2022 Day 15 Complete!
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@ -5,7 +5,6 @@ import (
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"math"
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"os"
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"strings"
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"time"
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h "git.bullercodeworks.com/brian/adventofcode/helpers"
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)
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@ -79,122 +78,32 @@ func part1(inp []string) {
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fmt.Println(nopeCount)
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}
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type Sensor struct {
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c h.Coordinate // Sensor Position
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b h.Coordinate // Beacon Position
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d int // Distance
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}
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func (s Sensor) isInRange(c h.Coordinate) bool { return s.c.Distance(c) <= s.d }
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func (s Sensor) String() string { return s.c.String() }
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func part2(inp []string) {
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var sensors []Sensor
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var spots [][]int
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for i := range inp {
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s := Sensor{}
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s.c, s.b = strToCoords(inp[i])
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s.d = s.c.Distance(s.b)
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sensors = append(sensors, s)
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s, b := strToCoords(inp[i])
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xs, ys, xb, yb := s.X, s.Y, b.X, b.Y
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dist := s.Distance(b)
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spots = append(spots, []int{xs, ys, xb, yb, dist})
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}
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max := testRow * 2
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found := []h.Coordinate{}
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// Check around each sensor, the beacon must be it's distance + 1
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for _, sensor := range sensors {
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d := sensor.d + 1
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testEnds := []h.Coordinate{
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{X: sensor.c.X, Y: sensor.c.Y - d},
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{X: sensor.c.X + d, Y: sensor.c.Y},
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{X: sensor.c.X, Y: sensor.c.Y + d},
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{X: sensor.c.X - d, Y: sensor.c.Y},
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}
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printMap(sensors, max, max, h.Coordinate{X: math.MinInt, Y: math.MinInt})
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var tstX, tstY int
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for i := 0; i < 3; i++ {
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// Test all spots between testEnds[i] & testEnds[i+1]
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for tstX != testEnds[i+1].X && tstY != testEnds[i+1].Y {
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if testEnds[i].X < testEnds[i+1].X {
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tstX++
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if testEnds[i].Y < testEnds[i+1].Y {
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tstY++
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} else {
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tstY--
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}
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} else {
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tstX--
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if testEnds[i].Y < testEnds[i+1].Y {
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tstY++
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} else {
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tstY--
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min, max := 0, testRow*2
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// Brute-force it
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for y := min; y <= max; y++ {
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SEARCH:
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for x := min; x <= max; x++ {
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for _, c := range spots {
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if dx, dy := c[0]-x, c[1]-y; h.Abs(dx)+h.Abs(dy) <= c[4] {
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// Jump across the sensor's scan area
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x += c[4] - h.Abs(dy) + dx
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continue SEARCH
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}
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}
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}
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if tstX <= max && tstY <= max {
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fmt.Print(h.CLEAR_SCREEN)
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printMap(sensors, max, max, h.Coordinate{X: tstX, Y: tstY})
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fmt.Println("Testing", tstX, ",", tstY)
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time.Sleep(time.Second / 10)
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if testSpot(tstX, tstY, sensors) {
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found = append(found, h.Coordinate{X: tstX, Y: tstY})
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}
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}
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}
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}
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// If we get here, we found it.
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fmt.Println("# Part 2")
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fmt.Println(found)
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//fmt.Println((found.X * 4000000) + found.Y)
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}
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func testSpot(x, y int, sensors []Sensor) bool {
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var wasInRange bool
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for i := range sensors {
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if sensors[i].isInRange(h.Coordinate{X: x, Y: y}) {
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wasInRange = true
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break
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fmt.Println(x*4000000 + y)
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return
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}
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}
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return !wasInRange
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}
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func printMap(sensors []Sensor, ceilX, ceilY int, tstPos h.Coordinate) {
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minX, maxX, minY, maxY := math.MaxInt, math.MinInt, math.MaxInt, math.MinInt
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for i := range sensors {
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minX = h.Min(sensors[i].b.X, minX)
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maxX = h.Max(sensors[i].b.X, maxX)
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minY = h.Min(sensors[i].b.Y, minY)
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maxY = h.Max(sensors[i].b.Y, maxY)
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}
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for y := minY; y <= maxY; y++ {
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for x := minX; x <= maxX; x++ {
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wrk := h.Coordinate{X: x, Y: y}
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var found bool
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for _, sensor := range sensors {
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if sensor.c.Equals(wrk) {
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fmt.Print("S")
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found = true
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break
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} else if sensor.b.Equals(wrk) {
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fmt.Print("B")
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found = true
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break
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} else if sensor.isInRange(wrk) {
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fmt.Print("#")
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found = true
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break
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}
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}
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if !found {
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if wrk.Equals(tstPos) {
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fmt.Print(h.FILL_CHAR)
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} else {
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fmt.Print(".")
