Datasets:

JetBrains

/

KStack-clean

like 2

src/Day08.kt

ZiomaleQ

{"Kotlin": 49609}

fun main() { fun part1(input: List<String>): Int { var sum = 0 val trees = input.map { line -> line.map { c -> Tree(c.digitToInt()) } } for ((rowIndex, rowOfTrees) in trees.withIndex()) { if (rowIndex == 0 || rowIndex == trees.size - 1) { sum += rowOfTrees.size continue } for ((treeIndex, tree) in rowOfTrees.withIndex()) { if (treeIndex == 0 || treeIndex == rowOfTrees.size - 1) { sum++ continue } val treesToLeft = rowOfTrees.subList(0, treeIndex) val treesToRight = rowOfTrees.subList(treeIndex + 1, rowOfTrees.size) val treesToTop = trees.subList(0, rowIndex).map { it[treeIndex] } val treesToBottom = trees.subList(rowIndex + 1, trees.size).map { it[treeIndex] } val isVisibleHorizontal = treesToLeft.all { it.height < tree.height } || treesToRight.all { it.height < tree.height } val isVisibleVertical = treesToTop.all { it.height < tree.height } || treesToBottom.all { it.height < tree.height } if (isVisibleVertical || isVisibleHorizontal) { sum++ } } } return sum } fun part2(input: List<String>): Int { val trees = input.map { line -> line.map { c -> Tree(c.digitToInt()) } }.also { setScore(it) } return trees.flatten().maxOf { it.score } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") part1(testInput).also { println(it); check(it == 21) } part2(testInput).also { println(it); check(it == 8) } val input = readInput("Day08") println(part1(input)) println(part2(input)) } data class Tree(val height: Int, var score: Int = 0) fun setScore(map: List<List<Tree>>) = map.forEachIndexed { y, row -> row.forEachIndexed { x, tree -> tree.score = scenicScore(map, x, y) } } fun scenicScore(map: List<List<Tree>>, x: Int, y: Int): Int { val currentHeight = map[y][x].height val directions = listOf( (x + 1..map[0].lastIndex).map { map[y][it].height }, (x - 1 downTo 0).map { map[y][it].height }, (y + 1..map.lastIndex).map { map[it][x].height }, (y - 1 downTo 0).map { map[it][x].height } ) return directions .map { dir -> (dir.indexOfFirst { it >= currentHeight } + 1) .takeIf { it != 0 } ?: dir.size } .reduce(Int::times) }

Kotlin

b8811a6a9c03e80224e4655013879ac8a90e69b5

aoc-2022

Apache License 2.0

src/Day08.kt

zirman

{"Kotlin": 89030}

fun main() { fun part1(input: List<String>): Int { val trees = input.map { row -> row.map { it.digitToInt() } } val visible = trees.map { it.indices.map { false }.toMutableList() } for (c in trees.first().indices) { var h = -1 for (r in trees.indices) { if (trees[r][c] > h) { visible[r][c] = true h = trees[r][c] } } } for (c in trees.first().indices) { var h = -1 for (r in trees.indices.reversed()) { if (trees[r][c] > h) { visible[r][c] = true h = trees[r][c] } } } for (r in trees.indices) { var h = -1 for (c in trees.first().indices) { if (trees[r][c] > h) { visible[r][c] = true h = trees[r][c] } } } for (r in trees.indices) { var h = -1 for (c in trees.first().indices.reversed()) { if (trees[r][c] > h) { visible[r][c] = true h = trees[r][c] } } } return visible.sumOf { row -> row.count { it } } } fun part2(input: List<String>): Int { val trees = input.map { row -> row.map { it.digitToInt() } } val scenicScore = trees.indices.map { r -> trees.first().indices.map { c -> val max = trees[r][c] tailrec fun searchNorth(r: Int, acc: Int): Int { return when { r < 0 -> acc trees[r][c] >= max -> acc + 1 else -> searchNorth(r - 1, acc + 1) } } tailrec fun searchSouth(r: Int, acc: Int): Int { return when { r >= trees.size -> acc trees[r][c] >= max -> acc + 1 else -> searchSouth(r + 1, acc + 1) } } tailrec fun searchEast(c: Int, acc: Int): Int { return when { c >= trees.size -> acc trees[r][c] >= max -> acc + 1 else -> searchEast(c + 1, acc + 1) } } tailrec fun searchWest(c: Int, acc: Int): Int { return when { c < 0 -> acc trees[r][c] >= max -> acc + 1 else -> searchWest(c - 1, acc + 1) } } searchNorth(r - 1, 0) * searchSouth(r + 1, 0) * searchEast(c + 1, 0) * searchWest(c - 1, 0) } } return scenicScore.maxOf { row -> row.maxOf { it } } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 21) val input = readInput("Day08") println(part1(input)) check(part2(testInput) == 8) println(part2(input)) }

Kotlin

2ec1c664f6d6c6e3da2641ff5769faa368fafa0f

aoc2022

Apache License 2.0

src/year2023/day23/Day23.kt

lukaslebo

{"Kotlin": 222221}

package year2023.day23 import check import readInput fun main() { val testInput = readInput("2023", "Day23_test") check(part1(testInput), 94) check(part2(testInput), 154) val input = readInput("2023", "Day23") println(part1(input)) println(part2(input)) } private fun part1(input: List<String>) = input.parseHikingMap().longestHike() private fun part2(input: List<String>) = input.parseHikingMap().removeSlopes().longestHike() private fun HikingMap.longestHike() = createGraph().longestHike(start, target) ?: error("no path found") private data class Pos(val x: Int, val y: Int) { fun neighbours() = listOf(Pos(x, y - 1), Pos(x, y + 1), Pos(x - 1, y), Pos(x + 1, y)) } private data class HikingMap( val trail: Set<Pos>, /** Positions of the slope with the position one has to go next */ val slopes: Map<Pos, Pos>, val start: Pos, val target: Pos, ) private fun List<String>.parseHikingMap(): HikingMap { val trail = mutableSetOf<Pos>() val slopes = mutableMapOf<Pos, Pos>() for ((y, line) in withIndex()) { for ((x, c) in line.withIndex()) { when (c) { '.' -> trail += Pos(x, y) 'v' -> slopes += Pos(x, y) to Pos(x, y + 1) '^' -> slopes += Pos(x, y) to Pos(x, y - 1) '>' -> slopes += Pos(x, y) to Pos(x + 1, y) '<' -> slopes += Pos(x, y) to Pos(x - 1, y) } } } return HikingMap( trail = trail, slopes = slopes, start = trail.single { it.y == 0 }, target = trail.single { it.y == lastIndex }, ) } private fun HikingMap.removeSlopes() = copy(trail = trail + slopes.keys, slopes = emptyMap()) private fun HikingMap.createGraph(): Map<Pos, Set<Pair<Pos, Int>>> { val nodes = trail.filter { trailPos -> trailPos.neighbours().count { it in trail || it in slopes } > 2 } + start + target val graph = nodes.associateWith { mutableSetOf<Pair<Pos, Int>>() } fun pathsWithDistance(pos: Pos, distance: Int = 0, visited: Set<Pos> = setOf(pos)): List<Pair<Pos, Int>> { if (pos in nodes && distance > 0) return listOf(pos to distance) return pos.neighbours() .filter { next -> (next in trail || (next in slopes && pos != slopes[next])) && next !in visited } .flatMap { next -> pathsWithDistance(pos = next, distance = distance + 1, visited = visited + next) } } for (node in nodes) { graph.getValue(node) += pathsWithDistance(node) } return graph } private fun Map<Pos, Set<Pair<Pos, Int>>>.longestHike(pos: Pos, target: Pos, visited: Set<Pos> = setOf(pos)): Int? { return if (pos == target) 0 else getValue(pos) .filter { it.first !in visited } .mapNotNull { (next, distance) -> val longestHike = longestHike(next, target, visited + next) ?: return@mapNotNull null distance + longestHike } .maxOrNull() }

Kotlin

f3cc3e935bfb49b6e121713dd558e11824b9465b

AdventOfCode

Apache License 2.0

src/Day13.kt

flex3r

{"Kotlin": 63192}

fun main() { val testInput = readInput("Day13_test") check(part1(testInput) == 13) check(part2(testInput) == 140) val input = readInput("Day13") println(part1(input)) println(part2(input)) } private fun part1(input: List<String>): Int { return input.partitionBy { it.isEmpty() } .asSequence() .map { (a, b) -> parse(a).compareTo(parse(b)) } .withIndex() .filter { (_, res) -> res == -1 } .sumOf { (idx, _) -> idx + 1 } } private fun part2(input: List<String>): Int { val firstDivider = PacketList(listOf(PacketList(listOf(PacketValue(2))))) val secondDivider = PacketList(listOf(PacketList(listOf(PacketValue(6))))) val sorted = input .asSequence() .filterNot { it.isEmpty() } .map { parse(it) } .plus(firstDivider) .plus(secondDivider) .sorted() .toList() return (sorted.indexOf(firstDivider) + 1) * (sorted.indexOf(secondDivider) + 1) } private fun parse(value: String): Packet { if (value.firstOrNull()?.isDigit() == true) return PacketValue(value.toInt()) return PacketList( packets = buildList { var openBrackets = 0 var lastComma = 0 value.forEachIndexed { idx, c -> when { c == '[' -> openBrackets++ c == ']' -> if (--openBrackets == 0) add(parse(value.substring(lastComma + 1 until idx))) c == ',' && openBrackets == 1 -> add(parse(value.substring(lastComma + 1 until idx))).also { lastComma = idx } } } } ) } private sealed class Packet : Comparable<Packet> { override fun compareTo(other: Packet) = when { this is PacketValue && other is PacketValue -> this.packet.compareTo(other.packet) else -> compareLists(this.asList(), other.asList()) } private fun compareLists(a: PacketList, b: PacketList): Int { a.packets.zip(b.packets).forEach { (a, b) -> val compared = a.compareTo(b) if (compared != 0) return compared } return a.packets.size.compareTo(b.packets.size) } private fun asList() = if (this is PacketList) this else PacketList(listOf(this)) } private data class PacketList(val packets: List<Packet>) : Packet() private data class PacketValue(val packet: Int) : Packet()

Kotlin

8604ce3c0c3b56e2e49df641d5bf1e498f445ff9

aoc-22

Apache License 2.0

src/year2021/day08/Day08.kt

fadi426

{"Kotlin": 44622}

package year2021.day01.day08 import util.assertTrue import util.read2021DayInput fun main() { fun task01(input: List<String>): Int { val formattedInput = input.map { it.substringAfter(" | ") }.map { it.split(" ") } return listOf(2, 4, 3, 7).let { uniqueSegments -> formattedInput.sumOf { it.count { uniqueSegments.contains(it.length) } } } } fun task02(input: List<String>): Int { var sum = 0 val formattedInput = input.map { it.split(" | ") }.map { it.map { it.split(" ") } } formattedInput.forEach { val segments = mutableListOf<Pair<String, Int>>() segments.addAll(byUniqueLength(it[0])) segments.addAll(byLengthSix(it[0], segments)) segments.addAll(byLengthFive(it[0], segments)) sum += decodeSignal(it[1], segments) } return sum } val input = read2021DayInput("Day08") assertTrue(task01(input) == 261) assertTrue(task02(input) == 987553) } fun decodeSignal(list: List<String>, segments: List<Pair<String, Int>>): Int { return list.map { segments.first { e -> it.alphabetized() == e.first.alphabetized() } }.map { it.second } .joinToString { it.toString() }.replace(", ", "").toInt() } fun byUniqueLength(list: List<String>): List<Pair<String, Int>> { val l = listOf(Pair(1, 2), Pair(4, 4), Pair(7, 3), Pair(8, 7)) return list.map { Pair(it, l.find { e -> e.second == it.length }) }.filter { it.second != null } .map { Pair(it.first, it.second!!.first) } } fun byLengthFive(list: List<String>, segments: List<Pair<String, Int>>): List<Pair<String, Int>> { val outcome = mutableListOf<Pair<String, Int>>() val fiveList = list.filter { it.length == 5 } val three = Pair(fiveList.first { containsDigitPattern(it, segments, 7) }, 3) val five = Pair(fiveList.first { segments.first { e -> e.second == 6 }.first.toList().containsAll(it.toList()) }, 5) val two = Pair(fiveList.first { it != three.first && it != five.first }, 2) outcome.addAll(listOf(three, five, two)) return outcome } fun byLengthSix(list: List<String>, segments: List<Pair<String, Int>>): List<Pair<String, Int>> { val outcome = mutableListOf<Pair<String, Int>>() val sixList = list.filter { it.length == 6 } val six = Pair(sixList.first { !containsDigitPattern(it, segments, 1) }, 6) val nine = Pair(sixList.first { containsDigitPattern(it, segments, 4) }, 9) val zero = Pair(sixList.first { it != six.first && it != nine.first }, 0) outcome.addAll(listOf(six, nine, zero)) return outcome } fun containsDigitPattern(a: String, list: List<Pair<String, Int>>, i: Int): Boolean { return a.toList().containsAll(list.first { it.second == i }.first.toList()) } fun String.alphabetized() = String(toCharArray().apply { sort() })

Kotlin

acf8b6db03edd5ff72ee8cbde0372113824833b6

advent-of-code-kotlin-template

Apache License 2.0

src/Day14.kt

laricchia

{"Kotlin": 38143}

fun firstPart14(list : List<Pair<String, String>>, start : String) { var newSeq = start val steps = 10 for (i in 0 until steps) { var windows = newSeq.windowed(2).map { StringBuilder(it) } list.map { insertion -> windows = windows.map { if (it.toString() == insertion.first) it.insert(1, insertion.second) else it } } newSeq = windows.joinToString(separator = "") { it.deleteCharAt(it.length - 1).toString() } + start.last() // println(newSeq) } val distinctLetters = newSeq.split("").filterNot { it.isEmpty() }.distinct() val counts = distinctLetters.map { letter -> newSeq.count { it == letter.first() } }.sortedDescending() println(counts.first() - counts.last()) } fun secondPart14(list : List<Pair<String, String>>, start : String) { val steps = 40 var state = mutableMapOf<String, Long>() val startWindows = start.windowed(2) startWindows.distinct().map { s -> state[s] = startWindows.count { s == it }.toLong() } list.filterNot { it.first in startWindows }.map { state[it.first] = 0 } // println(state) for (i in 0 until steps) { val updatedState = mutableMapOf<String, Long>() list.map { val elem1 = it.first.first() + it.second val elem2 = it.second + it.first.last() val value = state[it.first] ?: 0 updatedState[elem1] = (updatedState[elem1] ?: 0) + value updatedState[elem2] = (updatedState[elem2] ?: 0) + value } state = updatedState // println(state) } val distinctLetters = state.map { it.key }.map { it.split("").filterNot { it.isEmpty() }.map { it.first() } }.flatten().distinct() val counts = mutableMapOf<Char, Long>() distinctLetters.map { counts[it] = 0 } state.map { counts[it.key.first()] = counts[it.key.first()]!! + it.value counts[it.key.last()] = counts[it.key.last()]!! + it.value } //println(counts) val sortedCounts = counts.map { val updatedValue = it.value / 2 if (it.key == start.last()) (updatedValue + 1) else updatedValue }.sortedDescending() // println(sortedCounts) println(sortedCounts.first() - sortedCounts.last()) } fun main() { val input : List<String> = readInput("Day14") val start = input.first() val pairs = input.subList(2, input.size).map { val splits = it.split(" -> ") splits[0] to splits[1] } firstPart14(pairs, start) secondPart14(pairs, start) }

