain names, you have to get it from some organization (ultimately administered by ICANN).
Because GUIDs can be unwieldy (from a human readable point of view they are a string of hexadecimal numbers, usually grouped like so: aaaaaaaa-bbbb-cccc-dddd-ffffffffffff), some namespaces that need unique names across different organization use another scheme (often based on Internet domain names).
So, the namespace for Java packages by convention starts with the orgnaization's domain name (reversed) followed by names that are determined in some organization specfic way. For example, a Java package might be named:
com.example.jpackage
This means that dealing with name collisions becomes the responsibility of each organization.
XML namespaces are also made unique in a similar way - by convention, someone creating an XML namespace is supposed to make it 'underneath' a registered domain name under their control. For example:
xmlns="http://www.w3.org/1999/xhtml"
Another way that unique IDs have been managed is for Ethernet MAC addresses. A company that makes Ethernet cards has to get a block of addresses assigned to them by the IEEE (I think it's the IEEE). In this case the scheme has worked pretty well, and even if a manufacturer screws up and issues cards with duplicate MAC addresses, things will still work OK as long as those cards are not on the same subnet, since beyond a subnet, only the IP address is used to route packets. Although there are some other uses of MAC addresses that might be affected - one of the algorithms for generating GUIDs uses the MAC address as one parameter. This GUID generation method is not as widely used anymore because it is considered a privacy threat.
One example of a scheme to come up with unique identifiers that didn't work very well was the Microsoft provided ID's for 'VxD' drivers in Windows 9x. Developers of third party VxD drivers were supposed to ask Microsoft for a set of IDs to use for any drivers the third party wrote. This way, Microsoft could ensure there were not duplicate IDs. Unfortunately, many driver writers never bothered, and simply used whatever ID was in the example VxD they used as a starting point. I'm not sure how much trouble this caused - I don't think VxD ID uniqueness was absolutely necessary, but it probably affected some functionality in some APIs.
GUID or UUID (globally vs Universally) Unique IDentifier is, well, a unique ID :) When you need something really unique machine generated, there are libraries to get you one.
See GUID on wikipedia for details.
As to when you don't need a GUID, it is when a counter that you control (one way or another, like a SERIAL SQL type or a sequence) gets incremented. Indexing a "text" value (GUID in textual form) or a 128 bit binary value (which a GUID is) is far more expensive than an integer.
Someone said they are conceptually 128-bit random values, and that is substantially true, but having done a little reading on UUID (GUID usually refers to Microsoft's implementation of UUID), I see that there are several different UUID versions, and most of them are not actually random. So it is possible to generate a UUID for a machine (or something else) and be able to reliably repeat that process to obtain the same UUID down the road, which is important for some applications.
For me it's easier to think of them as simply "128-bit random values". Which is essentially what they are. There are some algorithms for including a bit of information in a few digits of your GUID (thus the random part gets a bit smaller), but still they are pretty large almost-random values.
Since they are so large, it is extremely unlikely that two GUIDs will ever be generated that are the same. For all practical purposes, every GUID ever generated is unique in the world.
I'll leave it to you to figure out where to use them, but other answers already have some examples. Let your imagination run wild. :)
Can be a hard thing to understand because of all the maths that goes on behind generating them. Think of it as a unique id. You can get Visual Studio to generate one for you, or .NET if you happen to be using C# or one of the many other applications or websites. They are considered unique because there is such a silly small chance you'll see the same one twice that it isn't worth considering.
128-bit Globally Unique ID. You can generate GUIDs from now until sunset and you never generate the same GUID twice, and neither will anyone else. They are used a lot with COM.
As for example of something you would use them for, we use them in one of our products. Our users can generate categories and cards on various devices. We want to make sure that we don't confuse a category made on one device with a category created on a different one, so it's important that IDs are unique no matter who generates them, where they generate them, and when they generate them. So we use GUIDs (actually we use our own scheme using 64-bit numbers but they are similar to GUIDs).
I worked on an ACD call center system a few years back where we wanted to gather call detail records from multiple call processors into a single database. I setup a column in MS SQL to generate a GUID for the database key rather than using a system-generated sequential ID (identity column). Back then, this required setting the default value to NewID (or generating it in the code, but the NewID() function was safer). Of course, having a large value for a key may raise a few eyebrows, but I would rather give up the space than risk a collision.
I didn't see anyone address using a GUID as a database key so I thought it might help to know you could do that too.
GUID stands for "Globally Unique Identifier" and you use it when you want to have, erm, a Globally Unique Identifier.
In RSS feeds, for example, you should have a GUID for each item in the feed. That way, the feed reader software can keep track of whether you have read that item or not. Without a GUID, it would be impossible to tell.
A GUID differs from something like a database ID in that no matter who creates an object -- you, me, the guy down the street -- our GUIDs will always be different. There should be no collisions using a GUID.