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}
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}
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}
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fmt.Println()
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}
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}
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func strToCoords(s string) (h.Coordinate, h.Coordinate) {
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@ -1,43 +1,29 @@
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Advent of Code
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• [About]
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• [Events]
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• [Shop]
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• [Settings]
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• [Log Out]
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br0xen (AoC++) 28*
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<y>2022</y>
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• [Calendar]
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• [AoC++]
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• [Sponsors]
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• [Leaderboard]
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• [Stats]
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Our sponsors help make Advent of Code possible:
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BJSS - Our people are a team of problem solvers, experienced in evolving technologies and delivering
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world-class technology solutions.
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Advent of Code
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br0xen (AoC++) 32*
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--- Day 15: Beacon Exclusion Zone ---
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You feel the ground rumble again as the distress signal leads you to a large network of subterranean tunnels.
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You don't have time to search them all, but you don't need to: your pack contains a set of deployable sensors
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You feel the ground rumble again as the distress signal leads you to a
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large network of subterranean tunnels. You don't have time to search them
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all, but you don't need to: your pack contains a set of deployable sensors
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that you imagine were originally built to locate lost Elves.
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The sensors aren't very powerful, but that's okay; your handheld device indicates that you're close enough to
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the source of the distress signal to use them. You pull the emergency sensor system out of your pack, hit the
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The sensors aren't very powerful, but that's okay; your handheld device
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indicates that you're close enough to the source of the distress signal to
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use them. You pull the emergency sensor system out of your pack, hit the
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big button on top, and the sensors zoom off down the tunnels.
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Once a sensor finds a spot it thinks will give it a good reading, it attaches itself to a hard surface and
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begins monitoring for the nearest signal source beacon. Sensors and beacons always exist at integer
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coordinates. Each sensor knows its own position and can determine the position of a beacon precisely; however,
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sensors can only lock on to the one beacon closest to the sensor as measured by the Manhattan distance. (There
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is never a tie where two beacons are the same distance to a sensor.)
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Once a sensor finds a spot it thinks will give it a good reading, it
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attaches itself to a hard surface and begins monitoring for the nearest
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signal source beacon. Sensors and beacons always exist at integer
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coordinates. Each sensor knows its own position and can determine the
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position of a beacon precisely; however, sensors can only lock on to the
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one beacon closest to the sensor as measured by the Manhattan distance.
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(There is never a tie where two beacons are the same distance to a
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sensor.)
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It doesn't take long for the sensors to report back their positions and closest beacons (your puzzle input).
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For example:
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It doesn't take long for the sensors to report back their positions and
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closest beacons (your puzzle input). For example:
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Sensor at x=2, y=18: closest beacon is at x=-2, y=15
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Sensor at x=9, y=16: closest beacon is at x=10, y=16
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@ -54,10 +40,11 @@
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Sensor at x=14, y=3: closest beacon is at x=15, y=3
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Sensor at x=20, y=1: closest beacon is at x=15, y=3
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So, consider the sensor at 2,18; the closest beacon to it is at -2,15. For the sensor at 9,16, the closest
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beacon to it is at 10,16.
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So, consider the sensor at 2,18; the closest beacon to it is at -2,15. For
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the sensor at 9,16, the closest beacon to it is at 10,16.
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Drawing sensors as S and beacons as B, the above arrangement of sensors and beacons looks like this:
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Drawing sensors as S and beacons as B, the above arrangement of sensors
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and beacons looks like this:
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1 1 2 2
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0 5 0 5 0 5
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@ -85,10 +72,11 @@
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21 ............................
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22 .......................B....