Kotlin

7041d15fafa7256628df5c52fea2a137bdc60727

Advent_of_Code_2021_Kotlin

Apache License 2.0

src/day24/d24_2.kt

svorcmar

{"Kotlin": 49110}

fun main() { val input = "" val list = input.lines().map { it.toInt() } val groupSize = list.sum() / 4 val firstGroup = solve(list, groupSize) // order by quantum entanglement and find smallest one for which // the rest of packages can be divided in three groups of the same weight val candidates = firstGroup.map { it.map(Int::toLong).reduce(Long::times) to it }.sortedBy { it.first } for (candidate in candidates) { if (canBeSplitIn3(list - candidate.second, groupSize)) { println(candidate.first) break } } } fun solve(packages: List<Int>, target: Int): List<List<Int>> { // dp[i][j] == set of the smallest subsets of the first i elements that sum to j val dp = Array(packages.size + 1) { Array(target + 1) { if (it == 0) 0 to listOf(emptyList<Int>()) else packages.size to emptyList<List<Int>>() } } packages.forEachIndexed { i0, n -> val i = i0 + 1 for (j in 1 .. target) { dp[i][j] = dp[i - 1][j] if (j >= n) { val prevRow = dp[i - 1][j - n] if (prevRow.first + 1 < dp[i][j].first) { dp[i][j] = prevRow.first + 1 to prevRow.second.map { it -> it + n } } else if (prevRow.first + 1 == dp[i][j].first) { dp[i][j] = dp[i][j].first to dp[i][j].second + prevRow.second.map { it -> it + n } } } } } return dp[packages.size][target].second } fun canBeSplitIn3(packages: List<Int>, target: Int): Boolean { // the order/size of the groups is not important; // the first element is forced the first group and the second element to the first or second group to fix the ordering return canBeSplitIn3Rec(packages, target, 2, packages[0] + packages[1], 0, 0) || canBeSplitIn3Rec(packages, target, 2, packages[0], packages[1], 0) } fun canBeSplitIn3Rec(packages: List<Int>, target: Int, nextIdx: Int, g1: Int, g2: Int, g3: Int): Boolean { if (nextIdx == packages.size) { return true } val next = packages[nextIdx] return (g1 < target && g1 + next <= target && canBeSplitIn3Rec(packages, target, nextIdx + 1, g1 + next, g2, g3)) || (g2 < target && g2 + next <= target && canBeSplitIn3Rec(packages, target, nextIdx + 1, g1, g2 + next, g3)) || (g3 < target && g3 + next <= target && canBeSplitIn3Rec(packages, target, nextIdx + 1, g1, g2, g3 + next)) }

Kotlin

cb097b59295b2ec76cc0845ee6674f1683c3c91f

aoc2015

MIT License

advent-of-code-2022/src/Day08.kt

osipxd

{"Kotlin": 141640, "Shell": 4083, "Scala": 693}

typealias Forest = List<List<Int>> fun main() { val testInput = readInput("Day08_test") val input = readInput("Day08") "Part 1" { part1(testInput) shouldBe 21 answer(part1(input)) } "Part 2" { part2(testInput) shouldBe 8 answer(part2(input)) } } private fun part1(forest: Forest): Int { val n = forest.size val m = forest[0].size /** Checks the tree at position [r],[c] is visible from the given [direction]. */ fun isVisibleFromOutside(r: Int, c: Int, direction: Direction): Boolean { val treeHeight = forest[r][c] return forest.treesByDirection(r, c, direction).all { it < treeHeight } } // All trees on edges are visible var count = (n + m - 2) * 2 for (r in 1 until n - 1) { for (c in 1 until m - 1) { if (Direction.values().any { isVisibleFromOutside(r, c, it) }) count++ } } return count } private fun part2(forest: Forest): Int { val n = forest.size val m = forest[0].size /** Counts trees visible from tree at position [r],[c] in the given [direction]. */ fun countVisibleTrees(r: Int, c: Int, direction: Direction): Int { val targetTree = forest[r][c] var count = 0 for (currentTree in forest.treesByDirection(r, c, direction)) { count++ if (currentTree >= targetTree) return count } return count } var maxScore = 0 // All trees on edges will have score 0, so skip it for (r in 1 until n - 1) { for (c in 1 until m - 1) { val score = Direction.values().map { countVisibleTrees(r, c, it) }.reduce(Int::times) maxScore = maxOf(maxScore, score) } } return maxScore } /** Generates sequence of trees heights for the given [direction] in order of distance from [r],[c]. */ private fun Forest.treesByDirection(r: Int, c: Int, direction: Direction): Sequence<Int> { return generateSequence(direction.next(r to c), direction::next) .takeWhile { (r, c) -> r in indices && c in first().indices } .map { (r, c) -> this[r][c] } } // dr, dc - delta row, delta column private enum class Direction(val dr: Int = 0, val dc: Int = 0) { UP(dr = -1), LEFT(dc = -1), DOWN(dr = +1), RIGHT(dc = +1); /** Returns the next coordinates on this direction. */ fun next(coordinates: Pair<Int, Int>): Pair<Int, Int> { val (r, c) = coordinates return (r + dr) to (c + dc) } } private fun readInput(name: String) = readLines(name).map { it.map(Char::digitToInt) }

Kotlin

6a67946122abb759fddf33dae408db662213a072

advent-of-code

Apache License 2.0

aoc21/day_08/main.kt

viktormalik

{"Rust": 227300, "Go": 86273, "OCaml": 82410, "Kotlin": 78968, "Makefile": 13967, "Roff": 9981, "Shell": 2796}

import java.io.File fun segmentsByLen(len: Int): Set<Char> = when (len) { 2 -> setOf('c', 'f') 3 -> setOf('a', 'c', 'f') 4 -> setOf('b', 'c', 'd', 'f') else -> ('a'..'g').toSet() } fun segmentToDigit(segment: Set<Char>): Char? = when (segment) { setOf('a', 'b', 'c', 'e', 'f', 'g') -> '0' setOf('c', 'f') -> '1' setOf('a', 'c', 'd', 'e', 'g') -> '2' setOf('a', 'c', 'd', 'f', 'g') -> '3' setOf('b', 'c', 'd', 'f') -> '4' setOf('a', 'b', 'd', 'f', 'g') -> '5' setOf('a', 'b', 'd', 'e', 'f', 'g') -> '6' setOf('a', 'c', 'f') -> '7' setOf('a', 'b', 'c', 'd', 'e', 'f', 'g') -> '8' setOf('a', 'b', 'c', 'd', 'f', 'g') -> '9' else -> null } fun MutableMap<Char, Set<Char>>.dropGroups(groups: Iterable<Set<Char>>) { for (group in groups) { for (c in filter { (_, map) -> map != group }.keys) merge(c, group, Set<Char>::minus) } } fun getOptions(digit: String, mapping: Map<Char, Set<Char>>): Set<Set<Char>> { if (digit.length == 1) return mapping.get(digit[0])!!.map { setOf(it) }.toSet() return getOptions(digit.substring(1), mapping) .flatMap { mapping.get(digit[0])!!.map { c -> setOf(c) + it } } .filter { it.size == digit.length } .toSet() } fun decode(entry: String): Int { val patterns = entry.split(" | ")[0] val mapping = ('a'..'g').map { it to ('a'..'g').toSet() }.toMap().toMutableMap() var size = mapping.map { (_, m) -> m.size }.sum() var prevSize = 0 while (size != prevSize) { prevSize = size for (pat in patterns.split(" ")) { for (i in 0 until pat.length) { mapping.merge(pat[i], segmentsByLen(pat.length), Set<Char>::intersect) } } mapping.dropGroups(mapping.filter { (_, m) -> m.size == 1 }.values) mapping.dropGroups( mapping.filter { (c1, m1) -> m1.size == 2 && mapping.any { (c2, m2) -> c1 != c2 && m1 == m2 } }.values ) size = mapping.map { (_, m) -> m.size }.sum() } return entry .split(" | ")[1] .split(" ") .map { getOptions(it, mapping).firstNotNullOf { segmentToDigit(it) } } .joinToString("") .toInt() } fun main() { val entries = File("input").readLines() val first = entries.map { e -> e.split(" | ")[1] .split(" ") .filter { d -> d.length == 2 || d.length == 3 || d.length == 4 || d.length == 7 } .count() }.sum() println("First: $first") val second = entries.map { decode(it) }.sum() println("Second: $second") }

Rust

f47ef85393d395710ce113708117fd33082bab30

advent-of-code

MIT License

src/main/kotlin/Day16.kt

todynskyi

{"Kotlin": 47697}

import kotlin.math.max fun main() { fun floydWarshall( shortestPaths: Map<String, MutableMap<String, Int>>, valves: Map<String, Valve> ): Map<String, Map<String, Int>> { for (k in shortestPaths.keys) { for (i in shortestPaths.keys) { for (j in shortestPaths.keys) { val ik = shortestPaths[i]?.get(k) ?: 9999 val kj = shortestPaths[k]?.get(j) ?: 9999 val ij = shortestPaths[i]?.get(j) ?: 9999 if (ik + kj < ij) { shortestPaths[i]?.set(j, ik + kj) } } } } shortestPaths.values.forEach { it.keys.map { key -> if (valves[key]?.flowRate == 0) key else "" } .forEach { toRemove -> if (toRemove != "") it.remove(toRemove) } } return shortestPaths } fun calculate(input: List<Valve>, totalTime: Int, optimal: Boolean): Int { var score = 0 val valves = input.associateBy { it.id } val shortestPaths = floydWarshall( input.associate { it.id to it.neighbors.associateWith { 1 }.toMutableMap() }.toMutableMap(), valves ) fun calculate(currScore: Int, currentValve: String, visited: Set<String>, time: Int, optimal: Boolean) { score = max(score, currScore) for ((valve, dist) in shortestPaths[currentValve]!!) { if (!visited.contains(valve) && time + dist + 1 < totalTime) { calculate( currScore + (totalTime - time - dist - 1) * valves[valve]?.flowRate!!, valve, visited.union(listOf(valve)), time + dist + 1, optimal ) } } if (optimal) { calculate(currScore, "AA", visited, 0, false) } } calculate(0, "AA", emptySet(), 0, optimal) return score } fun part1(input: List<Valve>): Int = calculate(input, PART1_TIME, false) fun part2(input: List<Valve>): Int = calculate(input, PART2_TIME, true) // test if implementation meets criteria from the description, like: val testInput = readInput("Day16_test").toValves() check(part1(testInput) == 1651) println(part2(testInput)) val input = readInput("Day16").toValves() println(part1(input)) println(part2(input)) } const val PART1_TIME = 30 const val PART2_TIME = 26 fun List<String>.toValves(): List<Valve> = this.map { val (left, right) = it.split("; ") val (id, flowRate) = left.split(" has flow rate=") Valve( id.substringAfter("Valve "), flowRate.toInt(), right.replace("tunnels lead to valves ", "") .replace("tunnel leads to valve ", "") .split(", ").map { valve -> valve.trim() } ) } data class Valve(val id: String, val flowRate: Int, val neighbors: List<String>)

Kotlin

5f9d9037544e0ac4d5f900f57458cc4155488f2a

KotlinAdventOfCode2022

Apache License 2.0

src/com/kingsleyadio/adventofcode/y2021/day22/Solution.kt

kingsleyadio

{"Kotlin": 134666, "JavaScript": 5423}

package com.kingsleyadio.adventofcode.y2021.day22 import com.kingsleyadio.adventofcode.util.readInput fun part1(commands: List<Command>): Int { val bound = -50..50 val ons = hashSetOf<P3>() for ((action, cuboid) in commands) { if (cuboid.x !in bound || cuboid.y !in bound || cuboid.z !in bound) continue when (action) { Action.ON -> cuboid.cubes().forEach { ons.add(it) } Action.OFF -> cuboid.cubes().forEach { ons.remove(it) } } } return ons.size } fun part2(commands: List<Command>): Long { val bound = -50..50 val within = commands.filter { (_, cuboid) -> cuboid.x in bound && cuboid.y in bound && cuboid.z in bound } return within.foldIndexed(0L) { index, acc, (action, cuboid) -> println(acc) val intersects = commands.subList(0, index).map { cuboid.intersect(it.second) } val currentVolume = if (action == Action.ON) cuboid.volume() else 0 acc - sum(intersects) + currentVolume } } fun sum(cuboids: List<Cuboid>): Long { return when (cuboids.size) { 0 -> 0L 1 -> cuboids[0].volume() else -> { val last = cuboids.last() val intersects = cuboids.subList(0, cuboids.lastIndex).map { it.intersect(last) }.filterNot { it.isNone() } sum(cuboids.subList(0, cuboids.lastIndex)) - sum(intersects) + last.volume() } } } fun main() { val commands = readInput(2021, 22).useLines { lines -> lines.map(::parse).toList() } println(part1(commands)) println(part2(commands)) } fun parse(line: String): Command { val (c, rest) = line.split(" ") val (x, y, z) = rest.split(",").map { ch -> ch.substringAfter("=").split("..").map { it.toInt() } } val action = if (c == "on") Action.ON else Action.OFF val cuboid = Cuboid(x[0]..x[1], y[0]..y[1], z[0]..z[1]) return Command(action, cuboid) } typealias P3 = List<Int> typealias Command = Pair<Action, Cuboid> enum class Action { ON, OFF } data class Cuboid(val x: IntRange, val y: IntRange, val z: IntRange) fun Cuboid.cubes() = sequence { for (xx in x) for (yy in y) for (zz in z) yield(listOf(xx, yy, zz)) } fun Cuboid.volume(): Long = x.size.toLong() * y.size * z.size fun Cuboid.isNone() = x == IntRange.EMPTY && y == IntRange.EMPTY && z == IntRange.EMPTY fun Cuboid.intersect(other: Cuboid) = Cuboid(x.intersect(other.x), y.intersect(other.y), z.intersect(other.z)) operator fun IntRange.contains(range: IntRange) = range.first in this && range.last in this val IntRange.size: Int get() = last - first + 1 fun IntRange.intersect(other: IntRange): IntRange { return if (this in other) this else if (other in this) other else if (last < other.first) IntRange.EMPTY else if (first > other.first) first..other.last else other.first..last }

