6.6 KiB
— Day 2: 1202 Program Alarm —
On the way to your gravity assist around the Moon, your ship computer beeps angrily about a "1202 program alarm". On the radio, an Elf is already explaining how to handle the situation: "Don't worry, that's perfectly norma–" The ship computer bursts into flames.
You notify the Elves that the computer's magic smoke seems to have escaped. "That computer ran Intcode programs like the gravity assist program it was working on; surely there are enough spare parts up there to build a new Intcode computer!"
An Intcode program is a list of
integers separated by commas
(like 1,0,0,3,99). To run one, start by looking at the first integer
(called position 0). Here, you will find an opcode - either 1,
2, or 99. The opcode indicates what to do; for example, 99 means
that the program is finished and should immediately halt. Encountering
an unknown opcode means something went wrong.
Opcode 1 adds together numbers read from two positions and stores
the result in a third position. The three integers immediately after
the opcode tell you these three positions - the first two indicate the
positions from which you should read the input values, and the third
indicates the position at which the output should be stored.
For example, if your Intcode computer encounters 1,10,20,30, it should
read the values at positions 10 and 20, add those values, and then
overwrite the value at position 30 with their sum.
Opcode 2 works exactly like opcode 1, except it multiplies the two
inputs instead of adding them. Again, the three integers after the
opcode indicate where the inputs and outputs are, not their values.
Once you're done processing an opcode, move to the next one by
stepping forward 4 positions.
For example, suppose you have the following program:
1,9,10,3,2,3,11,0,99,30,40,50
For the purposes of illustration, here is the same program split into multiple lines:
1,9,10,3, 2,3,11,0, 99, 30,40,50
The first four integers, 1,9,10,3, are at positions 0, 1, 2, and
3. Together, they represent the first opcode (1, addition), the
positions of the two inputs (9 and 10), and the position of the
output (3). To handle this opcode, you first need to get the values at
the input positions: position 9 contains 30, and position 10
contains 40. Add these numbers together to get 70. Then, store
this value at the output position; here, the output position (3) is
at position 3, so it overwrites itself. Afterward, the program looks
like this:
1,9,10,70, 2,3,11,0, 99, 30,40,50
Step forward 4 positions to reach the next opcode, 2. This opcode
works just like the previous, but it multiplies instead of adding. The
inputs are at positions 3 and 11; these positions contain 70 and
50 respectively. Multiplying these produces 3500; this is stored at
position 0:
3500,9,10,70, 2,3,11,0, 99, 30,40,50
Stepping forward 4 more positions arrives at opcode 99, halting the
program.
Here are the initial and final states of a few more small programs:
1,0,0,0,99becomes2,0,0,0,99(1 + 1 = 2).2,3,0,3,99becomes2,3,0,6,99(3 * 2 = 6).2,4,4,5,99,0becomes2,4,4,5,99,9801(99 * 99 = 9801).1,1,1,4,99,5,6,0,99becomes30,1,1,4,2,5,6,0,99.
Once you have a working computer, the first step is to restore the
gravity assist program (your puzzle input) to the "1202 program alarm"
state it had just before the last computer caught fire. To do this,
before running the program, replace position 1 with the value 12
and replace position 2 with the value 2. What value is left at
position 0 after the program halts?
Your puzzle answer was 3790689.
— Part Two —
"Good, the new computer seems to be working correctly! Keep it nearby during this mission - you'll probably use it again. Real Intcode computers support many more features than your new one, but we'll let you know what they are as you need them."
"However, your current priority should be to complete your gravity assist around the Moon. For this mission to succeed, we should settle on some terminology for the parts you've already built."
Intcode programs are given as a list of integers; these values are used as the initial state for the computer's memory. When you run an Intcode program, make sure to start by initializing memory to the program's values. A position in memory is called an address (for example, the first value in memory is at "address 0").
Opcodes (like 1, 2, or 99) mark the beginning of an instruction.
The values used immediately after an opcode, if any, are called the
instruction's parameters. For example, in the instruction 1,2,3,4,
1 is the opcode; 2, 3, and 4 are the parameters. The instruction
99 contains only an opcode and has no parameters.
The address of the current instruction is called the instruction
pointer; it starts at 0. After an instruction finishes, the
instruction pointer increases by the number of values in the
instruction; until you add more instructions to the computer, this is
always 4 (1 opcode + 3 parameters) for the add and multiply
instructions. (The halt instruction would increase the instruction
pointer by 1, but it halts the program instead.)
"With terminology out of the way, we're ready to proceed. To complete
the gravity assist, you need to determine what pair of inputs produces
the output 19690720."
The inputs should still be provided to the program by replacing the
values at addresses 1 and 2, just like before. In this program, the
value placed in address 1 is called the noun, and the value placed
in address 2 is called the verb. Each of the two input values will
be between 0 and 99, inclusive.
Once the program has halted, its output is available at address 0,
also just like before. Each time you try a pair of inputs, make sure you
first reset the computer's memory to the values in the program (your
puzzle input) - in other words, don't reuse memory from a previous
attempt.
Find the input noun and verb that cause the program to produce the
output 19690720. What is 100 * noun + verb? (For example, if
noun=12 and verb=2, the answer would be 1202.)
Your puzzle answer was 6533.
Both parts of this puzzle are complete! They provide two gold stars: **