You'll also see the term UUID, which stands for "Universally Unique Identifier." There is essentially no difference between the two. UUID is the more appropriate term. GUID is the term used by Microsoft.
If you need to generate an identifier that needs to be unique during the whole lifetime of your application, you use a GUID.
Imagine you have a server with sessions, if you give each session a GUID, you are certain that it will be unique for every session ever created by your server. This is useful for tracing bugs.
One particularly useful application of GUIDs that I've found is using them to track unique visitors in webapps where the visitors are anonymous (i.e. not logged in or registered).
GUID = Global Unique IDentifier.
Use it when you want to uniquely identify something in a global context.
This generator can be handy.
The Wikipedia article on GUIDs is pretty clear on what they are used for - maybe rephrasing your question would help - what do you need a GUID for?
To actually see what it looks like on a windows computer, go to cmd or powershell.
Powershell => [guid]::NewGuid()
CMD => powershell [guid]::NewGuid()
I'm using sequential ids as primary keys and there are cases where I don't want those ids to be visible to users, for example I might want to avoid urls like ?invoice_id=1234 that allow users to guess how many invoices the system as a whole is issuing.
I could add a database field with a GUID or something conjured up from hash functions, random strings and/or numeric base conversions, but schemes of that kind have three issues that I find annoying:
Having to allocate the extra database field. I know I could use the GUID as my primary key, but my auto-increment integer PK's are the right thing for most purposes, and I don't want to change that.
Having to think about the possibility of hash/GUID collisions. I give my full assent to all the arguments about GUID collisions being as likely as spontaneous combustion or whatever, but disregarding exceptional cases because they're exceptional goes against everything else I've been taught, and it continues to bother me even when I know I should be more bothered about other things.
I don't know how to safely trim hash-based identifiers, so even if my private ids are 16 or 32 bits, I'm stuck with 128 bit generated identifiers that are a nuisance in urls.
I'm interested in 1-1 mappings of an id range, stretchable or shrinkable so that for example 16-bit ids are mapped to 16 bit ids, 32 bit ids mapped to 32 bit ids, etc, and that would stop somebody from trying to guess the total number of ids allocated or the rate of id allocation over a period.
For example, if my user ids are 16 bit integers (0..65535), then an example of a transformation that somewhat obfuscates the id allocation is the function f(x) = (x mult 1001) mod 65536. The internal id sequence of 1, 2, 3 becomes the public id sequence of 1001, 2002, 3003. With a further layer of obfuscation from base conversion, for example to base 36, the sequence becomes 'rt', '1jm', '2bf'. When the system gets a request to the url ?userid=2bf, it converts from base 36 to get 3003 and it applies the inverse transformation g(x) = (x mult 1113) mod 65536 to get back to the internal id=3.
A scheme of that kind is enough to stop casual observation by casual users, but it's easily solvable by someone who's interested enough to try to puzzle it through. Can anyone suggest something that's a bit stronger, but is easily implementable in say PHP without special libraries? This is getting close to a roll-your-own encryption scheme, so maybe there is a proper encryption algorithm that's widely available and has the stretchability property mentioned above?
EDIT: Stepping back a little bit, some discussion at codinghorror about choosing from three kinds of keys - surrogate (guid-based), surrogate (integer-based), natural. In those terms, I'm trying to hide an integer surrogate key from users but I'm looking for something shrinkable that makes urls that aren't too long, which I don't know how to do with the standard 128-bit GUID. Sometimes, as commenter Princess suggests below, the issue can be sidestepped with a natural key.
EDIT 2/SUMMARY:
Given the constraints of the question I asked (stretchability, reversibility, ease of implementation), the most suitable solution so far seems to be the XOR-based obfuscation suggested by Someone and Breton.
It would be irresponsible of me to assume that I can achieve anything more than obfuscation/security by obscurity. The knowledge that it's an integer sequence is probably a crib that any competent attacker would be able to take advantage of.
I've given some more thought to the idea of the extra database field. One advantage of the extra field is that it makes it a lot more straightforward for future programmers who are trying to familiarise themselves with the system by looking at the database. Otherwise they'd have to dig through the source code (or documentation, ahem) to work out how a request to a given url is resolved to a given record in the database.
If I allow the extra database field, then some of the other assumptions in the question become irrelevant (for example the transformation doesn't need to be reversible). That becomes a different question, so I'll leave it there.
I find that simple XOR encryption is best suited for URL obfuscation. You can continue using whatever serial number you are using without change. Further XOR encryption doesn't increase the length of source string. If your text is 22 bytes, the encrypted string will be 22 bytes too. It's not easy enough as to be guessed like rot 13 but not heavy weight like DSE/RSA.
Search the net for PHP XOR encryption to find some implementation. The first one I found is here.