Kotlin

9abda490a7b4e3d9e6113a0d99d4695fcfb36422

adventofcode

Apache License 2.0

src/main/kotlin/Day12.kt

Ostkontentitan

{"Kotlin": 73563}

fun puzzleDayTwelvePartOne() { val inputs = readInput(12) val connections = inputsToConnections(inputs) val pathes = findUniquePaths(Cave.Start, connections, mapOf(Cave.Start to 1)) println("Number of pathes $pathes") } fun puzzleDayTwelvePartTwo() { val inputs = readInput(12) val connections = inputsToConnections(inputs) val pathes = findUniquePaths(Cave.Start, connections, mapOf(Cave.Start to 1), true) println("Number of pathes with 'golden ticket' $pathes") } fun inputsToConnections(inputs: List<String>): List<Connection> = inputs.map { val split = it.split("-") Connection(Cave(split[0]), Cave(split[1])) } fun findUniquePaths(from: Cave, connections: List<Connection>, visited: Map<Cave, Int>): Int { if (from == Cave.End) { return 1 } val connectionsToElement = connections.filter { it.contains(from) }.filterVisitable(from, visited) val nextOnes = connectionsToElement.map { it.getOther(from) } val updatedVisits = visited.incrementedForItem(from) return nextOnes.sumOf { findUniquePaths(it, connections, updatedVisits) } } fun findUniquePaths( from: Cave, connections: List<Connection>, visited: Map<Cave, Int>, goldenTicketAvailable: Boolean ): Int { if (from == Cave.End) { return 1 } val connectionsToElement = connections.filter { it.contains(from) }.filterVisitable(from, visited) val ticketConnections = if (goldenTicketAvailable) connections.filter { it.contains(from) } - connectionsToElement.toSet() else emptyList() val nextOnes = connectionsToElement.map { it.getOther(from) }.filterNot { it == Cave.Start } val nextOnesWithTicket = ticketConnections.map { it.getOther(from) }.filterNot { it.isBig || it == Cave.Start } val updatedVisits = visited.incrementedForItem(from) return nextOnes.sumOf { findUniquePaths(it, connections, updatedVisits, goldenTicketAvailable) } + nextOnesWithTicket.sumOf { findUniquePaths(it, connections, updatedVisits, false) } } fun List<Connection>.filterVisitable(cave: Cave, visited: Map<Cave, Int>) = this.filter { it.getOther(cave).isVisitable(visited) } fun Cave.isVisitable(visited: Map<Cave, Int>) = (visited[this] ?: 0) < this.maxVisits fun Map<Cave, Int>.incrementedForItem(item: Cave): Map<Cave, Int> = this + (item to (this[item] ?: 0) + 1) data class Cave(val key: String) { val isSmall = key == key.lowercase() val isBig = !isSmall val maxVisits = if (isSmall) 1 else Int.MAX_VALUE companion object { val Start = Cave("start") val End = Cave("end") } } data class Connection(private val one: Cave, private val two: Cave) { fun contains(cave: Cave) = one == cave || two == cave fun getOther(cave: Cave) = if (cave == one) two else if (cave == two) one else throw IllegalArgumentException("Other call with non contained element. ") }

Kotlin

e0e5022238747e4b934cac0f6235b92831ca8ac7

advent-of-kotlin-2021

Apache License 2.0

src/Day13.kt

bigtlb

{"Kotlin": 38940}

fun main() { class AdventList : Comparable<AdventList> { fun terms(input: String): List<String> { var parenLevel = 0 var start = 0 var next = 0 val termList = mutableListOf<String>() while (next <= input.length) { when { next == input.length || (parenLevel == 0 && ",]".contains(input[next])) -> { termList.add(input.substring(start until next)) start = next + 1 } parenLevel > 0 && input[next] == ']' -> parenLevel-- input[next] == '[' -> parenLevel++ else -> Unit } next++ } return termList } constructor(input: String) { list.addAll(terms(input.slice(1 until input.lastIndex)).map { it.trim() } .map { when { it.startsWith('[') -> Pair(null, AdventList(it)) else -> Pair(it.toIntOrNull(), null) } }) } var list = mutableListOf<Pair<Int?, AdventList?>>() fun Pair<Int?, AdventList?>.compareTo(other: Pair<Int?, AdventList?>) = when { this == other -> 0 first != null && other.first != null -> first!!.compareTo(other.first!!) first != null && other.second != null -> AdventList("[$first]").compareTo(other.second!!) second != null && other.first != null -> second!!.compareTo(AdventList("[${other.first}]")) second != null && other.second != null -> second!!.compareTo(other.second!!) first == null && second == null && (other.first != null || other.second != null) -> -1 else -> { 1 } } override fun compareTo(other: AdventList): Int { val result = this.list.zip(other.list).fold(0) { acc, (one, two) -> if (acc != 0) acc else one.compareTo(two) } return if (result == 0) listCount.compareTo(other.listCount) else result } val listCount: Int get() = list.sumOf { if (it.first != null) 1 else (it.second?.listCount ?: 0) + 1 } } fun part1(input: List<String>): Int = input.chunked(3).map { (first, second) -> AdventList(first).compareTo(AdventList(second)) <= 0 }.mapIndexed { idx, cur -> if (cur) idx + 1 else 0 }.sum() fun part2(input: List<String>): Int { val dividers = listOf(AdventList("[[2]]"), AdventList("[[6]]")) return input.filterNot { it.isNullOrBlank() }.map { AdventList(it) }.union(dividers).sorted() .mapIndexedNotNull { idx, node -> if (dividers.contains(node)) idx + 1 else null } .fold(1) { acc, idx -> acc * idx } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day13_test") check(part1(testInput) == 13) check(part2(testInput) == 140) println("checked") val input = readInput("Day13") println(part1(input)) println(part2(input)) }

Kotlin

d8f76d3c75a30ae00c563c997ed2fb54827ea94a

aoc-2022-demo

Apache License 2.0

y2023/src/main/kotlin/adventofcode/y2023/Day25.kt

Ruud-Wiegers

{"Kotlin": 503769}

package adventofcode.y2023 import adventofcode.io.AdventSolution fun main() { Day25.solve() } object Day25 : AdventSolution(2023, 25, "Snowverload") { override fun solvePartOne(input: String): Any { val weightedGraph: WeightedGraph = parse(input) .mapValues { Desc(1, it.value.associateWith { 1 }.toMutableMap()) } .entries.sortedBy { it.key }.map { it.value }.toTypedArray() repeat(weightedGraph.size - 2) { val (s, t) = weightedGraph.findMinCut() val cut = weightedGraph[t].edgeWeights.values.sum() if (cut == 3) { val wt = weightedGraph[t].vertexCount return (weightedGraph.sumOf { it.vertexCount } - wt) * wt } weightedGraph.merge(s, t) } error("No solution") } override fun solvePartTwo(input: String) = "Free!" } private fun parse(input: String): Map<Int, List<Int>> { val graph = input.lines().flatMap { val (s, es) = it.split(": ") es.split(" ").flatMap { e -> listOf(s to e, e to s) } }.groupBy({ it.first }, { it.second }) val keys = graph.keys.withIndex().associate { it.value to it.index } return graph.mapKeys { keys.getValue(it.key) }.mapValues { it.value.map { keys.getValue(it) } } } private data class Desc(var vertexCount: Int, val edgeWeights: MutableMap<Int, Int>) private typealias WeightedGraph = Array<Desc> private fun WeightedGraph.findMinCut(): List<Int> { val last = indexOfLast { it.vertexCount > 0 } val a = BooleanArray(last + 1) a[0] = true val weightsFromA = IntArray(last + 1) this.first().edgeWeights.forEach { weightsFromA[it.key] += it.value } repeat(a.size - 3) { val x = weightsFromA.max() val next = weightsFromA.indexOf(x) a[next] = true weightsFromA[next] = 0 this[next].edgeWeights.forEach { if (!a[it.key]) weightsFromA[it.key] += it.value } } val c1 = weightsFromA.indexOfFirst { it > 0 } val c2 = weightsFromA.indexOfLast { it > 0 } return listOf(c1, c2).sortedByDescending { weightsFromA[it] } } //merge s and t, move the empty t to the end of the array private fun WeightedGraph.merge(s: Int, t: Int) { val tDesc = get(t) val stDesc = get(s) tDesc.edgeWeights.forEach { (k, v) -> stDesc.edgeWeights.merge(k, v, Int::plus) } stDesc.edgeWeights -= s stDesc.edgeWeights -= t stDesc.vertexCount += tDesc.vertexCount val swap = maxOf(t, indexOfLast { it.vertexCount > 0 }) for ((_, w) in this) { w.remove(t)?.let { w.merge(s, it, Int::plus) } w.remove(swap)?.let { w[t] = it } } this[t] = this[swap] this[swap] = Desc(0, mutableMapOf()) }

Kotlin

fc35e6d5feeabdc18c86aba428abcf23d880c450

advent-of-code

MIT License

src/Day05/Day05.kt

martin3398

{"Kotlin": 63436, "Python": 5921}

import kotlin.math.min import kotlin.math.max fun main() { fun prepare(input: List<String>): List<Pair<Pair<Int, Int>, Pair<Int, Int>>> { return input.map { val split = it.split("->").map { x -> x.split(',').map { e -> e.trim() } } Pair(Pair(split[0][0].toInt(), split[0][1].toInt()), Pair(split[1][0].toInt(), split[1][1].toInt())) } } fun part1(input: List<Pair<Pair<Int, Int>, Pair<Int, Int>>>): Int { val inputWc = input.filter { it.first.first == it.second.first || it.first.second == it.second.second } val maxVal = input.maxOf { max(max(it.first.first, it.first.second), max(it.second.first, it.second.second)) } + 1 val array = MutableList(maxVal) { MutableList(maxVal) { 0 } } for (e in inputWc) { array.subList(min(e.first.first, e.second.first), max(e.first.first, e.second.first) + 1) .map { it.subList(min(e.first.second, e.second.second), max(e.first.second, e.second.second) + 1) } .forEach { it.forEachIndexed { index2, i -> it[index2] = i + 1 } } } return array.sumOf { x -> x.count { it > 1 } } } fun part2(input: List<Pair<Pair<Int, Int>, Pair<Int, Int>>>): Int { val maxVal = input.maxOf { max(max(it.first.first, it.first.second), max(it.second.first, it.second.second)) } + 1 val array = MutableList(maxVal) { MutableList(maxVal) { 0 } } for (e in input) { if (e.first.first == e.second.first || e.first.second == e.second.second) { array.subList(min(e.first.first, e.second.first), max(e.first.first, e.second.first) + 1) .map { it.subList(min(e.first.second, e.second.second), max(e.first.second, e.second.second) + 1) } .forEach { it.forEachIndexed { index2, i -> it[index2] = i + 1 } } } else { val length = e.first.first - e.second.first val range = if (length > 0) 0..length else 0..-length for (i in range) { array[e.first.first + if (e.first.first > e.second.first) -i else i][e.first.second + if (e.first.second > e.second.second) -i else i]++ } } } return array.sumOf { x -> x.count { it > 1 } } } val testInput = prepare(readInput(5, true)) val input = prepare(readInput(5)) check(part1(testInput) == 5) println(part1(input)) check(part2(testInput) == 12) println(part2(input)) }

Kotlin

085b1f2995e13233ade9cbde9cd506cafe64e1b5

advent-of-code-2021

Apache License 2.0

src/main/kotlin/day18/Day18.kt

Avataw

{"Kotlin": 99761}

package day18 fun solveA(input: List<String>): Int { val cubes = input.map(String::toCube).toSet() return cubes.size * 6 - cubes.sumOf { it.touches(cubes) } } fun solveB(input: List<String>): Int { val cubes = input.map(String::toCube).toSet() val min = minOf(cubes.minOf { it.x }, cubes.minOf { it.y }, cubes.minOf { it.z }) - 1 val max = maxOf(cubes.maxOf { it.x }, cubes.maxOf { it.y }, cubes.maxOf { it.z }) + 1 val fillers = mutableListOf(Cube(min, min, min)) fillers.first().fill(cubes, fillers, min..max) return fillers.sumOf { it.touches(cubes) } } fun String.toCube(): Cube { val (x, y, z) = this.split(",").map(String::toInt) return Cube(x, y, z) } data class Cube(val x: Int, val y: Int, val z: Int) { fun touches(cubes: Set<Cube>) = listOfNotNull( cubes.find { it.x == x - 1 && it.y == y && it.z == z }, cubes.find { it.x == x + 1 && it.y == y && it.z == z }, cubes.find { it.y == y - 1 && it.x == x && it.z == z }, cubes.find { it.y == y + 1 && it.x == x && it.z == z }, cubes.find { it.z == z - 1 && it.y == y && it.x == x }, cubes.find { it.z == z + 1 && it.y == y && it.x == x } ).count() fun fill(cubes: Set<Cube>, fillers: MutableList<Cube>, bounds: IntRange) { val adjacentCubes = this.calcAdjacent().filter { !fillers.contains(it) && cubes.none { cube -> it.x == cube.x && it.y == cube.y && it.z == cube.z } && it.x in bounds && it.y in bounds && it.z in bounds } fillers.addAll(adjacentCubes) adjacentCubes.forEach { it.fill(cubes, fillers, bounds) } } private fun calcAdjacent(): List<Cube> = listOf( Cube(x + 1, y, z), Cube(x - 1, y, z), Cube(x, y + 1, z), Cube(x, y - 1, z), Cube(x, y, z + 1), Cube(x, y, z - 1), ) }

Kotlin

769c4bf06ee5b9ad3220e92067d617f07519d2b7

advent-of-code-2022

Apache License 2.0

src/Day08.kt

SebastianHelzer

{"Kotlin": 27111}

fun main() { fun getTreeMap(input: List<String>): Map<Pair<Int, Int>, Int> { val heights = input.map { line -> line.toCharArray().map { it.digitToInt() } } return heights.flatMapIndexed { row, line -> line.mapIndexed { col, value -> (col to row) to value } }.toMap() } fun part1(input: List<String>): Int { val rows = input.size val cols = input.first().length val treeMap: Map<Pair<Int, Int>, Int> = getTreeMap(input) return treeMap.size - treeMap.count { entry -> val (x, y) = entry.key val height = entry.value val upIndices = 0 until y val leftIndices = 0 until x val rightIndices = (x + 1) until cols val downIndices = (y + 1) until rows upIndices.any { (treeMap[x to it] ?: 0) >= height } && leftIndices.any { (treeMap[it to y] ?: 0) >= height } && rightIndices.any { (treeMap[it to y] ?: 0) >= height } && downIndices.any { (treeMap[x to it] ?: 0) >= height } } } fun part2(input: List<String>): Int { val rows = input.size val cols = input.first().length val treeMap: Map<Pair<Int, Int>, Int> = getTreeMap(input) return treeMap.maxOf { entry -> val (x, y) = entry.key val height = entry.value val upIndices = 0 until y val leftIndices = 0 until x val rightIndices = (x + 1) until cols val downIndices = (y + 1) until rows val up = upIndices.indexOfLast { (treeMap[x to it] ?: 0) >= height }.let { if (it == -1) { y } else { y - it } } val left = leftIndices.indexOfLast { (treeMap[it to y] ?: 0) >= height }.let { if (it == -1) { x } else { x - it } } val right = rightIndices.indexOfFirst { (treeMap[it to y] ?: 0) >= height }.let { if(it == -1) { (cols - 1) - x } else {it + 1} } val down = downIndices.indexOfFirst { (treeMap[x to it] ?: 0) >= height }.let { if(it == -1) { (rows - 1) - y } else {it + 1}} up * left * right * down } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") checkEquals(21, part1(testInput)) checkEquals(8, part2(testInput)) val input = readInput("Day08") println(part1(input)) println(part2(input)) }

