day25: Day 25: Combo Breaker
In tjmahr/adventofcode20: Advent of Code 2020
Description
Usage
Arguments
Details
Value
Examples
Description
Usage
1
2
3
Arguments
x
some data
example
Which example data to use (by position or name). Defaults to
1.
Details
Part One
You finally reach the check-in desk. Unfortunately, their registration
systems are currently offline, and they cannot check you in. Noticing
the look on your face, they quickly add that tech support is already on
the way! They even created all the room keys this morning; you can take
yours now and give them your room deposit once the registration system
comes back online.
The room key is a small
RFID
card. Your room is on the 25th floor and the elevators are also
temporarily out of service, so it takes what little energy you have left
to even climb the stairs and navigate the halls. You finally reach the
door to your room, swipe your card, and - beep - the light turns red.
Examining the card more closely, you discover a phone number for tech
support.
\"Hello! How can we help you today?\" You explain the situation.
\"Well, it sounds like the card isn\'t sending the right command to
unlock the door. If you go back to the check-in desk, surely someone
there can reset it for you.\" Still catching your breath, you describe
the status of the elevator and the exact number of stairs you just had
to climb.
\"I see! Well, your only other option would be to reverse-engineer the
cryptographic handshake the card does with the door and then inject your
own commands into the data stream, but that\'s definitely impossible.\"
You thank them for their time.
Unfortunately for the door, you know a thing or two about cryptographic
handshakes.
The handshake used by the card and the door involves an operation that
transforms a subject number. To transform a subject number, start
with the value 1. Then, a number of times called the loop size,
perform the following steps:
Set the value to itself multiplied by the subject number.
Set the value to the remainder after dividing the value by
20201227.
The card always uses a specific, secret loop size when it transforms a
subject number. The door always uses a different, secret loop size.
The cryptographic handshake works like this:
The card transforms the subject number of 7 according to the
card\'s secret loop size. The result is called the card\'s public
key.
The door transforms the subject number of 7 according to the
door\'s secret loop size. The result is called the door\'s public
key.
The card and door use the wireless RFID signal to transmit the two
public keys (your puzzle input) to the other device. Now, the card
has the door\'s public key, and the door has the card\'s
public key. Because you can eavesdrop on the signal, you have both
public keys, but neither device\'s loop size.
The card transforms the subject number of the door\'s public key
according to the card\'s loop size. The result is the encryption
key.
The door transforms the subject number of the card\'s public key
according to the door\'s loop size. The result is the same
encryption key as the card calculated.
If you can use the two public keys to determine each device\'s loop
size, you will have enough information to calculate the secret
encryption key that the card and door use to communicate; this would
let you send the unlock command directly to the door!
For example, suppose you know that the card\'s public key is 5764801.
With a little trial and error, you can work out that the card\'s loop
size must be 8, because transforming the initial subject number of
7 with a loop size of 8 produces 5764801.
Then, suppose you know that the door\'s public key is 17807724. By the
same process, you can determine that the door\'s loop size is 11,
because transforming the initial subject number of 7 with a loop size
of 11 produces 17807724.
At this point, you can use either device\'s loop size with the other
device\'s public key to calculate the encryption key. Transforming the
subject number of 17807724 (the door\'s public key) with a loop size
of 8 (the card\'s loop size) produces the encryption key,
14897079. (Transforming the subject number of 5764801 (the card\'s
public key) with a loop size of 11 (the door\'s loop size) produces
the same encryption key: 14897079.)
What encryption key is the handshake trying to establish?
Part Two
(Use have to manually add this yourself.)
(Try using convert_clipboard_html_to_roxygen_md())
Value
For Part One, f25a(x) returns .... For Part Two,
f25b(x) returns ....
Examples
1
2
tjmahr/adventofcode20 documentation built on Dec. 31, 2020, 8:39 a.m.
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Description Usage Arguments Details Value Examples
Description
Usage
1 2 3 |
Arguments
x |
some data |
example |
Which example data to use (by position or name). Defaults to 1. |
Details
Part One
You finally reach the check-in desk. Unfortunately, their registration systems are currently offline, and they cannot check you in. Noticing the look on your face, they quickly add that tech support is already on the way! They even created all the room keys this morning; you can take yours now and give them your room deposit once the registration system comes back online.
The room key is a small RFID card. Your room is on the 25th floor and the elevators are also temporarily out of service, so it takes what little energy you have left to even climb the stairs and navigate the halls. You finally reach the door to your room, swipe your card, and - beep - the light turns red.
Examining the card more closely, you discover a phone number for tech support.
\"Hello! How can we help you today?\" You explain the situation.
\"Well, it sounds like the card isn\'t sending the right command to unlock the door. If you go back to the check-in desk, surely someone there can reset it for you.\" Still catching your breath, you describe the status of the elevator and the exact number of stairs you just had to climb.
\"I see! Well, your only other option would be to reverse-engineer the cryptographic handshake the card does with the door and then inject your own commands into the data stream, but that\'s definitely impossible.\" You thank them for their time.
Unfortunately for the door, you know a thing or two about cryptographic handshakes.
The handshake used by the card and the door involves an operation that
transforms a subject number. To transform a subject number, start
with the value 1. Then, a number of times called the loop size,
perform the following steps:
Set the value to itself multiplied by the subject number.
Set the value to the remainder after dividing the value by
20201227.
The card always uses a specific, secret loop size when it transforms a subject number. The door always uses a different, secret loop size.
The cryptographic handshake works like this:
The card transforms the subject number of
7according to the card\'s secret loop size. The result is called the card\'s public key.The door transforms the subject number of
7according to the door\'s secret loop size. The result is called the door\'s public key.The card and door use the wireless RFID signal to transmit the two public keys (your puzzle input) to the other device. Now, the card has the door\'s public key, and the door has the card\'s public key. Because you can eavesdrop on the signal, you have both public keys, but neither device\'s loop size.
The card transforms the subject number of the door\'s public key according to the card\'s loop size. The result is the encryption key.
The door transforms the subject number of the card\'s public key according to the door\'s loop size. The result is the same encryption key as the card calculated.
If you can use the two public keys to determine each device\'s loop
size, you will have enough information to calculate the secret
encryption key that the card and door use to communicate; this would
let you send the unlock command directly to the door!
For example, suppose you know that the card\'s public key is 5764801.
With a little trial and error, you can work out that the card\'s loop
size must be 8, because transforming the initial subject number of
7 with a loop size of 8 produces 5764801.
Then, suppose you know that the door\'s public key is 17807724. By the
same process, you can determine that the door\'s loop size is 11,
because transforming the initial subject number of 7 with a loop size
of 11 produces 17807724.
At this point, you can use either device\'s loop size with the other
device\'s public key to calculate the encryption key. Transforming the
subject number of 17807724 (the door\'s public key) with a loop size
of 8 (the card\'s loop size) produces the encryption key,
14897079. (Transforming the subject number of 5764801 (the card\'s
public key) with a loop size of 11 (the door\'s loop size) produces
the same encryption key: 14897079.)
What encryption key is the handshake trying to establish?
Part Two
(Use have to manually add this yourself.)
(Try using convert_clipboard_html_to_roxygen_md())
Value
For Part One, f25a(x) returns .... For Part Two,
f25b(x) returns ....
Examples
1 2 |
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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