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This isn't necessarily a comprehensive map of all beacons in the area, though. Because each sensor only
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identifies its closest beacon, if a sensor detects a beacon, you know there are no other beacons that close or
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closer to that sensor. There could still be beacons that just happen to not be the closest beacon to any
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sensor. Consider the sensor at 8,7:
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This isn't necessarily a comprehensive map of all beacons in the area,
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though. Because each sensor only identifies its closest beacon, if a
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sensor detects a beacon, you know there are no other beacons that close or
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closer to that sensor. There could still be beacons that just happen to
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not be the closest beacon to any sensor. Consider the sensor at 8,7:
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1 1 2 2
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0 5 0 5 0 5
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@ -118,16 +106,18 @@
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21 ............................
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22 .......................B....
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This sensor's closest beacon is at 2,10, and so you know there are no beacons that close or closer (in any
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positions marked #).
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This sensor's closest beacon is at 2,10, and so you know there are no
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beacons that close or closer (in any positions marked #).
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None of the detected beacons seem to be producing the distress signal, so you'll need to work out where the
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distress beacon is by working out where it isn't. For now, keep things simple by counting the positions where a
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None of the detected beacons seem to be producing the distress signal, so
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you'll need to work out where the distress beacon is by working out where
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it isn't. For now, keep things simple by counting the positions where a
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beacon cannot possibly be along just a single row.
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So, suppose you have an arrangement of beacons and sensors like in the example above and, just in the row where
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y=10, you'd like to count the number of positions a beacon cannot possibly exist. The coverage from all sensors
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near that row looks like this:
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So, suppose you have an arrangement of beacons and sensors like in the
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example above and, just in the row where y=10, you'd like to count the
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number of positions a beacon cannot possibly exist. The coverage from all
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sensors near that row looks like this:
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1 1 2 2
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0 5 0 5 0 5
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@ -135,16 +125,36 @@
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10 ..####B######################..
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11 .###S#############.###########.
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In this example, in the row where y=10, there are 26 positions where a beacon cannot be present.
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In this example, in the row where y=10, there are 26 positions where a
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beacon cannot be present.
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Consult the report from the sensors you just deployed. In the row where y=2000000, how many positions cannot
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contain a beacon?
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Consult the report from the sensors you just deployed. In the row where
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y=2000000, how many positions cannot contain a beacon?
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To begin, get your puzzle input.
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Your puzzle answer was 4748135.
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Answer: _____________________ [ [Submit] ]
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--- Part Two ---
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You can also [Shareon Twitter Mastodon] this puzzle.
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Your handheld device indicates that the distress signal is coming from a
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beacon nearby. The distress beacon is not detected by any sensor, but the
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distress beacon must have x and y coordinates each no lower than 0 and no
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larger than 4000000.
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To isolate the distress beacon's signal, you need to determine its tuning
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frequency, which can be found by multiplying its x coordinate by 4000000
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and then adding its y coordinate.
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In the example above, the search space is smaller: instead, the x and y
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coordinates can each be at most 20. With this reduced search area, there
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is only a single position that could have a beacon: x=14, y=11. The tuning
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frequency for this distress beacon is 56000011.
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Find the only possible position for the distress beacon. What is its
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tuning frequency?
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Your puzzle answer was 13743542639657.
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Both parts of this puzzle are complete! They provide two gold stars: **
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References
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@ -152,7 +162,6 @@ References
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. https://adventofcode.com/
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. https://adventofcode.com/2022/about
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. https://adventofcode.com/2022/events
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. https://teespring.com/stores/advent-of-code
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. https://adventofcode.com/2022/settings
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. https://adventofcode.com/2022/auth/logout
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. Advent of Code Supporter
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@ -164,8 +173,6 @@ References
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. https://adventofcode.com/2022/leaderboard
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. https://adventofcode.com/2022/stats
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. https://adventofcode.com/2022/sponsors
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. https://www.bjss.com/
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. https://en.wikipedia.org/wiki/Taxicab_geometry
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. https://adventofcode.com/2022
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. https://adventofcode.com/2022/day/15/input
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. https://twitter.com/intent/tweet?text=%22Beacon+Exclusion+Zone%22+%2D+Day+15+%2D+Advent+of+Code+2022&url=https%3A%2F%2Fadventofcode%2Ecom%2F2022%2Fday%2F15&related=ericwastl&hashtags=AdventOfCode
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. javascript:void(0);
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