Kotlin

e48757626eb2fb5286fa1c59960acd4582432700

advent-of-code-2022

Apache License 2.0

src/Day12.kt

hrach

{"Kotlin": 32838}

fun main() { data class Map( val levels: List<List<Int>>, val start: Pair<Int, Int>, val end: Pair<Int, Int>, ) { fun getSteps(current: Pair<Int, Int>): List<Pair<Int, Int>> { return listOf( current.first - 1 to current.second, current.first to current.second - 1, current.first to current.second + 1, current.first + 1 to current.second, ).mapNotNull { val level = levels.getOrNull(it.first)?.getOrNull(it.second) ?: return@mapNotNull null if ((level - levels[current.first][current.second]) <= 1) { it } else { null } } } } fun parse(input: List<String>): Map { var start: Pair<Int, Int>? = null var end: Pair<Int, Int>? = null val levels = input.mapIndexed { y, line -> line.mapIndexed { x, c -> when (c) { 'S' -> { start = y to x 'a'.code } 'E' -> { end = y to x 'z'.code } else -> c.code } } } return Map(levels, start!!, end!!) } fun shortest(map: Map): Int { var todo = listOf(map.start to 0) val visited = mutableSetOf(map.start) while (todo.isNotEmpty()) { val (pos, price) = todo.first() val steps = map.getSteps(pos).filter { it !in visited } for (step in steps) { visited += step if (step == map.end) return price + 1 } todo = (todo.drop(1) + steps.map { it to price + 1 }).sortedBy { it.second } } return Int.MAX_VALUE } fun part1(input: List<String>): Int { val map = parse(input) return shortest(map) } fun part2(input: List<String>): Int { val map = parse(input) val lengths = mutableListOf<Int>() map.levels.forEachIndexed { y, row -> row.forEachIndexed q@{ x, c -> if (c != 'a'.code) return@q val newMap = map.copy(start = y to x) lengths.add(shortest(newMap)) } } return lengths.min() } val testInput = readInput("Day12_test") check(part1(testInput), 31) check(part2(testInput), 29) val input = readInput("Day12") println(part1(input)) println(part2(input)) }

Kotlin

40b341a527060c23ff44ebfe9a7e5443f76eadf3

aoc-2022

Apache License 2.0

src/day-14/Day14.kt

skbkontur

fun main() { fun parseInput(input: List<String>): Pair<String, Map<String, String>> { val source = input.first() val replacements = input .filter { it.contains("->") } .map { it.split(" -> ") } .associate { (a, b) -> a to b } return Pair(source, replacements) } fun part1(input: List<String>, iterations: Int): Int { val (source, replacements) = parseInput(input) val freqs = (0 until iterations) .fold(source) { it, _ -> it .windowed(2, partialWindows = true) { if (it.length == 2) "${it[0]}${replacements[it.toString()]}" else it } .joinToString("") } .groupingBy { it } .eachCount() .values val max = freqs.maxOf { it } val min = freqs.minOf { it } return max - min } fun countPairs(source: String): Map<String, Long> { return source .windowed(2) { it.toString() } .groupingBy { it } .eachCount() .mapValues { it.value.toLong() } } fun part2(input: List<String>, iterations: Int): Long { val (source, replacements) = parseInput(input) val freqs = (0 until iterations) .fold(countPairs(source)) { map, _ -> map .flatMap { (symbolPair, count) -> val newChar = replacements[symbolPair]!! val fst = symbolPair[0] + newChar val snd = newChar + symbolPair[1] listOf(fst to count, snd to count) } .groupBy { it.first } .mapValues { (_, counts) -> counts.sumOf { it.second } } } .flatMap { (pair, count) -> pair.map { it to count } } .groupBy { (char, _) -> char } .mapValues { (_, listCounts) -> listCounts.sumOf { (_, count) -> count } } .mapValues { (char, count) -> if (char == source.first() || char == source.last()) (count + 1) / 2 else count / 2 } .values val max = freqs.maxOf { it } val min = freqs.minOf { it } return max - min } // test if implementation meets criteria from the description, like: val testInput = readInput("Day14_test") check(part1(testInput, 10) == 1588) println(part1(testInput, 10)) println(part2(testInput, 10)) val input = readInput("Day14") println(part1(input, 10)) println(part2(input, 10)) println(part2(input, 40)) }

1C Enterprise

e5a791492f8c466404eb300708ec09b441872865

AoC2021

MIT License

src/Day08.kt

bin-wang

{"Kotlin": 19395}

import kotlin.math.min object Day08 { data class Tree(val x: Int, val y: Int) class Forest(private val heights: List<List<Int>>) { private val h = heights.size private val w = heights.first().size private fun leftward(tree: Tree) = ((tree.y - 1) downTo 0).map { Tree(tree.x, it) } private fun rightward(tree: Tree) = ((tree.y + 1) until w).map { Tree(tree.x, it) } private fun upward(tree: Tree) = ((tree.x - 1) downTo 0).map { Tree(it, tree.y) } private fun downward(tree: Tree) = ((tree.x + 1) until h).map { Tree(it, tree.y) } fun trees(): List<Tree> = (0 until h).cartesianProduct(0 until w).map { Tree(it.first, it.second) } fun visible(tree: Tree): Boolean { fun Tree.visibleInDirection(direction: (Tree) -> List<Tree>): Boolean { val myHeight = heights[x][y] return direction(this).map { heights[it.x][it.y] }.all { it < myHeight } } return tree.visibleInDirection(::leftward) || tree.visibleInDirection(::rightward) || tree.visibleInDirection(::upward) || tree.visibleInDirection(::downward) } fun score(tree: Tree): Int { fun Tree.scoreInDirection(direction: (Tree) -> List<Tree>): Int { val myHeight = heights[x][y] val otherTrees = direction(this) return min(otherTrees.takeWhile { heights[it.x][it.y] < myHeight }.size + 1, otherTrees.size) } return tree.scoreInDirection(::leftward) * tree.scoreInDirection(::rightward) * tree.scoreInDirection(::upward) * tree.scoreInDirection(::downward) } } } fun main() { fun part1(forest: Day08.Forest): Int { return forest.trees().count { forest.visible(it) } } fun part2(forest: Day08.Forest): Int { return forest.trees().maxOf { forest.score(it) } } val testInput = readInput("Day08_test") val testHeights = testInput.map { line -> line.map { it.digitToInt() } } val testForest = Day08.Forest(testHeights) check(part1(testForest) == 21) check(part2(testForest) == 8) val input = readInput("Day08") val heights = input.map { line -> line.map { it.digitToInt() } } val forest = Day08.Forest(heights) println(part1(forest)) println(part2(forest)) }

Kotlin

dca2c4915594a4b4ca2791843b53b71fd068fe28

aoc22-kt

Apache License 2.0

src/day15/Day15.kt

bartoszm

{"Kotlin": 39186}

package day15 import readInput import kotlin.math.absoluteValue typealias Point = Pair<Long, Long> fun main() { println(solve1(parse(readInput("day15/test")), 10)) println(solve1(parse(readInput("day15/input")), 2000000)) println(solve2(parse(readInput("day15/test")), 20)) println(solve2(parse(readInput("day15/input")), 4000000)) } fun taxi(a: Point, b: Point) = (a.first - b.first).absoluteValue + (a.second - b.second).absoluteValue class Sensor(val loc: Point, beac: Point) { val distance = taxi(loc, beac) fun canSense(p: Point) = taxi(loc, p) > distance fun coverageIn(row: Long): LongRange { val rem = distance - (loc.second - row).absoluteValue return if (rem < 0L) LongRange.EMPTY else loc.first - rem..loc.first + rem } } fun toDist(p: Pair<Point, Point>, c: (Long, Long) -> Long) = c(p.first.first, taxi(p.first, p.second)) fun minOf(values: List<Pair<Point, Point>>): Long { return values.minOf { toDist(it) { a, b -> a - b } } } fun maxOf(values: List<Pair<Point, Point>>): Long { return values.maxOf { toDist(it) { a, b -> a + b } } } fun solve1(data: List<Pair<Point, Point>>, row: Long): Int { val sensors = data.map { Sensor(it.first, it.second) } val start = minOf(data) val stop = maxOf(data) fun beaconsAt(row: Long) = data.map { it.second }.distinct() .filter { it.second == row } .count { it.first in start..stop } fun impossible(p: Point) = sensors.any { !it.canSense(p) } return (start..stop).map { it to row } .count { impossible(it) } - beaconsAt(row) } fun combine(ranges: List<LongRange>): List<LongRange> { fun sum(a: LongRange, b: LongRange): List<LongRange> { if (a.last < b.first) return listOf(a, b) return listOf(if (a.last >= b.last) a else a.first..b.last) } val r = ranges.sortedBy { it.first } return r.fold(listOf(r.first())) { acc, v -> acc.dropLast(1) + sum(acc.last(), v) } } fun toValues(a: LongRange, b: LongRange) = (a.last + 1 until b.first).toList() fun toValues(ranges: List<LongRange>) = ranges.windowed(2).flatMap { (a, b) -> toValues(a, b) } fun solve2(data: List<Pair<Point, Point>>, max: Int): Long { val sensors = data.map { Sensor(it.first, it.second) } val point = (0..max.toLong()).asSequence().flatMap { row -> val coverage = combine(sensors.map { it.coverageIn(row) }) toValues(coverage).map { v -> v to row } }.first() return point.first * 4000000 + point.second } //Sensor at x=20, y=1: closest beacon is at x=15, y=3 val cRegex = """x=([\d-]+), y=([\d-]+)""".toRegex() fun parse(input: List<String>): List<Pair<Point, Point>> { return input.map { val res = cRegex.find(it)!! val (sx, sy) = res.destructured val (bx, by) = res.next()!!.destructured val s = sx.toLong() to sy.toLong() val b = bx.toLong() to by.toLong() s to b } }

Kotlin

f1ac6838de23beb71a5636976d6c157a5be344ac

aoc-2022

Apache License 2.0

src/Day08.kt

cypressious

{"Kotlin": 40281}

fun main() { val easyDigits = mapOf( 2 to 1, 4 to 4, 3 to 7, 7 to 8, ) fun part1(input: List<String>): Int { val characters = input.flatMap { it.split(" | ")[1].split(" ") } return characters.count { it.length in easyDigits } } class Mapping { private val mapping = mutableMapOf<Set<Char>, Int>() private val inverseMapping = mutableMapOf<Int, Set<Char>>() fun insert(value: Int, chars: Set<Char>) { mapping[chars] = value inverseMapping[value] = chars check(mapping.size == inverseMapping.size) } operator fun get(chars: Set<Char>) = mapping.getValue(chars) operator fun get(value: Int) = inverseMapping.getValue(value) operator fun contains(chars: Set<Char>) = chars !in mapping override fun toString() = mapping.entries.sortedBy { it.value }.joinToString { "${it.value}=${it.key.joinToString("")}" } } fun <T> MutableList<T>.removeFirst(filter: (T) -> Boolean) = removeAt(indexOfFirst(filter)) fun buildMapping(allDigits: Iterable<Set<Char>>): Mapping { val all = allDigits.distinct().toMutableList() check(all.size == 10) val mapping = Mapping() for ((count, value) in easyDigits) { mapping.insert(value, all.removeFirst { it.size == count }) } // 3 has 5 chars and contains all of 1 mapping.insert(3, all.removeFirst { it.size == 5 && it.containsAll(mapping[1]) }) // 9 has 6 chars and contains union of 3 & 4 mapping.insert(9, all.removeFirst { it.size == 6 && it.containsAll(mapping[3] union mapping[4]) }) // determine char that represents e (the char that differentiates 5 from 6) val eChar = mapping[8] subtract mapping[9] // 6 has 6 chars, 5 has 5 chars, and they only differ by the eChar outer@ for (fiveChar in all.filter { it.size == 5 }) { for (sixChar in all.filter { it.size == 6 }) { if (sixChar subtract fiveChar == eChar) { mapping.insert(6, sixChar) mapping.insert(5, fiveChar) all.remove(sixChar) all.remove(fiveChar) break@outer } } } // 2 has 5 chars and is not already mapped mapping.insert(2, all.removeFirst { it.size == 5 }) // 0 has 6 chars and is not already mapped mapping.insert(0, all.removeFirst { it.size == 6 }) return mapping } fun part2(input: List<String>): Int { var sum = 0 for (line in input) { val (test, output) = line.split(" | ").map { it.split(" ").map(String::toSet) } val mapping = buildMapping(test + output) sum += output.joinToString("") { mapping[it].toString() }.toInt() } return sum } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 26) check(part2(testInput) == 61229) val input = readInput("Day08") println(part1(input)) println(part2(input)) }

Kotlin

169fb9307a34b56c39578e3ee2cca038802bc046

AdventOfCode2021

Apache License 2.0

src/day15/d15_2.kt

svorcmar

{"Kotlin": 49110}

fun main() { val input = "" val ingredients = input.lines().map { parseIngredient(it) }.associateBy { it.name } println(forAllCombinations(ingredients, 100) { it.map { (k, v) -> listOf( ingredients[k]!!.capacity * v, ingredients[k]!!.durability * v, ingredients[k]!!.flavor * v, ingredients[k]!!.texture * v) to ingredients[k]!!.calories * v }.fold(listOf(0, 0, 0, 0) to 0) { (acc, accC), (list, c) -> acc.zip(list) { a, b -> a + b } to accC + c } .let { (it, c) -> it.map { if (it < 0) 0 else it } .reduce(Int::times) to c } }.filter { it.second == 500 } .map { it.first } .max()) } data class Ingredient(val name: String, val capacity: Int, val durability: Int, val flavor: Int, val texture: Int, val calories: Int) fun parseIngredient(s: String): Ingredient = s.split(" ").let { Ingredient(it[0].dropLast(1), it[2].dropLast(1).toInt(), it[4].dropLast(1).toInt(), it[6].dropLast(1).toInt(), it[8].dropLast(1).toInt(), it[10].toInt()) } fun <T> forAllCombinations(ingredients: Map<String, Ingredient>, n: Int, f: (Map<String, Int>) -> T): Sequence<T> { val names = ingredients.keys.toList() val arr = Array(names.size) { 0 } return forAllCombinationsRec(0, n, 0, arr, names, f) } fun <T> forAllCombinationsRec(step: Int, stepCount: Int, currIdx: Int, arr: Array<Int>, names: List<String>, f: (Map<String, Int>) -> T): Sequence<T> = sequence { if (step == stepCount) { yield(f(arr.mapIndexed {i, cnt -> names[i] to cnt }.toMap())) } else { if (currIdx < arr.size - 1) { arr[currIdx + 1]++ yieldAll(forAllCombinationsRec(step + 1, stepCount, currIdx + 1, arr, names, f)) arr[currIdx + 1]-- } arr[currIdx]++ yieldAll(forAllCombinationsRec(step + 1, stepCount, currIdx, arr, names, f)) arr[currIdx]-- } }

