In Swing, the password field has a getPassword() (returns char[]) method instead of the usual getText() (returns String) method. Similarly, I have come across a suggestion not to use String to handle passwords.
Why does String pose a threat to security when it comes to passwords?
It feels inconvenient to use char[].
Strings are immutable. That means once you've created the String, if another process can dump memory, there's no way (aside from reflection) you can get rid of the data before garbage collection kicks in.
With an array, you can explicitly wipe the data after you're done with it. You can overwrite the array with anything you like, and the password won't be present anywhere in the system, even before garbage collection.
So yes, this is a security concern - but even using char[] only reduces the window of opportunity for an attacker, and it's only for this specific type of attack.
As noted in the comments, it's possible that arrays being moved by the garbage collector will leave stray copies of the data in memory. I believe this is implementation-specific - the garbage collector may clear all memory as it goes, to avoid this sort of thing. Even if it does, there's still the time during which the char[] contains the actual characters as an attack window.
char[] locations cuts off that line of attack, something not possible when using String.
While other suggestions here seem valid, there is one other good reason. With plain String you have much higher chances of accidentally printing the password to logs, monitors or some other insecure place. char[] is less vulnerable.
Consider this:
public static void main(String[] args) {
Object pw = "Password";
System.out.println("String: " + pw);
pw = "Password".toCharArray();
System.out.println("Array: " + pw);
}
Prints:
String: Password
Array: [C@5829428e
toString is classname@hashcode. [C represents char[], the rest is hexadecimal hash code.
Jan 20, 2012 at 12:39
Password class type for this. It's less obscure, and harder to accidentally pass somewhere.
To quote an official document, the Java Cryptography Architecture guide says this about char[] vs. String passwords (about password-based encryption, but this is more generally about passwords of course):
It would seem logical to collect and store the password in an object of type
java.lang.String. However, here's the caveat:Objects of typeStringare immutable, i.e., there are no methods defined that allow you to change (overwrite) or zero out the contents of aStringafter usage. This feature makesStringobjects unsuitable for storing security sensitive information such as user passwords. You should always collect and store security sensitive information in achararray instead.
Guideline 2-2 of the Secure Coding Guidelines for the Java Programming Language, Version 4.0 also says something similar (although it is originally in the context of logging):
Guideline 2-2: Do not log highly sensitive information
Some information, such as Social Security numbers (SSNs) and passwords, is highly sensitive. This information should not be kept for longer than necessary nor where it may be seen, even by administrators. For instance, it should not be sent to log files and its presence should not be detectable through searches. Some transient data may be kept in mutable data structures, such as char arrays, and cleared immediately after use. Clearing data structures has reduced effectiveness on typical Java runtime systems as objects are moved in memory transparently to the programmer.
This guideline also has implications for implementation and use of lower-level libraries that do not have semantic knowledge of the data they are dealing with. As an example, a low-level string parsing library may log the text it works on. An application may parse an SSN with the library. This creates a situation where the SSNs are available to administrators with access to the log files.
String is pretty well understood and how it behaves in the JVM... there are good reasons to use char[] in place of String when dealing with passwords in a secure manner.
At which point - that's application specific, but the general rule is to do so as soon as you get a hold of something that is supposed to be a password (plaintext or otherwise). You get it from the browser as part of an HTTP request, for instance. You cannot control the delivery, but you can control your own storage, so as soon as you get it, put it in a char[], do what you need to do with it, then set all to '0' and let the gc reclaim it.
Jan 3, 2019 at 19:25
Character arrays (char[]) can be cleared after use by setting each character to zero and Strings not. If someone can somehow see the memory image, they can see a password in plain text if Strings are used, but if char[] is used, after purging data with 0's, the password is secure.
