You've essentially asked three questions:

- What is this code doing?
- Why is
`1`

bad?
- Why was it replaced with
`65537`

?

It sounds like you don't have a lot of cryptography background, so I'll try to fill in some of the gaps there as well.

## What is this code doing?

To understand why the original value of `1`

was a broken choice, you have to understand a little bit about how RSA works.

RSA is a *cryptosystem* -- a way of performing key generation, encryption, and decryption -- so that you can send messages securely to other people. RSA is a member of a class called *public-key cryptosystems*, because the key that you use to encrypt messages is *public* and can be freely known by everyone. The key you use to decrypt messages enciphered with your public key is secret and known only by you, so we call it a *private key*.

If you imagine padlocks and keys as the analog to public keys and private keys, you can see how this might work with real-world messages:

- Bob gives Alice a padlock (his public key) and keeps the key to the lock (his private key).
- Now, if Alice wants to send a Bob a message, she puts a message inside a box, puts his padlock on a box, and sends him the box.
- Only Bob has the key, so only Bob can unlock the padlock and get inside the box.

To actually generate the key, RSA needs three important numbers:

- "N", the product of two very large prime numbers p and q
- "e", the "public exponent"
- "d", the "private exponent"

A big part of the security of RSA comes from the fact that it should be very difficult to figure out what `d`

is, given `N`

and `e`

. The public key in RSA consists of two numbers: `<N,e>`

, while the private key is `<N,d>`

.

In other words, if I know what Bob's padlock looks like, it should be **very difficult** to reverse-engineer a key that will open Bob's padlock.

## Why is `1`

bad?

`1`

is a bad choice because it makes **very easy** to reverse-engineer a key that will open Bob's padlock, which is the opposite of what we want.

The problematic section in full looks like this:

```
def gen_keys(keydir, keyname, keysize, user=None):
# Generate a keypair for use with salt
# ...
gen = RSA.gen_key(keysize, 1, callback=lambda x, y, z: None)
```

This is a Python fragment which generates a RSA key with `e = 1`

.

The relationship between `N`

, `e`

, and `d`

is given by:

```
d*e = 1 mod (p-1)(q-1)
```

But wait: if you pick `e = 1`

, as SaltStack did, then you have a problem:

```
d = 1 mod (p-1)(q-1)
```

Now you have the private key! The security is broken, since you can figure out what `d`

is. So you can decrypt everyone's transmissions -- you've made it so that you can trivially get Bob's key given his padlock. Oops.

It actually gets worse than that. In RSA, encryption means that you have a message `m`

to transmit that you want to encrypt with the public key `<N,e>`

. The enciphered message `c`

is computed as:

```
c = m^e (mod N)
```

So, if `e = 1`

, then `m^e = m`

, and you have `c = m mod N`

.

**But if **`m < N`

, then `m mod N`

is `m`

. So you have:

```
c = m
```

The enciphered text is the same the message text, **so no encryption is happening at all!** Double oops.

Hopefully it's clear why `1`

is a bad choice!

## Why is `65537`

better?

65537 seems like an unusual, arbitrary choice. You may wonder why, for instance, we couldn't just pick `e = 3`

. The lower `e`

is, the faster encryption becomes, since to encrypt anything we have to execute:

```
c = m^e (mod N)
```

and `m^e`

can be a very large number when `e`

is large.

It turns out that 65537 is mostly for compatibility reasons with existing hardware and software, and for a few other reasons. This Cryptography StackExchange answer explains it in good detail.

With a suitable random padding scheme, you can pick almost any odd integer higher other than 1 without affecting security, so `e = 3`

is otherwise a choice that maximizes performance.