Kotlin

cb097b59295b2ec76cc0845ee6674f1683c3c91f

aoc2015

MIT License

src/main/kotlin/day9/Day9.kt

alxgarcia

{"Kotlin": 91398}

package day9 import java.io.File fun parseMap(rows: List<String>): Array<IntArray> = rows.map { row -> row.trim().map { it - '0' }.toIntArray() }.toTypedArray() fun expandAdjacent(row: Int, column: Int, map: Array<IntArray>): List<Pair<Int, Int>> = listOf(0 to -1, -1 to 0, 0 to 1, 1 to 0) .map { (r, c) -> (r + row) to (c + column) } .filterNot { (r, c) -> r < 0 || c < 0 || r >= map.size || c >= map[0].size } fun findLocalMinimums(map: Array<IntArray>): List<Pair<Int, Int>> { fun isLocalMinimum(row: Int, column: Int): Boolean { val adjacent = expandAdjacent(row, column, map) val current = map[row][column] return adjacent.all { (r, c) -> map[r][c] > current } } val rows = map.indices val columns = map[0].indices val traverseMapIndices = rows.flatMap { r -> columns.map { c -> r to c } } return traverseMapIndices.filter { (r, c) -> isLocalMinimum(r, c) } } fun sumOfLocalMinimums(map: Array<IntArray>): Int = findLocalMinimums(map).sumOf { (r, c) -> map[r][c] + 1 } fun computeBasinSize(row: Int, column: Int, map: Array<IntArray>): Int { val visited = mutableSetOf<Pair<Int, Int>>() val remaining = ArrayDeque(listOf(row to column)) var size = 0 do { val current = remaining.removeFirst() val currentValue = map[current.first][current.second] if (currentValue == 9 || visited.contains(current)) continue val nonVisitedAdjacent = expandAdjacent(current.first, current.second, map).filterNot { visited.contains(it) } val belongsToBasin = nonVisitedAdjacent.all { (r, c) -> map[r][c] >= currentValue } if (belongsToBasin) { size += 1 visited.add(current) remaining.addAll(nonVisitedAdjacent) } } while (!remaining.isEmpty()) return size } fun productOfSizeThreeLargestBasins(map: Array<IntArray>): Int = findLocalMinimums(map) .map { (r, c) -> computeBasinSize(r, c, map) } .sorted() .takeLast(3) .reduce(Int::times) fun main() { File("./input/day9.txt").useLines { lines -> val map = parseMap(lines.toList()) println(findLocalMinimums(map)) println(productOfSizeThreeLargestBasins(map)) } }

Kotlin

d6b10093dc6f4a5fc21254f42146af04709f6e30

advent-of-code-2021

MIT License

src/Day12.kt

sebastian-heeschen

{"Kotlin": 17461}

fun main() { fun parse(input: List<String>): HeightMap { val grid = input.map { it.toCharArray() } fun find(characterToFind: Char): Pair<Int, Int> { val y = grid.indexOfFirst { line -> line.contains(characterToFind) } val x = grid.map { line -> line.indexOfFirst { it == characterToFind } }.first { it >= 0 } return y to x } val start = find('S') val end = find('E') return HeightMap(grid, start, end) } fun elevation(current: Char): Int = when (current) { 'S' -> 0 'E' -> 'z' - 'a' else -> current - 'a' } fun shortestPath( grid: List<CharArray>, start: Pair<Int, Int>, target: Char, ascending: Boolean = true ): Int { fun nextSteps(point: Point) = listOfNotNull( Point(point.y, point.x - 1).takeIf { it.x >= 0 }, Point(point.y, point.x + 1).takeIf { it.x < grid.first().size }, Point(point.y - 1, point.x).takeIf { it.y >= 0 }, Point(point.y + 1, point.x).takeIf { it.y < grid.size } ) val end = Point( grid.indexOfFirst { line -> line.contains(target) }, grid.map { line -> line.indexOfFirst { it == target } }.first { it >= 0 } ) val queue = mutableListOf(start) val distances = mutableMapOf<Point, Int>() val visited = mutableSetOf<Point>() distances[start] = 0 while (queue.isNotEmpty()) { val current = queue.removeFirst() if (current !in visited) { visited.add(current) val currentElevation = elevation(grid[current.y][current.x]) val nextSteps = nextSteps(current) println("current: ${current.first},${current.second}: nexts: ${nextSteps.joinToString(separator = ";") { "${it.first},${it.second}" }}") nextSteps.filter { (x, y) -> val destElevation = elevation(grid[x][y]) if (ascending) { currentElevation - destElevation >= -1 } else { destElevation - currentElevation >= -1 } } .filter { it !in visited } .forEach { if (grid[it.y][it.x] == grid[end.y][end.x]) { return distances[current]!! + 1 } if (it !in distances) { distances[it] = distances[current]!! + 1 queue.add(it) } } } } return 0 } fun part1(input: List<String>): Int { val (grid, start, end) = parse(input) return shortestPath(grid, start, 'E') } fun part2(input: List<String>): Int { val (grid, start, end) = parse(input) return shortestPath(grid, end, 'a', ascending = false) } // test if implementation meets criteria from the description, like: val testInput = readInput("Day12_test") check(part1(testInput) == 31) check(part2(testInput) == 29) val input = readInput("Day12") println(part1(input)) println(part2(input)) } private data class HeightMap( val grid: List<CharArray>, val start: Pair<Int, Int>, val end: Pair<Int, Int> ) private typealias Point = Pair<Int, Int> val Point.x get() = second val Point.y get() = first

Kotlin

4432581c8d9c27852ac217921896d19781f98947

advent-of-code-2022

Apache License 2.0

src/Day08.kt

razvn

{"Kotlin": 27208}

private data class Tree(val x: Int, val y: Int, val value: Int) fun main() { val day = "Day08" fun part1(input: List<String>): Int { val trees = input.mapIndexed { lIdx, line -> line.mapIndexed { cIdx, col -> Tree(lIdx, cIdx, col.digitToInt()) } }.flatten() val maxX = trees.maxOf { it.x } val maxY = trees.maxOf { it.y } val visibleTrees = trees.filter { t -> when { t.x == 0 || t.y == 0 || t.x == maxX || t.y == maxY -> true else -> { val leftTreesBigger = trees.filter { it.x < t.x && it.y == t.y}.filter { it.value >= t.value } if (leftTreesBigger.isEmpty()) true else { val rightTreeBigger = trees.filter { it.x > t.x && it.y == t.y}.filter { it.value >= t.value } if (rightTreeBigger.isEmpty()) true else { val topTreeBigger = trees.filter { it.y < t.y && it.x == t.x}.filter { it.value >= t.value } if (topTreeBigger.isEmpty()) true else { val bottomTreeBigger = trees.filter { it.y > t.y && it.x == t.x}.filter { it.value >= t.value } bottomTreeBigger.isEmpty() } } } } } }.toSet() val totalVisible = visibleTrees.size return totalVisible } fun part2(input: List<String>): Int { val trees = input.mapIndexed { lIdx, line -> line.mapIndexed { cIdx, col -> Tree(cIdx, lIdx, col.digitToInt()) } }.flatten() // println(trees) val scenics = trees.map { tree -> val maxX = trees.maxOf { it.x } val maxY = trees.maxOf { it.y } if (tree.x == 0 || tree.y == 0 || tree.x == maxX || tree.y == maxY) 0 else { val leftValue = calcMove(tree, trees) {a, b -> (b.x == (a.x - 1)) && (a.y == b.y) } val rightValue = calcMove(tree, trees) {a, b -> (b.x == (a.x + 1)) && (a.y == b.y) } val topValue = calcMove(tree, trees) {a, b -> (b.y == (a.y - 1)) && (a.x == b.x) } val bottomValue = calcMove(tree, trees) {a, b -> (b.y == (a.y + 1)) && (a.x == b.x) } val rep = leftValue * rightValue * topValue * bottomValue //println("____ TREE ___ $tree = $rep (l: $leftValue | r: $rightValue | t: $topValue | b: $bottomValue") rep } } return scenics.max() } // test if implementation meets criteria from the description, like: val testInput = readInput("${day}_test") //println(part1(testInput)) // println(part2(testInput)) check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInput(day) println(part1(input)) println(part2(input)) } private fun calcMove(t: Tree, trees: List<Tree>, fn: (a: Tree, b: Tree) -> Boolean): Int { var exit = false var i = 0 var current = t while (!exit) { // println("currentTree: $current" ) val next = trees.firstOrNull { fn(current, it)} // println("Next: $next" ) if (next == null) exit = true else { i++ when { next.value >= t.value -> exit = true else -> current = next } } } return i }

Kotlin

73d1117b49111e5044273767a120142b5797a67b

aoc-2022-kotlin

Apache License 2.0

src/Day11.kt

thpz2210

{"Kotlin": 50995}

private open class Solution11(input: List<String>) { val monkeys = input.chunked(7).map { Monkey(it) } fun solve(times: Int): Long { repeat(times) { doRound() } return monkeys.map { it.counter }.sorted().takeLast(2).reduce(Long::times) } private fun doRound() { monkeys.forEach { m -> m.items.forEach { processItem(m, it) }; m.items.clear() } } private fun processItem(monkey: Monkey, it: Long) { var worryLevel = when (monkey.operation["code"]) { "*" -> if (monkey.operation["value"] == "old") it * it else it * monkey.operation["value"]!!.toLong() "+" -> if (monkey.operation["value"] == "old") it + it else it + monkey.operation["value"]!!.toLong() else -> throw IllegalArgumentException() } worryLevel = reduceWorryLevel(worryLevel) if (worryLevel % monkey.testValue == 0L) monkeys[monkey.ifTrue].items.add(worryLevel) else monkeys[monkey.ifFalse].items.add(worryLevel) monkey.counter += 1 } open fun reduceWorryLevel(worryLevel: Long) = worryLevel / 3L class Monkey(input: List<String>) { val items = input[1].split(":").last().split(",").map { it.trim().toLong() }.toMutableList() val operation = mapOf( Pair("code", input[2].trim().split(" ")[4]), Pair("value", input[2].trim().split(" ")[5])) val testValue = input[3].trim().split(" ").last().toLong() val ifTrue = input[4].trim().split(" ").last().toInt() val ifFalse = input[5].trim().split(" ").last().toInt() var counter = 0L } } private class Solution11Part2(input: List<String>) : Solution11(input) { val commonMultiple = monkeys.map { it.testValue }.reduce(Long::times) override fun reduceWorryLevel(worryLevel: Long) = worryLevel % commonMultiple } fun main() { val testSolution = Solution11(readInput("Day11_test")) check(testSolution.solve(20) == 10605L) val testSolution2 = Solution11Part2(readInput("Day11_test")) check(testSolution2.solve(10000) == 2713310158L) val solution = Solution11(readInput("Day11")) println(solution.solve(20)) val solution2 = Solution11Part2(readInput("Day11")) println(solution2.solve(10000)) }

Kotlin

69ed62889ed90692de2f40b42634b74245398633

aoc-2022

Apache License 2.0

src/Day11.kt

iProdigy

{"Kotlin": 33616}

fun main() { fun part1(input: List<String>) = run(input, 20, true) fun part2(input: List<String>) = run(input, 10_000, false) // test if implementation meets criteria from the description, like: val testInput = readInput("Day11_test") check(part1(testInput) == 10605L) check(part2(testInput) == 2713310158L) val input = readInput("Day11") println(part1(input)) // 57838 println(part2(input)) // 15050382231 } private fun run(input: List<String>, rounds: Int, divideBy3: Boolean): Long { val monkeys = parse(input).associateBy { it.id } val divisorProduct = monkeys.values.map { it.testDivisible }.distinct().reduce(Long::times) val counts = IntArray(monkeys.size) for (round in 1..rounds) { monkeys.values.forEach { while (it.items.isNotEmpty()) { val item = it.items.removeFirst() val updated = it.operation(item).let { l -> if (divideBy3) l / 3 else l } % divisorProduct counts[it.id]++ val next = if (updated % it.testDivisible == 0L) it.nextWhenTrue else it.nextWhenFalse monkeys[next]!!.items += updated } } } return counts.sortedDescending().let { (first, second) -> first.toLong() * second } } private fun parse(input: List<String>) = input.partitionBy { it.isEmpty() } .map { it.drop(1).map { line -> line.substring(line.indexOf(':') + 2) } } .mapIndexed { index, (startingStr, operationStr, testStr, trueStr, falseStr) -> fun last(str: String) = str.substring(str.lastIndexOf(' ') + 1) val items = startingStr.split(", ").mapTo(ArrayDeque()) { it.toLong() } val opDelim = operationStr.lastIndexOf(' ') val opNum = operationStr.substring(opDelim + 1).toLongOrNull() val operation: (Long) -> Long = when { operationStr.endsWith("* old") -> { it -> it * it } '*' == operationStr[opDelim - 1] -> { it -> it * opNum!! } '+' == operationStr[opDelim - 1] -> { it -> it + opNum!! } else -> throw Error("Bad Input!") } Monkey(index, items, last(testStr).toLong(), last(trueStr).toInt(), last(falseStr).toInt(), operation) } private data class Monkey( val id: Int, val items: ArrayDeque<Long> = ArrayDeque(), val testDivisible: Long, val nextWhenTrue: Int, val nextWhenFalse: Int, val operation: (Long) -> Long )

Kotlin

784fc926735fc01f4cf18d2ec105956c50a0d663

advent-of-code-2022

Apache License 2.0

kotlin/src/main/kotlin/year2023/Day19.kt

adrisalas

{"Kotlin": 130217, "Python": 1548}

package year2023 fun main() { val input = readInput2("Day19") Day19.part1(input).println() Day19.part2(input).println() } object Day19 { fun part1(input: String): Int { val chunks = input.split(DOUBLE_NEW_LINE_REGEX) val workflows = chunks[0] .split(NEW_LINE_REGEX) .map { line -> val name = line.split("{")[0] val rules = line.split("{")[1].split("}")[0].split(",").map { Rule(it) } Workflow(name, rules) } .associateBy { it.name } val ratings = chunks[1] .split(NEW_LINE_REGEX) .map { line -> line.split("{")[1] .split("}")[0] .split(",") .associate { it.split("=")[0][0] to it.split("=")[1].toInt() } } return ratings.sumOf { rating -> var result = -1 var next = "in" while (result == -1) { val rule = workflows.getValue(next).rules.first { it.matches(rating) } when (rule.result) { "R" -> result = 0 "A" -> result = rating.values.sum() else -> next = rule.result } } result } } fun part2(input: String): Long { val chunks = input.split(DOUBLE_NEW_LINE_REGEX) val workflows = chunks[0] .split(NEW_LINE_REGEX) .map { line -> val name = line.split("{")[0] val rules = line.split("{")[1].split("}")[0].split(",").map { Rule(it) } Workflow(name, rules) } .associateBy { it.name } return combine( workflows = workflows, entry = "in", ranges = mapOf( 'x' to (1..4000), 'm' to (1..4000), 'a' to (1..4000), 's' to (1..4000) ) ) } private fun combine(workflows: Map<String, Workflow>, entry: String, ranges: Map<Char, IntRange>): Long { return when (entry) { "R" -> 0L "A" -> ranges.values.map { it.last() - it.first() + 1 }.map { it.toLong() }.reduce(Long::times) else -> { val newRanges = ranges.toMutableMap() workflows.getValue(entry).rules.sumOf { rule -> if (rule.isUnconditional()) { combine( workflows = workflows, entry = rule.result, ranges = newRanges ) } else { val newRange = newRanges.getValue(rule.category!!).intersection(rule.range()) val newReversed = newRanges.getValue(rule.category).intersection(rule.reversedRange()) newRanges[rule.category] = newRange combine( workflows = workflows, entry = rule.result, ranges = newRanges ).also { newRanges[rule.category] = newReversed } } } } } } data class Workflow(val name: String, val rules: List<Rule>) class Rule(rule: String) { val result: String val category: Char? val operand: Char? private val value: Int? init { if (':' in rule) { val condition = rule.split(":")[0] category = condition[0] operand = condition[1] value = condition.substring(2).toInt() result = rule.split(":")[1] } else { category = null operand = null value = null result = rule } } fun isUnconditional() = category == null || operand == null || value == null fun matches(rating: Map<Char, Int>): Boolean { if (isUnconditional()) { return true } return when (operand) { '>' -> rating.getValue(category!!) > value!! '<' -> rating.getValue(category!!) < value!! else -> false } } fun range(): IntRange { if (value == null) { error("Not defined") } if (operand == '<') { return (1..<value) } return (value + 1..4000) } fun reversedRange(): IntRange { if (value == null) { error("Not defined") } if (operand == '<') { return (value..4000) } return (1..value) } } private fun IntRange.intersection(other: IntRange): IntRange { return (maxOf(first, other.first)..minOf(last, other.last)) } }