HttpServletRequest object in plaintext. If the JVM version is 1.6 or lower, it'll be in permgen space. If it's in 1.7, it'll still be readable until it gets collected. (Whenever that is.)
intern() on arbitrary strings. But you are right in that the String instances exist in the first place (until collected) and turning them into char[] arrays afterwards doesn’t change it.
new String() or StringBuilder.toString() I managed applications with lots of string constants, and we had lots of permgen creep as a result. Until 1.7.
intern() on an arbitrary string could cause the allocation of an equivalent string in the permgen space. The latter could get GC’ed, if there was no literal string of the same contents sharing that object…
Some people believe that you have to overwrite the memory used to store the password once you no longer need it. This reduces the time window an attacker has to read the password from your system and completely ignores the fact that the attacker already needs enough access to hijack the JVM memory to do this. An attacker with that much access can catch your key events making this completely useless (AFAIK, so please correct me if I am wrong).
Update
Thanks to the comments I have to update my answer. Apparently there are two cases where this can add a (very) minor security improvement as it reduces the time a password could land on the hard drive. Still I think it's overkill for most use cases.
If possible, disabling core dumps and the swap file would take care of both problems. However, they would require administrator rights and may reduce functionality (less memory to use) and pulling RAM from a running system would still be a valid concern.
I don't think this is a valid suggestion, but, I can at least guess at the reason.
I think the motivation is wanting to make sure that you can erase all trace of the password in memory promptly and with certainty after it is used. With a char[] you could overwrite each element of the array with a blank or something for sure. You can't edit the internal value of a String that way.
But that alone isn't a good answer; why not just make sure a reference to the char[] or String doesn't escape? Then there's no security issue. But the thing is that String objects can be intern()ed in theory and kept alive inside the constant pool. I suppose using char[] forbids this possibility.
char[] can be modified, and then it's irrelevant whether it's collected or not. And since string interning needs to be done explicitly for non-literals, it's the same like telling that a char[] can be referenced by a static field.
The answer has already been given, but I'd like to share an issue that I discovered lately with Java standard libraries. While they take great care now of replacing password strings with char[] everywhere (which of course is a good thing), other security-critical data seems to be overlooked when it comes to clearing it from memory.
I'm thinking of e.g. the PrivateKey class. Consider a scenario where you would load a private RSA key from a PKCS#12 file, using it to perform some operation. Now in this case, sniffing the password alone wouldn't help you much as long as physical access to the key file is properly restricted. As an attacker, you would be much better off if you obtained the key directly instead of the password. The desired information can be leaked manifold, core dumps, a debugger session or swap files are just some examples.
And as it turns out, there is nothing that lets you clear the private information of a PrivateKey from memory, because there's no API that lets you wipe the bytes that form the corresponding information.
This is a bad situation, as this paper describes how this circumstance could be potentially exploited.
The OpenSSL library for example overwrites critical memory sections before private keys are freed. Since Java is garbage-collected, we would need explicit methods to wipe and invalidate private information for Java keys, which are to be applied immediately after using the key.
PrivateKey that doesn't actually load its private content in memory: via a PKCS#11 hardware token for example. Perhaps a software implementation of PKCS#11 could take care of cleaning up the memory manually. Perhaps using something like the NSS store (which shares most of its implementation with the PKCS11 store type in Java) is better. The KeychainStore (OSX keystore) loads the full content of the private key into its PrivateKey instances, but it should not need to. (Not sure what the WINDOWS-MY KeyStore does on Windows.)
char[] "now", because I'm looking at this nice new ConnectionBuilder class added in JDK 9, and it still has password(String) and no option to pass char[] at all. It seems that with Java there's a lot of "do what I say, not what I do".
As Jon Skeet states, there is no way except by using reflection.
However, if reflection is an option for you, you can do this.
public static void main(String[] args) {
System.out.println("please enter a password");
// don't actually do this, this is an example only.
