Since Ed25519 has not been around for long (in JDK), there are very few resources on how to use it.

While their example is very neat and useful, I have some trouble understanding what am I doing wrong regarding key parsing.

They Public Key is being read from a packet sent by an iDevice.

**(Let's just say, it's an array of bytes)**

From the searching and trying my best to understand how the keys are encoded, I stumbled upon this message.

```
4. The public key A is the encoding of the point [s]B. First,
encode the y-coordinate (in the range 0 <= y < p) as a little-
endian string of 32 octets. The most significant bit of the
final octet is always zero. To form the encoding of the point
[s]B, copy the least significant bit of the x coordinate to the
most significant bit of the final octet. The result is the
public key.
```

That means that if I want to get `y`

and `isXOdd`

I have to do some work.
**(If I understood correctly)**

Below is the code for it, yet the verifying still fails.

I think, I did it correctly by reversing the array to get it back into Big Endian for BigInteger to use.

My questions are:

- Is this the correct way to parse the public key from byte arrays
- If it is, what could possibly be the reason for it to fail the verifying process?

```
// devicePublicKey: ByteArray
val lastIndex = devicePublicKey.lastIndex
val lastByte = devicePublicKey[lastIndex]
val lastByteAsInt = lastByte.toInt()
val isXOdd = lastByteAsInt.and(255).shr(7) == 1
devicePublicKey[lastIndex] = (lastByteAsInt and 127).toByte()
val y = devicePublicKey.reversedArray().asBigInteger
val keyFactory = KeyFactory.getInstance("Ed25519")
val nameSpec = NamedParameterSpec.ED25519
val point = EdECPoint(isXOdd, y)
val keySpec = EdECPublicKeySpec(nameSpec, point)
val key = keyFactory.generatePublic(keySpec)
Signature.getInstance("Ed25519").apply {
initVerify(key)
update(deviceInfo)
println(verify(deviceSignature))
}
```

And the data (before manipulation) (all in HEX):

```
Device identifier: 34444432393531392d463432322d343237442d414436302d444644393737354244443533
Device public key: e0a611c84db0ae91abfe2e6db91b6a457a4b41f9d8e09afdc7207ce3e4942e94
Device signature: a0383afb3bcbd43d08b04274a9214036f16195dc890c07a81aa06e964668955b29c5026d73d8ddefb12160529eeb66f843be4a925b804b575e6a259871259907
Device info: a86a71d42874b36e81a0acc65df0f2a84551b263b80b61d2f70929cd737176a434444432393531392d463432322d343237442d414436302d444644393737354244443533e0a611c84db0ae91abfe2e6db91b6a457a4b41f9d8e09afdc7207ce3e4942e94
// Device info is simply concatenated [hkdf, identifier, public key]
```

And the public key after the manipulation:

```
e0a611c84db0ae91abfe2e6db91b6a457a4b41f9d8e09afdc7207ce3e4942e14
```

Thank you very much, and every bit of help is greatly appreciated. This will help many more who will stumble upon this problem at a later point, when the Ed25519 implementation will not be so fresh.