Kotlin

6733e3a270781ad0d0c383f7996be9f027c56c0e

advent-of-code

MIT License

y2023/src/main/kotlin/adventofcode/y2023/Day12.kt

Ruud-Wiegers

{"Kotlin": 503769}

package adventofcode.y2023 import adventofcode.io.AdventSolution fun main() { Day12.solve() } object Day12 : AdventSolution(2023, 12, "Hot Springs") { override fun solvePartOne(input: String) = parse(input).sumOf(ConditionRecord::countMatchingConfigurations) override fun solvePartTwo(input: String) = parse(input, 5).sumOf(ConditionRecord::countMatchingConfigurations) private fun parse(input: String, times: Int = 1) = input.lineSequence().map { val (line, guide) = it.split(" ") val springs = "$line?".repeat(times).dropLast(1).map(Spring::fromChar) val groups = "$guide,".repeat(times).dropLast(1).split(",").map(String::toInt) ConditionRecord(springs, groups) } } private data class ConditionRecord(val row: List<Spring>, val damagedGroups: List<Int>) { fun countMatchingConfigurations() = row.fold(mapOf(SolutionPattern(Constraint.None, damagedGroups) to 1L)) { prev, spring -> buildMap { for ((clue, count) in prev) { for (new in clue.matchNextSpring(spring)) { merge(new, count, Long::plus) } } } } .filterKeys(SolutionPattern::completeMatch).values.sum() } private data class SolutionPattern(val constraint: Constraint, val unmatchedDamagedGroups: List<Int>) { fun matchNextSpring(spring: Spring): List<SolutionPattern> = buildList { if (spring != Spring.Operational) matchDamagedSpring()?.let(::add) if (spring != Spring.Damaged) matchOperationalSpring()?.let(::add) } private fun matchOperationalSpring(): SolutionPattern? = when (constraint) { is Constraint.Damaged -> null else -> SolutionPattern(Constraint.None, unmatchedDamagedGroups) } private fun matchDamagedSpring(): SolutionPattern? = when (constraint) { Constraint.Operational -> null Constraint.None -> startNewDamagedGroup()?.matchDamagedSpring() is Constraint.Damaged -> SolutionPattern(constraint.next(), unmatchedDamagedGroups) } private fun startNewDamagedGroup(): SolutionPattern? = if (unmatchedDamagedGroups.isEmpty()) null else SolutionPattern( Constraint.Damaged(unmatchedDamagedGroups.first()), unmatchedDamagedGroups.drop(1) ) fun completeMatch() = !constraint.mandatory && unmatchedDamagedGroups.isEmpty() } //Requirements for next springs to match private sealed class Constraint(val mandatory: Boolean) { //no requirements data object None : Constraint(false) //next spring must be operational data object Operational : Constraint(false) //next [amount] springs must be damaged, followed by 1 operational spring data class Damaged(private val amount: Int) : Constraint(true) { fun next() = if (amount > 1) Damaged(amount - 1) else Operational } } private enum class Spring { Operational, Damaged, Unknown; companion object { fun fromChar(ch: Char) = when (ch) { '.' -> Operational '#' -> Damaged else -> Unknown } } }

Kotlin

fc35e6d5feeabdc18c86aba428abcf23d880c450

advent-of-code

MIT License

src/Day13.kt

palex65

{"Kotlin": 68582}

import kotlin.math.min private fun compareSeq(a: List<String>, b: List<String>): Int { for(i in 0 until min(a.size,b.size)) { val res = compare(a[i], b[i]) if (res!=0) return res } return a.size - b.size } private fun String.indexOfClosedPair(from: Int): Int { var level = 1 for( i in from until length ) when(this[i]) { '[' -> ++level ']' -> if (--level==0) return i } return -1 } private fun String.splitSeq(): List<String> { val res = mutableListOf<String>() var lastIdx = 0 var idx = 0 while(idx < length) { when(this[idx]) { ',' -> { res.add( substring(lastIdx,idx) ) lastIdx=++idx } '[' -> idx = indexOfClosedPair(idx+1)+1 else -> ++idx } } if (idx>lastIdx) res.add( substring(lastIdx,idx)) return res } private fun compare(a: String, b: String): Int { val fa = a[0] val fb = b[0] fun String.toSeq() = substring(1,lastIndex).splitSeq() return when { fa.isDigit() && fb.isDigit() -> a.toInt() - b.toInt() fa=='[' && fb=='[' -> compareSeq( a.toSeq(), b.toSeq() ) fa=='[' -> compareSeq( a.toSeq(), listOf(b) ) fb=='[' -> compareSeq( listOf(a), b.toSeq() ) else -> error("Invalid start of package $fa or $fb") } } private fun part1(lines: List<String>): Int = lines .splitBy { it.isEmpty() } .mapIndexed { idx, pair -> if (compare(pair[0], pair[1]) < 0) idx+1 else 0 } .sum() private fun part2(lines: List<String>): Int { val packets = lines.filter{ it.isNotEmpty() } + "[[2]]" + "[[6]]" val sorted = packets.sortedWith(::compare) return (sorted.indexOf("[[2]]")+1) * (sorted.indexOf("[[6]]")+1) } fun main() { val testInput = readInput("Day13_test") check(part1(testInput) == 13) check(part2(testInput) == 140) val input = readInput("Day13") println(part1(input)) // 5390 println(part2(input)) // 19261 }

Kotlin

35771fa36a8be9862f050496dba9ae89bea427c5

aoc2022

Apache License 2.0

src/year2022/12/Day12.kt

Vladuken

{"Kotlin": 327524, "Python": 16475}

package year2022.`12` import kotlin.math.abs import readInput data class Square( val i: Int, val j: Int, val height: Int, ) data class SquareRecord( val currentNode: Square, var shortestDistance: Int, var previousNode: Square? ) fun calculateDistances(start: Square, grid: List<List<Square>>): List<SquareRecord> { fun nodeAtOrNull(i: Int, j: Int): Square? { val iMax = grid.lastIndex val jMax = grid[0].lastIndex return if (i < 0 || i > iMax || j < 0 || j > jMax) null else grid[i][j] } fun Square.neighbors() = listOfNotNull( nodeAtOrNull(i - 1, j), nodeAtOrNull(i + 1, j), nodeAtOrNull(i, j - 1), nodeAtOrNull(i, j + 1) ) .filter { it.height + 1 >= height } val result: List<SquareRecord> = grid .flatten() .map { SquareRecord( currentNode = it, shortestDistance = if (it == start) 0 else Int.MAX_VALUE, previousNode = null ) } val unvisitedSquares = grid.flatten().toMutableSet() val visitedSquares = mutableSetOf<Square>() while (unvisitedSquares.isNotEmpty()) { // Find next record to visit val record = result .filter { it.currentNode in unvisitedSquares } .minBy { it.shortestDistance } //Find neighbours that have one step distance val neighbours = record.currentNode.neighbors() neighbours .filter { it in unvisitedSquares } .forEach { neighbour -> // Find current record for this neighbour val neighbourRecord = result .find { it.currentNode == neighbour } ?: error("Illegal State") // Calculate new distance (1 is a step) val distance = record.shortestDistance + 1 // If distance is less - then update record with new distance if (distance < neighbourRecord.shortestDistance) { neighbourRecord.shortestDistance = distance neighbourRecord.previousNode = record.currentNode } } // Mark node as visited unvisitedSquares.remove(record.currentNode) visitedSquares.add(record.currentNode) } return result } fun main() { fun parseInput(input: List<String>): Triple<Square, Square, List<List<Square>>> { var start: Square? = null var end: Square? = null val grid = input.mapIndexed { i, line -> line .split("") .dropLast(1) .drop(1) .mapIndexed { j, symbol -> val isS = symbol == "S" val isE = symbol == "E" val newChar = when { isS -> 'a' isE -> 'z' else -> symbol[0] } Square( i = i, j = j, height = abs('a' - newChar), ).also { if (isS) start = it if (isE) end = it } } } return Triple(start!!, end!!, grid) } fun part1(input: List<String>): Int { val (start, end, grid) = parseInput(input) val results = calculateDistances(end, grid) val sum = results.find { it.currentNode == start } return sum!!.shortestDistance } fun part2(input: List<String>): Int { val (_, end, grid) = parseInput(input) val results = calculateDistances(end, grid) val sum = results .filter { it.currentNode.height == 0 } .filter { it.shortestDistance >= 0 } .minBy { it.shortestDistance } return sum.shortestDistance } // test if implementation meets criteria from the description, like: val testInput = readInput("Day12_test") val part1Test = part1(testInput) val part2Test = part2(testInput) println(part1Test) check(part1Test == 31) check(part2Test == 29) val input = readInput("Day12") println(part1(input)) println(part2(input)) }

Kotlin

c0f36ec0e2ce5d65c35d408dd50ba2ac96363772

KotlinAdventOfCode

Apache License 2.0

src/Day08.kt

xabgesagtx

{"Kotlin": 23192}

fun main() { fun part1(input: List<String>): Int { val treeValues = input.map { line -> line.toList().map { it.digitToInt() } } val lastXIndex = treeValues[0].lastIndex val lastYIndex = treeValues.lastIndex return treeValues.indices.flatMap { y -> treeValues[y].indices.mapNotNull { x -> val currentValue = treeValues[y][x] when { x == 0 || y == 0 || x == lastXIndex || y == lastYIndex -> x to y treeValues.maxFromLeft(x, y) < currentValue -> x to y treeValues.maxFromRight(x, y) < currentValue -> x to y treeValues.maxFromTop(x, y) < currentValue -> x to y treeValues.maxFromBottom(x, y) < currentValue -> x to y else -> null } } }.distinct().count() } fun part2(input: List<String>): Int { val treeValues = input.map { line -> line.toList().map { it.digitToInt() } } return treeValues.mapIndexed { y, line -> List(line.size) { x -> treeValues.scenicScore(x, y) }.max() }.max() } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") println(part1(testInput)) check(part1(testInput) == 21) println(part2(testInput)) check(part2(testInput) == 8) val input = readInput("Day08") println(part1(input)) println(part2(input)) } private fun List<List<Int>>.maxFromLeft(x: Int, y: Int) = this[y].subList(0, x).max() private fun List<List<Int>>.maxFromRight(x: Int, y: Int) = this[y].subList(x + 1, this[y].lastIndex + 1).max() private fun List<List<Int>>.maxFromTop(x: Int, y: Int): Int { val list = this.map { it[x] } return list.subList(0, y).max() } private fun List<List<Int>>.maxFromBottom(x: Int, y: Int): Int { val list = this.map { it[x] } return list.subList(y + 1, lastIndex + 1).max() } private fun List<List<Int>>.scenicScore(x: Int, y: Int): Int { return if (x == 0 || y == 0 || y == this.lastIndex || x == this[y].lastIndex) { 0 } else { scenicScoreLeft(x, y) * scenicScoreRight(x, y) * scenicScoreTop(x, y) * scenicScoreBottom(x, y) } } private fun List<List<Int>>.scenicScoreBottom(x: Int, y: Int): Int { val currentValue = this[y][x] val list = this.map { it[x] }.subList(y + 1, lastIndex + 1) return (list.takeWhile { it < currentValue }.count() + 1).coerceAtMost(list.size) } private fun List<List<Int>>.scenicScoreTop(x: Int, y: Int): Int { val currentValue = this[y][x] val list = this.map { it[x] }.subList(0, y).reversed() return (list.takeWhile { it < currentValue }.count() + 1).coerceAtMost(list.size) } private fun List<List<Int>>.scenicScoreLeft(x: Int, y: Int): Int { val currentValue = this[y][x] val list = this[y].subList(0, x).reversed() return (list.takeWhile { it < currentValue }.count() + 1).coerceAtMost(list.size) } private fun List<List<Int>>.scenicScoreRight(x: Int, y: Int): Int { val currentValue = this[y][x] val list = this[y].subList(x + 1, this[y].lastIndex + 1) return (list.takeWhile { it < currentValue }.count() + 1).coerceAtMost(list.size) }

Kotlin

976d56bd723a7fc712074066949e03a770219b10

advent-of-code-2022

Apache License 2.0

src/Day08.kt

dmstocking

{"Kotlin": 40350}

fun main() { fun part1(input: List<String>): Int { val heights = input .map { line -> line.map { it.digitToInt() } } val height = heights.size val width = heights.first().size return heights .mapIndexed { y, line -> line.mapIndexed { x, h -> val left = (0 until x).map { heights[y][it] }.all { it < h } val right = ((x+1) until width).map { heights[y][it] }.all { it < h } val up = (0 until y).map { heights[it][x] }.all { it < h } val down = ((y+1) until height).map { heights[it][x] }.all { it < h } left || right || up || down } } .flatten() .map { if (it) 1 else 0 } .sumOf { it } } fun part2(input: List<String>): Int { val heights = input .map { line -> line.map { it.digitToInt() } } val height = heights.size val width = heights.first().size return heights .mapIndexed { y, line -> line.mapIndexed { x, h -> val left = (0 until x).reversed().map { heights[y][it] }.takeWhileInclusive { it < h }.count() val right = ((x+1) until width).map { heights[y][it] }.takeWhileInclusive { it < h }.count() val up = (0 until y).reversed().map { heights[it][x] }.takeWhileInclusive { it < h }.count() val down = ((y+1) until height).map { heights[it][x] }.takeWhileInclusive { it < h }.count() left * right * up * down } } .flatten() .maxOf { it } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 21) val input = readInput("Day08") println(part1(input)) println(part2(input)) } fun <T> Iterable<T>.takeWhileInclusive(predicate: (T) -> Boolean): List<T> { val list = ArrayList<T>() for (item in this) { list.add(item) if (!predicate(item)) break } return list }