Scanner in = new Scanner(System.in);
String password = in.nextLine();
usePassword(password);
clearString(password);
System.out.println("password: '" + password + "'");
}
private static void usePassword(String password) {
}
private static void clearString(String password) {
try {
Field value = String.class.getDeclaredField("value");
value.setAccessible(true);
char[] chars = (char[]) value.get(password);
Arrays.fill(chars, '*');
} catch (Exception e) {
throw new AssertionError(e);
}
}
when run
please enter a password
hello world
password: '***********'
Note: if the String's char[] has been copied as a part of a GC cycle, there is a chance the previous copy is somewhere in memory.
This old copy wouldn't appear in a heap dump, but if you have direct access to the raw memory of the process you could see it. In general you should avoid anyone having such access.
'***********'.
Aug 27, 2015 at 19:21
Scanner’s internal buffer and, since you didn’t use System.console().readPassword(), in readable form in the console window. But for most practical use cases, the duration of usePassword’s execution is the actual problem. E.g., when making a connection to another machine, it takes a significant time and tells an attacker that it is the right time to search for the password in the heap. The only solution is to prevent attackers from reading the heap memory…
There is nothing that char array gives you vs String unless you clean it up manually after use, and I haven't seen anyone actually doing that. So to me the preference of char[] vs String is a bit exaggerated.
Take a look at the widely used Spring Security library here and ask yourself - are Spring Security guys incompetent or char[] passwords just don't make much sense. When some nasty hacker grabs memory dumps of your RAM be sure s/he'll get all the passwords even if you use sophisticated ways to hide them.
However, Java changes all the time, and some scary features like String Deduplication feature of Java 8 might intern String objects without your knowledge. But that's a different conversation.
BCrypt and BCryptPasswordEncoder. Even in the simultaneous initial commit they took an inconsistent approach: taking String for Bcrypt and taking CharSequence for BCryptPasswordEncoder (which calls Bcrypt).
Sep 17, 2019 at 16:58
Edit: Coming back to this answer after a year of security research, I realize it makes the rather unfortunate implication that you would ever actually compare plaintext passwords. Please don't. Use a secure one-way hash with a salt and a reasonable number of iterations. Consider using a library: this stuff is hard to get right!
Original answer: What about the fact that String.equals() uses short-circuit evaluation, and is therefore vulnerable to a timing attack? It may be unlikely, but you could theoretically time the password comparison in order to determine the correct sequence of characters.
public boolean equals(Object anObject) {
if (this == anObject) {
return true;
}
if (anObject instanceof String) {
String anotherString = (String)anObject;
int n = value.length;
// Quits here if Strings are different lengths.
if (n == anotherString.value.length) {
char v1[] = value;
char v2[] = anotherString.value;
int i = 0;
// Quits here at first different character.
while (n-- != 0) {
if (v1[i] != v2[i])
return false;
i++;
}
return true;
}
}
return false;
}
Some more resources on timing attacks:
Arrays.equals for char[] is as high as for String.equals. If anyone cared, there was a dedicated key class encapsulating the actual password and taking care of the issues—oh wait, the real security packages have dedicated key classes, this Q&A is only about a habit outside of them, say, e.g. JPasswordField, to use char[] instead of String (where the actual algorithms use byte[] anyway).
sleep(secureRandom.nextInt()) before rejecting a login attempt anyway, that’s not only removing the possibility of timing attacks, it also makes counteracts brute force attempts.
Strings are immutable and cannot be altered once they have been created. Creating a password as a string will leave stray references to the password on the heap or on the String pool. Now if someone takes a heap dump of the Java process and carefully scans through he might be able to guess the passwords. Of course these non used strings will be garbage collected but that depends on when the GC kicks in.
On the other side char[] are mutable as soon as the authentication is done you can overwrite them with any character like all M's or backslashes. Now even if someone takes a heap dump he might not be able to get the passwords which are not currently in use. This gives you more control in the sense like clearing the Object content yourself vs waiting for the GC to do it.
strings AND the String pool (pool of previously used strings) were BOTH stored in Permgen prior to 1.7. Also, See section 5.1: docs.oracle.com/javase/specs/jvms/se6/html/… The JVM always checked Strings to see if they were the same reference value, and would call String.intern() FOR YOU. The result was that every time the JVM detected identical Strings in the constant_pool or heap it would move them into permgen. And I worked on several applications with "creeping permgen" until 1.7. It was a real problem.
constant_pool which was located IN permgen, and then if a string was used more than once, it would be interned.
