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the encryption keys, why can't the government just sneak on them?
(lemmy.dbzer0.com)
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this is very detailed answer thank you. however I face an ambiguity regarding this:
How can this private half be something that I know, Youtube knows but impossible for the snooper to our communication to know??
Your computer generates two keys. One to encrypt a message. One to decrypt the message. The encrypt key is public. The decrypt key is private. Your computer shares the public key with YouTube. The private key is never shared.
YouTube does the same thing for your computer.
Your computer will have YouTube’s public key and your computer’s private key..
Your computer will be able to encrypt messages to send to YouTube that only YouTube will be able to decrypt. Even your computer will not be able to decrypt these messages after it has encrypted them using YouTube’s public key.
Since the decryption keys are never shared they can’t be snooped. That is why it is only possible for an attacker to encrypt new messages but not read any messages from either sender.
Good description of asymmetric cryptography!
Youtube never knows the private half of your key pair. That never leaves your system.
Anything encrypted with the private half can only be decrypted with the public half, and anything encrypted with the public half can only be decrypted with the private half. These halves are known as the public key and the private key. Each side of the connection generates their own key pairs.
We both generate a set of keys, and exchange the public halves with each other. I then want to send you a message: I first encrypt it using my private key, I then encrypt it again using your public key and send that to you.
In order to read that message, you first decrypt it using your private key. This ensures the message was intended for you and wasn't modified in transit, as you are the only one with access to that private key and only its matching public key could have been used to encrypt that layer.
You then decrypt it a second time using my public key. As I'm the only one with access to my own private key, you can be sure the message was sent by me.
As long as that resulted in a readable message; You've now verified who sent the message, that it was intended for you, and that the contents have not been modified or read in transit.
All this, including the key exchange is handled for you by the https (tls) protocol every time you connect to a website. Each of the messages sent between you and the site are encrypted in this manner.
so you can encrypt a message with my public key but you cannot decrypt it afterward ??
The best way I find to think about it is a padlocked box.
The public key is a box with an open padlock on it. I can give it to anyone. If someone puts a message inside the box they can lock the padlock, but they don't have the key to open it again.
I keep the key private. If someone sends me a locked box that has my padlock on it, only I have the key to open it and read the message.
Exactly. Once encrypted with your public key, you're the only one who can decrypt and read it as you are the only one with access to your private key.
This is not true. In key pair cryptography, the public key used only for encryption and the private key is used only for decryption.
As far as I understand a key pair can be used bi-directionally like I'd described. Was I mistaken?
In practice, the private key is usually used to create signatures instead, but I avoided that for simplicity.
You're not mistaken, it is definitely possible with at least RSA, though, I would guess it may not always be possible. It also sounds like it's still a bad idea unless you know all of the parameters used to generate the keys and can be sure what information is actually encoded in the keys.
no, it isn't bidirectional, public = encrypt, private = decrypt, that's it. You can address a message to multiple recipients though (when using GPG), so often in case of email a message is addressed both to yourself and your recipient, so both you and your recipient have access to message text