Kotlin

e49d9247340037e4e70f55b0c201b3a39edd0a0f

advent-of-code-kotlin-2022

Apache License 2.0

src/main/kotlin/dev/paulshields/aoc/Day9.kt

Pkshields

{"Kotlin": 133840}

/** * Day 9: Smoke Basin */ package dev.paulshields.aoc import dev.paulshields.aoc.common.readFileAsString fun main() { println(" ** Day 9: Smoke Basin ** \n") val heightMap = readFileAsString("/Day9HeightMap.txt") val riskLevel = calculateRiskLevelOfHeightMap(heightMap) println("The combined risk level for this height map is $riskLevel") val result = findSizeOfBasins(heightMap) .sortedDescending() .take(3) .fold(1) { accumulator, basinSize -> accumulator * basinSize } println("The product of the largest 3 basin sizes is $result") } fun calculateRiskLevelOfHeightMap(rawHeightMap: String): Int { val heightMap = parseHeightMap(rawHeightMap) return heightMap.filter { it.isLowPoint }.map { it.location }.sumOf { it + 1 } } fun findSizeOfBasins(rawHeightMap: String): List<Int> { val heightMap = parseHeightMap(rawHeightMap) return heightMap .filter { it.isLowPoint } .map { calculateSizeOfBasin(it, heightMap) } } fun calculateSizeOfBasin(centerLocation: HeightMapLocation, heightMap: List<HeightMapLocation>): Int { val modifiableHeightMap = heightMap.toMutableList().apply { remove(centerLocation) } val locationsInBasin = mutableListOf(centerLocation) var i = -1 while (++i < locationsInBasin.size) { val neighbours = findNeighboursWithinBasin(locationsInBasin[i], modifiableHeightMap) locationsInBasin.uniqueAddAll(neighbours) modifiableHeightMap.removeAll(neighbours) } return locationsInBasin.size } private fun findNeighboursWithinBasin(location: HeightMapLocation, heightMap: List<HeightMapLocation>): List<HeightMapLocation> { return heightMap.filter { it.x == location.x - 1 && it.y == location.y || it.x == location.x + 1 && it.y == location.y || it.x == location.x && it.y == location.y - 1 || it.x == location.x && it.y == location.y + 1 }.filter { it.location != 9 } } private fun parseHeightMap(rawHeightMap: String): List<HeightMapLocation> { val heightMap = rawHeightMap .lines() .map { it.toCharArray().map { it.digitToInt() } } return heightMap.mapIndexed { yIndex, line -> line.mapIndexed { xIndex, location -> val left = if (xIndex > 0) location < heightMap[yIndex][xIndex - 1] else true val right = if (xIndex < line.size - 1) location < heightMap[yIndex][xIndex + 1] else true val top = if (yIndex > 0) location < heightMap[yIndex - 1][xIndex] else true val bottom = if (yIndex < heightMap.size - 1) location < heightMap[yIndex + 1][xIndex] else true HeightMapLocation(location, xIndex, yIndex, left && right && top && bottom) } }.flatten() } data class HeightMapLocation(val location: Int, val x: Int, val y: Int, val isLowPoint: Boolean) fun <T> MutableList<T>.uniqueAddAll(listToAdd: List<T>) = addAll(listToAdd.filter { !this.contains(it) })

Kotlin

e3533f62e164ad72ec18248487fe9e44ab3cbfc2

AdventOfCode2021

MIT License

kotlin/src/Day14.kt

ekureina

{"Kotlin": 65477, "C": 12591, "Rust": 7560, "Makefile": 386}

fun main() { fun part1(input: List<String>): Int { val template = input.first() val rules = input.drop(2).associate { line -> val (pair, insert) = line.split(" -> ") (pair[0] to pair[1]) to insert[0] } val finalString = (0 until 10).fold(template) { polymer, _ -> val insertions = polymer.zipWithNext().map { pair -> rules[pair]!! }.joinToString("") polymer.zip(insertions).flatMap { (polymer, inserted) -> listOf(polymer, inserted) }.joinToString("") + polymer.last() } val charCounts = finalString.toSet().associateWith { char -> finalString.count(char::equals) } return charCounts.values.maxOrNull()!! - charCounts.values.minOrNull()!! } fun part2(input: List<String>): Long { val template = input.first() val rules = input.drop(2).associate { line -> val (pair, insert) = line.split(" -> ") (pair[0] to pair[1]) to ((pair[0] to insert[0]) to (insert[0] to pair[1])) } val pairs = rules.keys.associateWith { pair -> template.zipWithNext().count { it == pair }.toLong() } val finalPairs = (0 until 40).fold(pairs) { pairs, _ -> val newPairs = pairs.keys.flatMap { pair -> listOf(rules[pair]!!.first to pairs[pair]!!, rules[pair]!!.second to pairs[pair]!!) } newPairs.toSet() .map(Pair<Pair<Char, Char>, Long>::first) .associateWith { pair -> newPairs.filter { (key, _) -> key == pair }.sumOf { it.second } } } val charCounts = rules.keys.map(Pair<Char, Char>::first).toSet().associateWith { char -> finalPairs.filter { (pair, count) -> pair.first == char }.values.sum() + if (char == template.last()) { 1 } else { 0 } } return charCounts.values.maxOrNull()!! - charCounts.values.minOrNull()!! } // test if implementation meets criteria from the description, like: val testInput = readInput("Day14_test") check(part1(testInput) == 1588) { "${part1(testInput)}" } check(part2(testInput) == 2188189693529L) { "${part2(testInput)}"} val input = readInput("Day14") println(part1(input)) println(part2(input)) }

Kotlin

391d0017ba9c2494092d27d22d5fd9f73d0c8ded

aoc-2021

MIT License

src/year2023/Day2.kt

drademacher

{"Kotlin": 76037}

package year2023 import readLines fun main() { val input = readLines("2023", "day2") val testInput = readLines("2023", "day2_test") check(part1(testInput) == 8) println("Part 1:" + part1(input)) check(part2(testInput) == 2286) println("Part 2:" + part2(input)) } private fun parseInput(input: List<String>): List<Game> { fun parseCubeCount(string: String): CubeCount { val rawCubePairs = string.split(", ").map { rawCube -> rawCube.split(" ").let { Pair(it[0], it[1]) } } return CubeCount( red = rawCubePairs.find { it.second == "red" }?.first?.toInt() ?: 0, blue = rawCubePairs.find { it.second == "blue" }?.first?.toInt() ?: 0, green = rawCubePairs.find { it.second == "green" }?.first?.toInt() ?: 0, ) } fun parseGame(string: String): Game { val number = string.dropWhile { !it.isDigit() }.takeWhile { it.isDigit() }.toInt() val rawCubeCounts = string.dropWhile { it != ':' }.drop(2).split("; ") val cubeCounts = rawCubeCounts.map { parseCubeCount(it) } return Game(number, cubeCounts) } return input.map { parseGame(it) } } private fun part1(input: List<String>): Int { val input = parseInput(input) return input .filter { game -> game.cubeCounts.all { cubeCount -> cubeCount.red <= 12 && cubeCount.green <= 13 && cubeCount.blue <= 14 } } .sumOf { it.index } } private fun part2(input: List<String>): Int { val input = parseInput(input) return input .map { game -> game.cubeCountMaximums() } .sumOf { maximums -> maximums.red * maximums.blue * maximums.green } } data class Game(val index: Int, val cubeCounts: List<CubeCount>) { fun cubeCountMaximums(): CubeCount { return CubeCount( cubeCounts.maxBy { it.red }.red, cubeCounts.maxBy { it.blue }.blue, cubeCounts.maxBy { it.green }.green, ) } } data class CubeCount(val red: Int, val blue: Int, val green: Int)

Kotlin

4c4cbf677d97cfe96264b922af6ae332b9044ba8

advent_of_code

MIT License

src/Day08.kt

proggler23

{"Kotlin": 27990}

fun main() { fun part1(input: List<String>) = input.parse8().visibleTreeCount fun part2(input: List<String>) = input.parse8().bestScenicView // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInput("Day08") println(part1(input)) println(part2(input)) } fun List<String>.parse8() = TreeGrid(Array(this[0].length) { x -> Array(size) { y -> this[y][x].digitToInt() } }) fun <T> List<T>.productOf(transform: (T) -> Int) = fold(1) { acc, t -> acc * transform(t) } class TreeGrid(private val heights: Array<Array<Int>>) { val visibleTreeCount: Int get() = heights.indices.sumOf { x -> heights[x].indices.count { y -> isTreeVisible(x, y) } } val bestScenicView: Int get() = heights.indices.maxOf { x -> heights[x].indices.maxOf { y -> getScenicScore(x, y) } } private fun viewRanges(x: Int, y: Int) = listOf( (x - 1 downTo 0).map { heights[it][y] }, (x + 1 until heights.size).map { heights[it][y] }, (y - 1 downTo 0).map { heights[x][it] }, (y + 1 until heights[x].size).map { heights[x][it] } ) private fun isTreeVisible(x: Int, y: Int) = viewRanges(x, y).any { it.all { height -> height < heights[x][y] } } private fun getScenicScore(x: Int, y: Int) = viewRanges(x, y).productOf { range -> val filteredRange = range.takeWhile { height -> height < heights[x][y] } if (range.isEmpty()) 0 else if (filteredRange.size == range.size) range.size else filteredRange.size + 1 } }

Kotlin

584fa4d73f8589bc17ef56c8e1864d64a23483c8

advent-of-code-2022

Apache License 2.0

aoc21/day_22/main.kt

viktormalik

{"Rust": 227300, "Go": 86273, "OCaml": 82410, "Kotlin": 78968, "Makefile": 13967, "Roff": 9981, "Shell": 2796}

import java.io.File import kotlin.math.max import kotlin.math.min data class Range(val min: Int, val max: Int) { fun hasIntersection(range: Range): Boolean = range.min <= max && range.max >= min fun intersection(range: Range): Range = Range(max(min, range.min), min(max, range.max)) fun minus(range: Range): List<Range> { if (!hasIntersection(range)) return listOf(this) if (range.min <= min && range.max >= max) return listOf() if (range.min < min) return listOf(Range(range.max + 1, max)) if (range.max > max) return listOf(Range(min, range.min - 1)) return listOf(Range(min, range.min - 1), Range(range.max + 1, max)) } fun size(): Long = (max - min + 1).toLong() } class Cube(val x: Range, val y: Range, val z: Range) { fun hasIntersection(cube: Cube): Boolean = x.hasIntersection(cube.x) && y.hasIntersection(cube.y) && z.hasIntersection(cube.z) fun intersection(cube: Cube): Cube? = if (hasIntersection(cube)) Cube(x.intersection(cube.x), y.intersection(cube.y), z.intersection(cube.z)) else null fun minus(cube: Cube): List<Cube> = x.minus(cube.x).map { Cube(it, y, z) } + y.minus(cube.y).map { Cube(x.intersection(cube.x), it, z) } + z.minus(cube.z).map { Cube(x.intersection(cube.x), y.intersection(cube.y), it) } fun size(): Long = x.size() * y.size() * z.size() } fun main() { var cubes = listOf<Cube>() val re = "x=(-?\\d+)..(-?\\d+),y=(-?\\d+)..(-?\\d+),z=(-?\\d+)..(-?\\d+)".toRegex() for (line in File("input").readLines()) { val match = re.find(line)!!.groupValues val cube = Cube( Range(match.get(1).toInt(), match.get(2).toInt()), Range(match.get(3).toInt(), match.get(4).toInt()), Range(match.get(5).toInt(), match.get(6).toInt()), ) if (line.startsWith("on")) { cubes += cubes.fold(listOf(cube)) { newCubes, c -> newCubes.flatMap { if (it.hasIntersection(c)) it.minus(c) else listOf(it) } } } else { cubes = cubes.flatMap { if (it.hasIntersection(cube)) it.minus(cube) else listOf(it) } } } val initArea = Cube(Range(-50, 50), Range(-50, 50), Range(-50, 50)) val first = cubes.map { it.intersection(initArea)?.size() ?: 0 }.sum() println("First: $first") val second = cubes.map { it.size() }.sum() println("Second: $second") }

Rust

f47ef85393d395710ce113708117fd33082bab30

advent-of-code

MIT License

src/Day16.kt

jbotuck

{"Kotlin": 42401}

import kotlin.math.max import kotlin.math.min fun main() { val valves = readInput("Day16") .map { Valve.of(it) } .associateBy { it.name } val start = valves["AA"]!! val valvesWithNeighbors = valves.values .filter { it.name == "AA" || it.flowRate > 0 } .sortedBy { it.name } .let { valuableValves -> val distances = valuableValves.mapIndexed { index, origin -> (index.inc()..valuableValves.lastIndex) .map { (origin.name to valuableValves[it].name) to valves.calculateCost( origin.name, valuableValves[it].name ) } }.flatten().toMap() valuableValves.associateWith { thisValve -> valuableValves .filter { it != thisValve && it.name != "AA" } .map { it to distances.getDistance(thisValve.name, it.name) } .sortedBy { it.second } } } //part1 run { val paths = getPaths(start, valvesWithNeighbors, 30) println(paths.values.max()) } //part 2 val paths = getPaths(start, valvesWithNeighbors, 26) paths.maxOf { me -> me.value.plus(paths .filter { elephant -> elephant.key.all { it !in me.key } } .maxOfOrNull { elephant -> elephant.value } ?: 0 ) }.let { println(it) } } private fun getPaths( start: Valve, valvesWithNeighbors: Map<Valve, List<Pair<Valve, Int>>>, timeAllowed: Int = 30 ) = mutableMapOf<Set<String>, Int>().apply { val solutions = ArrayDeque<Solution>().apply { addLast(Solution(start, timeAllowed = timeAllowed)) } while (solutions.isNotEmpty()) { val solution = solutions.removeFirst() val key = solution.visited.map { it.name }.toSet() this[key] = max(solution.totalRelief, this[key] ?: 0) solution.nextSolutions(valvesWithNeighbors).takeUnless { it.isEmpty() }?.let { solutions.addAll(it) } } }.toMap() private fun Map<Pair<String, String>, Int>.getDistance(a: String, b: String) = get(listOf(a, b).sorted().run { first() to last() })!! fun Map<String, Valve>.calculateCost(origin: String, destination: String): Int { val costs = mutableMapOf<String, Int>().apply { set(origin, 0) } val toVisit = mutableListOf(origin) val visited = mutableSetOf<String>() while (toVisit.isNotEmpty()) { val visiting = toVisit.removeAt(toVisit.withIndex().minBy { costs[it.value] ?: Int.MAX_VALUE }.index) if (visiting in visited) continue visited.add(visiting) if (visiting == destination) return costs[visiting]!!.inc() //Plus 1 to open the valve val distanceOfNeighbor = costs[visiting]!!.inc() for (neighbor in get(visiting)!!.neighbors) { toVisit.add(neighbor) costs[neighbor] = costs[neighbor]?.let { min(it, distanceOfNeighbor) } ?: distanceOfNeighbor } } throw IllegalStateException("oops") } data class Valve(val name: String, val flowRate: Int, val neighbors: List<String>) { fun totalRelief(timeOpen: Int) = flowRate * timeOpen companion object { fun of(line: String): Valve { val (valve, neighbors) = line.split(';') val (name, flowRate) = valve.substringAfter("Valve ").split(" has flow rate=") return Valve( name, flowRate.toInt(), neighbors .substringAfter(" tunnel leads to valve ") .substringAfter(" tunnels lead to valves ") .split(", ") ) } } } data class Solution( val visited: Set<Valve>, val lastVisited: Valve, val costIncurred: Int = 0, val timeAllowed: Int = 30, val totalRelief: Int = 0 ) { constructor(valve: Valve, costIncurred: Int = 0, timeAllowed: Int = 30, totalRelief: Int = 0) : this( setOf(), valve, costIncurred, timeAllowed, totalRelief ) private val timeRemaining = timeAllowed - costIncurred private fun with(valve: Valve, additionalCost: Int) = copy( visited = visited + valve, lastVisited = valve, costIncurred = costIncurred + additionalCost, totalRelief = totalRelief + valve.totalRelief(timeRemaining - additionalCost) ) fun nextSolutions(valvesWithNeighbors: Map<Valve, List<Pair<Valve, Int>>>) = mutableListOf<Solution>().apply { for (destination in valvesWithNeighbors[lastVisited]!!) { if (destination.first in visited) continue if (destination.second > timeRemaining) break add(with(destination.first, destination.second)) } } }