String is immutable and it goes to the string pool. Once written, it cannot be overwritten.
char[] is an array which you should overwrite once you used the password and this is how it should be done:
char[] passw = request.getPassword().toCharArray()
if (comparePasswords(dbPassword, passw) {
allowUser = true;
cleanPassword(passw);
cleanPassword(dbPassword);
passw = null;
}
private static void cleanPassword (char[] pass) {
Arrays.fill(pass, '0');
}
One scenario where the attacker could use it is a crashdump—when the JVM crashes and generates a memory dump—you will be able to see the password.
That is not necessarily a malicious external attacker. This could be a support user that has access to the server for monitoring purposes. He/she could peek into a crashdump and find the passwords.
request.getPassword() already create the string and add it to the pool?
ch = '0' changes the local variable ch; it has no effect on the array. And your example is pointless anyway, you start with a string instance you call toCharArray() on, creating a new array and even when you overwrite the new array correctly, it doesn’t change the string instance, so it has no advantage over just using the string instance.
The short and straightforward answer would be because char[] is mutable while String objects are not.
Strings in Java are immutable objects. That is why they can't be modified once created, and therefore the only way for their contents to be removed from memory is to have them garbage collected. It will be only then when the memory freed by the object can be overwritten, and the data will be gone.
Now garbage collection in Java doesn't happen at any guaranteed interval. The String can thus persist in memory for a long time, and if a process crashes during this time, the contents of the string may end up in a memory dump or some log.
With a character array, you can read the password, finish working with it as soon as you can, and then immediately change the contents.
Case String:
String password = "ill stay in StringPool after Death !!!";
// some long code goes
// ...Now I want to remove traces of password
password = null;
password = "";
// above attempts wil change value of password
// but the actual password can be traced from String pool through memory dump, if not garbage collected
Case CHAR ARRAY:
char[] passArray = {'p','a','s','s','w','o','r','d'};
// some long code goes
// ...Now I want to remove traces of password
for (int i=0; i<passArray.length;i++){
passArray[i] = 'x';
}
// Now you ACTUALLY DESTROYED traces of password form memory
A string in Java is immutable. So whenever a string is created, it will remain in memory until it is garbage collected. So anyone who has access to the memory can read the value of the string.
If the value of the string is modified then it will end up creating a new string. So both the original value and the modified value stay in the memory until it is garbage collected.
With the character array, the contents of the array can be modified or erased once the purpose of the password is served. The original contents of the array will not be found in memory after it is modified and even before the garbage collection kicks in.
Because of the security concern it is better to store password as a character array.
It is debatable as to whether you should use String or use Char[] for this purpose because both have their advantages and disadvantages. It depends on what the user needs.
Since Strings in Java are immutable, whenever some tries to manipulate your string it creates a new Object and the existing String remains unaffected. This could be seen as an advantage for storing a password as a String, but the object remains in memory even after use. So if anyone somehow got the memory location of the object, that person can easily trace your password stored at that location.
Char[] is mutable, but it has the advantage that after its usage the programmer can explicitly clean the array or override values. So when it's done being used it is cleaned and no one could ever know about the information you had stored.
Based on the above circumstances, one can get an idea whether to go with String or to go with Char[] for their requirements.
A lot of the previous answers are great. There is another point which I am assuming (please correct me if I am wrong).
By default Java uses UTF-16 for storing strings. Using character arrays, char[] array, facilitates use of Unicode, regional characters, etc. This technique allows all character set to be respected equally for storing the passwords and henceforth will not initiate certain crypto issues due to character set confusion. Finally, using the character array, we can convert the password array to our desired character set string.
