What is the difference between encrypting some data vs signing some data (using RSA)?

Does it simply reverse the role of the public-private keys?

For example, I want to use my private key to generate messages so only I can possibly be the sender. I want my public key to be used to read the messages and I do not care who reads them. I want to be able to encrypt certain information and use it as a product-key for my software. I only care that I am the only one who can generate these. I would like to include my public key in my software to decrypt/read the signature of the key. I do not care who can read the data in the key, I only care that I am the only verifiable one who can generate them.

Is signing useful in this scenario?

11 Answers 11

up vote 302 down vote accepted

When encrypting, you use their public key to write message and they use their private key to read it.

When signing, you use your private key to write message's signature, and they use your public key to check if it's really yours.

I want to use my private key to generate messages so only I can possibly be the sender.

I want my public key to be used to read the messages and I do not care who reads them

This is signing, it is done with your private key.

I want to be able to encrypt certain information and use it as a product-key for my software.

I only care that I am the only one who can generate these.

If you only need to know it to yourself, you don't need to mess with keys to do this. You may just generate random data and keep it in a database.

But if you want people to know that the keys are really yours, you need to generate random data, keep in it a database AND sign it with your key.

I would like to include my public key in my software to decrypt/read the signature of the key

You'll probably need to purchase a certificate for your public key from a commercial provider like Verisign or Thawte, so that people may check that no one had forged you software and replaced your public key with their.

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    Technically speaking, when you say the private key is used to write the message's signature, you're saying that the hash of the message is being encrypted with my private key? – Andy Ibanez Nov 2 '15 at 21:39
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    @AndyIbanez: what is encrypted (the digest) may also include timestamp and some random salt, but yes, that's the gist of it. – Quassnoi Nov 2 '15 at 21:53
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    @Quassnoi In fact when we say 'sign with the private key', it means not 'encrypt' but instead means 'decrypt'. Sign the message roughly speaking is the same as decrypt with the private key and in the receiver encrypt with public key, this way the hash will became the same and could be compared. – Johnny Willer Nov 6 '15 at 19:52
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    @JohnnyWiller: as @slim mentioned below, the mathematical core is the same for both encrypt and decrypt functions. They are not separate functions, they are the same function f(key, message), such that f(private, f(public, message)) === f(public, f(private, message)) === message – Quassnoi Nov 6 '15 at 21:57
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    @Quassnoi You mean for every public key there is only 1 possible private key? – Honey May 11 '16 at 21:00

In RSA crypto, when you generate a key pair, it's completely arbitrary which one you choose to be the public key, and which is the private key. If you encrypt with one, you can decrypt with the other - it works in both directions.

So, it's fairly simple to see how you can encrypt a message with the receiver's public key, so that the receiver can decrypt it with their private key.

A signature is proof that the signer has the private key that matches some public key. To do this, it would be enough to encrypt the message with that sender's private key, and include the encrypted version alongside the plaintext version. To verify the sender, decrypt the encrypted version, and check that it is the same as the plaintext.

Of course, this means that your message is not secret. Anyone can decrypt it, because the public key is well known. But when they do so, they have proved that the creator of the ciphertext has the corresponding private key.

However, this means doubling the size of your transmission - plaintext and ciphertext together (assuming you want people who aren't interested in verifying the signature, to read the message). So instead, typically a signature is created by creating a hash of the plaintext. It's important that fake hashes can't be created, so cryptographic hash algorithms such as SHA-2 are used.

So:

  • To generate a signature, make a hash from the plaintext, encrypt it with your private key, include it alongside the plaintext.
  • To verify a signature, make a hash from the plaintext, decrypt the signature with the sender's public key, check that both hashes are the same.
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    @headcode it only applies to asymmetric keys. Symmetric keys don't come in pairs. – slim Jul 4 '15 at 18:06
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    In fact, it only applies to RSA keys. With ECDSA keys, for example, you can trivially generate the public key from the private key, and the private key is a scalar while the public key is a coordinate. – David Schwartz Jun 13 '16 at 16:57
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    How can you decrypt messages with PUBLIC keys? Aren't messages only decrypted with private keys? – daremkd Jul 25 '16 at 10:52
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    @kuhajeyan if you encrypt with a private key, then anyone with the public key can decrypt. Since the public key is not a secret, there's little point in doing that, except to produce a signature. – slim Jul 12 '17 at 9:01
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    5 sources contradicting this answer 1, 2, 3, 4, 5 – Alex L Aug 10 '17 at 15:03

Yeah think of signing data as giving it your own wax stamp that nobody else has. It is done to achieve integrity and non-repudiation. Encryption is so no-one else can see the data. This is done to achieve confidentiality. See wikipedia http://en.wikipedia.org/wiki/Information_security#Key_concepts

A signature is a hash of your message signed using your private key.

Signing is producing a "hash" with your private key that can be verified with your public key. The text is sent in the clear.

Encrypting uses the receiver's public key to encrypt the data; decoding is done with their private key.

So, the use of keys is not reversed (otherwise your private key wouldn't be private anymore!).