I've toyed with this sort of thing myself, in my amateurish way, and arrived at a kind of kooky number scrambling algorithm, involving mixed radices. Basically I have a function that maps a number between 0-N to another number in the 0-N range. For URLS I then map that number to a couple of english words. (words are easier to remember).
A simplified version of what I do, without mixed radices: You have a number that is 32 bits, so ahead of time, have a passkey which is 32-bits long, and XOR the passkey with your input number. Then shuffle the bits around in a determinate reordering. (possibly based on your passkey).
The nice thing about this is
No collisions, as long as you shuffle and xor the same way each time
No need to store the obfuscated keys in the database
Still use your ordered IDS internally, since you can reverse the obfuscation
You can repeat the operation several times to get more obfuscated results.
if you're up for the mixed radix version, it's basically the same, except that I add the steps of converting the input to a mixed raddix number, using the maximum range's prime factors as the digit's bases. Then I shuffle the digits around, keeping the bases with the digits, and turn it back into a standard integer.
You might find it useful to revisit the idea of using a GUID, because you can construct GUIDs in a way that isn't subject to collision.
Check out the Wikipedia page on GUIDs - the "Type 1" algorithm uses both the MAC address of the PC, and the current date/time as inputs. This guarantees that collisions are simply impossible.
Alternatively, if you create a GUID column in your database as an alternative-key (keep using your auto-increment primary keys), define it as unique. Then, if your GUID generation approach does give a duplicate, you'll get an appropriate error on insert that you can handle.
I saw this question yesterday: how reddit generates an alphanum id
I think it's a reasonably good method (and particularily clever)
it uses Python
def to_base(q, alphabet):
if q < 0: raise ValueError, "must supply a positive integer"
l = len(alphabet)
converted = []
while q != 0:
q, r = divmod(q, l)
converted.insert(0, alphabet[r])
return "".join(converted) or '0'
def to36(q):
return to_base(q, '0123456789abcdefghijklmnopqrstuvwxyz')
Add a char(10) field to your order table... call it 'order_number'.
After you create a new order, randomly generate an integer from 1...9999999999. Check to see if it exists in the database under 'order_number'. If not, update your latest row with this value. If it does exist, pick another number at random.
Use 'order_number' for publicly viewable URLs, maybe always padded with zeros.
There's a race condition concern for when two threads attempt to add the same number at the same time... you could do a table lock if you were really concerned, but that's a big hammer. Add a second check after updating, re-select to ensure it's unique. Call recursively until you get a unique entry. Dwell for a random number of milliseconds between calls, and use the current time as a seed for the random number generator.
Swiped from here.
UPDATED As with using the GUID aproach described by Bevan, if the column is constrained as unique, then you don't have to sweat it. I guess this is no different that using a GUID, except that the customer and Customer Service will have an easier time referring to the order.
I've found a much simpler way. Say you want to map N digits, pseudorandomly to N digits. you find the next highest prime from N, and you make your function
prandmap(x) return x * nextPrime(N) % N
this will produce a function that repeats (or has a period) every N, no number is produced twice until x=N+1. It always starts at 0, but is pseudorandom thereafter.
I honestly thing encrypting/decrypting query string data is a bad approach to this problem. The easiest solution is sending data using POST instead of GET. If users are clicking on links with querystring data, you have to resort to some javascript hacks to send data by POST (keep accessibility in mind for users with Javascript turned off). This doesn't prevent users from viewing source, but at the very least it keeps sensitive from being indexed by search engines, assuming the data you're trying to hide really that sensitive in the first place.
Another approach is to use a natural unique key. For example, if you're issuing invoices to customers on a monthly basis, then "yyyyMM[customerID]" uniquely identifies a particular invoice for a particular user.
From your description, personally, I would start off by working with whatever standard encryption library is available (I'm a Java programmer, but I assume, say, a basic AES encryption library must be available for PHP):
on the database, just key things as you normally would
whenever you need to transmit a key to/from a client, use a fairly strong, standard encryption system (e.g. AES) to convert the key to/from a string of garbage. As your plain text, use a (say) 128-byte buffer containing: a (say) 4-byte key, 60 random bytes, and then a 64-byte medium-quality hash of the previous 64 bytes (see Numerical Recipes for an example)-- obviously when you receive such a string, you decrypt it then check if the hash matches before hitting the DB. If you're being a bit more paranoid, send an AES-encrypted buffer of random bytes with your key in an arbitrary position, plus a secure hash of that buffer as a separate parameter. The first option is probably a reasonable tradeoff between performance and security for your purposes, though, especially when combined with other security measures.
the day that you're processing so many invoices a second that AES encrypting them in transit is too performance expensive, go out and buy yourself a big fat server with lots of CPUs to celebrate.
Also, if you want to hide that the variable is an invoice ID, you might consider calling it something other than "invoice_id".