  • In normal Asymmetric encryption, encryption is done with the recipients public key, not your private key. – mmcdole Jan 17 '09 at 21:16
  • I fixed it for him. – slim Jan 17 '09 at 22:06
  • Did you miss that this question was specifically about RSA where the use of the keys is reversed and where it does not compromise the private key. – David Schwartz Jun 13 '16 at 16:56

Signing indicates you really are the source or vouch for of the object signed. Everyone can read the object, though.

Encrypting means only those with the corresponding private key can read it, but without signing there is no guarantee you are behind the encrypted object.

You are describing exactly how and why signing is used in public key cryptography. Note that it's very dangerous to sign (or encrypt) aritrary messages supplied by others - this allows attacks on the algorithms that could compromise your keys.

There are two distinct but closely related problems in establishing a secure communication

  1. Encrypt data so that only authorized persons can decrypt and read it
  2. Verify the identity/authentication of sender

Both of these problems can be elegantly solved using public key cryptography.

I. Encryption and decryption of data

Alice wants to send a message to Bob which no one should be able to read.

  • Alice encrypts the message with Bob's public key and sends it over
  • Bob receives the message and decrypts it using his Private Key

Note that if A wants to send a message to B, A needs to use the Public key of B (which is publicly available to anyone) and neither public nor private key of A comes into picture here.

So if you want to send a message to me you should know and use my public key which I provide to you and only I will be able to decrypt the message since I am the only one who has access to the corresponding private key

II. Verify the identity of sender (Authentication)

Alice wants to send a message to Bob again. The problem of encrypting the data is solved using the above method.

But what if I am sitting between Alice and Bob, introducing myself as 'Alice' to Bob and sending my own message to Bob instead of forwarding the one sent by Alice. Even though I can not decrypt and read the original message sent by Alice(that requires access to Bob's private key) I am hijacking the entire conversation between them.

Is there a way Bob can confirm that the messages he is receiving are actually sent by Alice?

  • Alice signs the message with her private key (Alice's private key) and send it over
  • Bob receives it and decrypts using Alice's public key. Since Alice's public key successfully decrypted the message, Bob can conclude that the message has been signed using Alice

In practice, both of the above methods are used together along with some form of hashing (SHA, MD5) to achieve encryption and authenticity.

  • I think this is a very clear answer – Henry Yang Oct 3 at 2:29
  • So when you sign the message, do you sign the actual message itself or the encrypted message? – FrostyStraw Nov 9 at 5:04

In your scenario, you do not encrypt in the meaning of asymmetric encryption; I'd rather call it "encode".

So you encode your data into some binary representation, then you sign with your private key. If you cannot verify the signature via your public key, you know that the signed data is not generated with your private key. ("verification" meaning that the unsigned data is not meaningful)

Functionally, you use public/private key encryption to make certain only the receiver can read your message. The message is encrypted then encrypted using the public key of the receiver.

Signing you use to let the receiver know you created the message and it has not changed during transfer. Message signing is done using your own private key.

As for the algorithm used: this involes prime-numbers. I'd do a search on google for a better explanation.

  • Can you comment on my use case? I want to use a private key to encrypt and a public key to allow anyone and everyone to decrypt. – mmcdole Jan 17 '09 at 21:17
  • It's not true that all asymmetric encryption is based on prime numbers, it's just the most well-known example (RSA); there are other methods such as elliptic curve cryptography. – Michael Borgwardt Jan 17 '09 at 21:18

I think there are mixed messages above. I was trying to achieve the same thing as Simucal was - i.e. I wanted to generate a licence key that holds important information about who can use the software and between what date ranges etc. But I don't want people to be able to amend that information to extend their licence period etc. My first approach was to use asymetric encryption, but despite some of the comments above, it appears that you can encrypt using either the public OR private key, BUT ONLY decrypt it using the private key. Therefore, in this scenario, you would have to store the private key in the system in order for it to decode and check the licence key... rendering the system pretty insecure because anybody could generate their own modified licence information and encrypt it using the public OR private key (one of which would be stored in the system binary files). The same security risk is attached to symetric encryption of course.

As many of the comments above point to, signing appears to be the way forward for this scenario, but I have yet to find a good example. Does anybody know of a tutorial or online demo that provides a run-through of such a method? Thanks, Chris

  • Did you find example? – Stefano Mtangoo May 23 '13 at 16:12
  • If the claim made here was true PKI wouldn't work at all, and it does. – user207421 Mar 10 '16 at 11:42

Answering this question in the content that the questioners intent was to use the solution for software licensing, the requirements are:

  1. No 3rd party can produce a license key from decompiling the app
  2. The content of the software key does not need to be secure
  3. Software key is not human readable

A Digital Signature will solve this issue as the raw data that makes the key can be signed with a private key which makes it not human readable but could be decoded if reverse engineered. But the private key is safe which means no one will be able to make licenses for your software (which is the point).

Remember you can not prevent a skilled person from removing the software locks on your product. So if they have to hack each version that is released. But you really don't want them to be able to generate new keys for your product that can be shared for all versions.

Python The PyNaCl documentation has an example of 'Digital Signature' which will suite the purpose. http://pynacl.readthedocs.org/en/latest/signing/

and of cause NaCl project to C examples

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