Kotlin

d5adefbcc04f37950143f384ff0efcd0bbb0d051

aoc2022

Apache License 2.0

src/Day12.kt

cisimon7

{"Kotlin": 41406}

fun main() { fun shortestPath( map: List<List<Elevation>>, startElevation: Elevation, endElevation: Elevation ): List<List<Elevation>> { var paths = listOf(listOf(map.flatten().firstOrNull { it == endElevation } ?: error("Can't find highest point"))) while (paths.map { it.last() }.none { it == startElevation }) { paths = paths // Eliminating paths that have the same start and end points by taking the shortest path already .groupBy { it.last() } .map { (_, list) -> list.minBy { it.size } } // Extending paths .map { path -> val (end, rest) = path.last() to path.dropLast(1) map.possibleNext(end) .filter { cell -> cell !in rest } // Prevent loop .map { cell -> rest + listOf(end, cell) } .ifEmpty { listOf(path) } }.flatten().also { if (it == paths) error("Can't find path to starting point") } } return paths } fun part1(map: List<List<Elevation>>): Int { val startElevation = map.flatten().first { it.h == -1 } val endElevation = map.flatten().first { it.h == 26 } val paths = shortestPath(map, startElevation, endElevation) return paths.filter { it.last().h == -1 }.minBy { it.size }.count() - 1 } fun part2(map: List<List<Elevation>>): Int { // Takes forever for large maps, but works val endElevation = map.flatten().first { it.h == 26 } val startElevations = map.flatten().filter { it.h == 0 } + map.flatten().first { it.h == -1 } println(startElevations.size) return startElevations .map { start -> runCatching { shortestPath(map, start, endElevation) } .getOrElse { emptyList() } } .flatten() .filter { it.last().h == -1 || it.last().h == 0 } .minBy { it.size } .count() - 1 } fun parse(stringList: List<String>): List<List<Elevation>> { return stringList.mapIndexed { rIdx, line -> line.mapIndexed { cIdx, h -> when { h.isLowerCase() -> Elevation(rIdx, cIdx, h - 'a', h) h == 'S' -> Elevation(-1, -1, -1, h) h == 'E' -> Elevation(rIdx, cIdx, 26, h) else -> error("un-excepted character $h") } } } } val testInput = readInput("Day12_test") check(part1(parse(testInput)) == 31) check(part2(parse(testInput)) == 29) val input = readInput("Day12_input") println(part1(parse(input))) println(part2(parse(input))) } data class Elevation(val x: Int, val y: Int, val h: Int, val ch: Char) fun List<List<Elevation>>.possibleNext(elevation: Elevation): List<Elevation> { val (x, y, h, _) = elevation return listOf(+1 to +0, +0 to +1, -1 to +0, +0 to -1) .map { (i, j) -> i + x to j + y } .filterNot { (i, j) -> i < 0 || i >= size || j < 0 || j >= this.first().size } .map { (i, j) -> this[i][j] } .filter { it.h + 1 == h || it.h >= h } } /** * Advent of Code[About][Events][Shop][Settings][Log Out]cisimon7 23* * λy.2022[Calendar][AoC++][Sponsors][Leaderboard][Stats] * Our sponsors help make Advent of Code possible: * NUMERAI - join the hardest data science tournament in the world * --- Day 12: Hill Climbing Algorithm --- * You try contacting the Elves using your handheld device, but the river you're following must be too low to get a decent signal. * * You ask the device for a heightmap of the surrounding area (your puzzle input). The heightmap shows the local area from above broken into a grid; the elevation of each square of the grid is given by a single lowercase letter, where a is the lowest elevation, b is the next-lowest, and so on up to the highest elevation, z. * * Also included on the heightmap are marks for your current position (S) and the location that should get the best signal (E). Your current position (S) has elevation a, and the location that should get the best signal (E) has elevation z. * * You'd like to reach E, but to save energy, you should do it in as few steps as possible. During each step, you can move exactly one square up, down, left, or right. To avoid needing to get out your climbing gear, the elevation of the destination square can be at most one higher than the elevation of your current square; that is, if your current elevation is m, you could step to elevation n, but not to elevation o. (This also means that the elevation of the destination square can be much lower than the elevation of your current square.) * * For example: * * Sabqponm * abcryxxl * accszExk * acctuvwj * abdefghi * Here, you start in the top-left corner; your goal is near the middle. You could start by moving down or right, but eventually you'll need to head toward the e at the bottom. From there, you can spiral around to the goal: * * v..v<<<< * >v.vv<<^ * .>vv>E^^ * ..v>>>^^ * ..>>>>>^ * In the above diagram, the symbols indicate whether the path exits each square moving up (^), down (v), left (<), or right (>). The location that should get the best signal is still E, and . marks unvisited squares. * * This path reaches the goal in 31 steps, the fewest possible. * * What is the fewest steps required to move from your current position to the location that should get the best signal? * * Your puzzle answer was 394. * * The first half of this puzzle is complete! It provides one gold star: * * * --- Part Two --- * As you walk up the hill, you suspect that the Elves will want to turn this into a hiking trail. The beginning isn't very scenic, though; perhaps you can find a better starting point. * * To maximize exercise while hiking, the trail should start as low as possible: elevation a. The goal is still the square marked E. However, the trail should still be direct, taking the fewest steps to reach its goal. So, you'll need to find the shortest path from any square at elevation a to the square marked E. * * Again consider the example from above: * * Sabqponm * abcryxxl * accszExk * acctuvwj * abdefghi * Now, there are six choices for starting position (five marked a, plus the square marked S that counts as being at elevation a). If you start at the bottom-left square, you can reach the goal most quickly: * * ...v<<<< * ...vv<<^ * ...v>E^^ * .>v>>>^^ * >^>>>>>^ * This path reaches the goal in only 29 steps, the fewest possible. * * What is the fewest steps required to move starting from any square with elevation a to the location that should get the best signal? * * Answer: * * * Although it hasn't changed, you can still get your puzzle input. * * You can also [Share] this puzzle.*/

Kotlin

29f9cb46955c0f371908996cc729742dc0387017

aoc-2022

Apache License 2.0

src/Day15.kt

AxelUser

{"Kotlin": 29744}

import kotlin.math.abs data class Day15Data(val scanner: Point<Long>, val beacon: Point<Long>, val distance: Long) fun main() { fun List<String>.parse(): List<Day15Data> { return this.map { Regex("-?\\d++").findAll(it).map { it.value.toLong() }.toList() .let { (x1, y1, x2, y2) -> Day15Data(Point(y1, x1), Point(y2, x2), abs(x1 - x2) + abs(y1 - y2)) } } } fun getRange(data: Day15Data, row: Long): LongArray { val xDiff = data.distance - abs(row - data.scanner.y) val start = data.scanner.x - xDiff val end = data.scanner.x + xDiff return longArrayOf(start, end) } fun getRanges(data: List<Day15Data>, row: Long): List<LongArray> { val ranges = data.asSequence() .filter { row in it.scanner.y - it.distance..it.scanner.y + it.distance } .map { getRange(it, row) } .sortedBy { it[0] } .toList() return ranges.fold(mutableListOf()) { acc, range -> acc.apply { if (isEmpty() || acc.last()[1] < range[0]) { add(range) } else if (acc.last()[1] >= range[0]) { acc.last()[1] = maxOf(acc.last()[1], range[1]) } } } } fun part1(data: List<Day15Data>, row: Long): Long { val sum = getRanges(data, row).sumOf { abs(it[1] - it[0]) + 1 } val beacons = data.map { it.beacon }.toSet().count { it.y == row } return sum - beacons } fun calcFreq(x: Long, y: Long): Long = x * 4_000_000 + y fun part2(data: List<Day15Data>, upperBound: Long): Long { for (row in 0..upperBound) { val ranges = getRanges(data, row) when { ranges.size == 1 && ranges[0][0] <= 0 && ranges[0][1] >= upperBound -> continue ranges.size == 1 && ranges[0][0] > 0 -> { return calcFreq(0, row) } ranges.size == 1 && ranges[0][1] < upperBound -> { return calcFreq(upperBound, row) } ranges.size == 2 -> { return calcFreq(ranges[0][1] + 1, row) } else -> error( "row:$row, ranges: ${ ranges.joinToString(prefix = "[", postfix = "]") { it.joinToString( prefix = "[", postfix = "]" ) } }" ) } } error("not found") } val testInput = readInput("Day15_test").parse() check(part1(testInput, 10) == 26L) check(part2(testInput, 20) == 56000011L) val input = readInput("Day15").parse() println(part1(input, 2_000_000)) println(part2(input, 4_000_000)) }

Kotlin

042e559f80b33694afba08b8de320a7072e18c4e

aoc-2022

Apache License 2.0

src/Day08.kt

wooodenleg

{"Kotlin": 30668}

data class Tree(val x: Int, val y: Int, val height: Int) fun makeForrest(input: List<String>): List<Tree> { val forrest = mutableListOf<Tree>() input.forEachIndexed { columnIndex, treeLine -> treeLine.forEachIndexed { rowIndex, height -> forrest.add(Tree(rowIndex, columnIndex, height.digitToInt())) } } return forrest } fun filterVisibleTreesInForest(forest: List<Tree>): Collection<Tree> { val rows = forest.rows() val columns = forest.columns() val treeLines = rows + rows.map(List<Tree>::asReversed) + columns + columns.map(List<Tree>::asReversed) return treeLines .flatMap(::filterVisibleTreesInTreeLine) .distinct() } fun filterVisibleTreesInTreeLine(line: List<Tree>): Collection<Tree> = buildList { var maxHeight = -1 for (tree in line) { if (tree.height > maxHeight) { add(tree) maxHeight = tree.height } } } fun List<Tree>.rows(): List<List<Tree>> = buildList { val rowsMap = this@rows.groupBy { it.y } for (key in rowsMap.keys) add(key, rowsMap.getValue(key)) } fun List<Tree>.columns(): List<List<Tree>> = buildList { val columnsMap = this@columns.groupBy { it.x } for (key in columnsMap.keys) add(key, columnsMap.getValue(key)) } fun List<Tree>.filterVisibleTreesFromHeightCount(height: Int): Int { var count = 0 for (tree in this) { count++ if (tree.height >= height) break } return count } fun Tree.scenicScore(row: List<Tree>, column: List<Tree>): Int { val rowIndex = row.indexOf(this) val columnIndex = column.indexOf(this) val left = row.subList(0, rowIndex).asReversed().filterVisibleTreesFromHeightCount(height) val right = row.subList(rowIndex + 1, row.size).filterVisibleTreesFromHeightCount(height) val top = column.subList(0, columnIndex).asReversed().filterVisibleTreesFromHeightCount(height) val bottom = column.subList(columnIndex + 1, column.size).filterVisibleTreesFromHeightCount(height) return left * right * top * bottom } fun main() { fun part1(input: List<String>): Int { val forrest = makeForrest(input) val visibleTrees = filterVisibleTreesInForest(forrest) return visibleTrees.count() } fun part2(input: List<String>): Int { val forest = makeForrest(input) val columns = forest.columns() val rows = forest.rows() var maxScore = 0 repeat(input.first().length) { x -> repeat(input.size) { y -> val tree = columns[x][y] val score = tree.scenicScore(rows[y], columns[x]) if (score > maxScore) maxScore = score } } return maxScore } val testInput = readInputLines("Day08_test") check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInputLines("Day08") println(part1(input)) println(part2(input)) }

Kotlin

ff1f3198f42d1880e067e97f884c66c515c8eb87

advent-of-code-2022

Apache License 2.0

src/Day18.kt

mjossdev

{"Kotlin": 81859}

fun main() { data class Cube(val x: Int, val y: Int, val z: Int) { override fun toString(): String = "$x,$y,$z" } fun Cube.adjacents() = listOf( copy(x = x + 1), copy(x = x - 1), copy(y = y + 1), copy(y = y - 1), copy(z = z + 1), copy(z = z - 1) ) fun readCubes(input: List<String>): List<Cube> = input.map { line -> line.split(',').map { it.toInt() }.let { (x, y, z) -> Cube(x, y, z) } }.distinct() fun getGrid(cubes: Iterable<Cube>): Array<Array<BooleanArray>> { val width = cubes.maxOf { it.x } + 1 val height = cubes.maxOf { it.y } + 1 val depth = cubes.maxOf { it.z } + 1 val grid = Array(width) { Array(height) { BooleanArray(depth) } } for ((x, y, z) in cubes) { grid[x][y][z] = true } return grid } fun part1(input: List<String>): Int { val cubes = readCubes(input) val grid = getGrid(cubes) val width = grid.size val height = grid[0].size val depth = grid[0][0].size return cubes.sumOf { (x, y, z) -> var sides = 6 if (x > 0 && grid[x - 1][y][z]) --sides if (x < width - 1 && grid[x + 1][y][z]) --sides if (y > 0 && grid[x][y - 1][z]) --sides if (y < height - 1 && grid[x][y + 1][z]) --sides if (z > 0 && grid[x][y][z - 1]) --sides if (z < depth - 1 && grid[x][y][z + 1]) --sides sides } } fun part2(input: List<String>): Int { val cubes = readCubes(input) val grid = getGrid(cubes) val width = grid.size val height = grid[0].size val depth = grid[0][0].size fun Cube.isAir() = !(grid.elementAtOrNull(x)?.elementAtOrNull(y)?.elementAtOrNull(z) ?: false) fun countReachableSides(cube: Cube): Int = cube.adjacents().filter { it.isAir() }.count { start -> val queue = ArrayDeque<Cube>() val explored = mutableSetOf(start) queue.addLast(start) while (queue.isNotEmpty()) { val next = queue.removeFirst() if (next.run { x == 0 || x == width - 1 || y == 0 || y == height - 1 || z == 0 || z == depth - 1 }) { return@count true } next.adjacents().filter { it.isAir() && it !in explored }.forEach { explored.add(it) queue.addLast(it) } } false } return cubes.sumOf { countReachableSides(it) } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day18_test") check(part1(testInput) == 64) check(part2(testInput) == 58) val input = readInput("Day18") println(part1(input)) println(part2(input)) }

Kotlin

afbcec6a05b8df34ebd8543ac04394baa10216f0

advent-of-code-22

Apache License 2.0

src/Day08.kt

Ajimi

{"Kotlin": 11228}

fun main() { fun part1(input: List<List<Int>>): Int { val height = input.size val width = input.first().size fun isVisibleFromOutside(row: Int, column: Int, direction: Direction): Boolean { val treeHeight = input[row][column] return input.treesByDirection(row, column, direction).all { it < treeHeight } } var count = (height + width - 2) * 2 (1 until height - 1).forEach { row -> (1 until width - 1) .asSequence() .filter { column -> Direction.values().any { isVisibleFromOutside(row, column, it) } } .forEach { count++ } } return count } fun part2(input: List<List<Int>>): Int { val height = input.size val width = input.first().size fun countVisibleTrees(r: Int, c: Int, direction: Direction): Int { val targetTree = input[r][c] var count = 0 input.treesByDirection(r, c, direction).forEach { currentTree -> count++ if (currentTree >= targetTree) return count } return count } var maxScore = 0 (1 until height - 1).forEach { row -> (1 until width - 1) .asSequence() .map { column -> Direction.values().map { countVisibleTrees(row, column, it) }.reduce(Int::times) } .forEach { maxScore = maxOf(it, maxScore) } } return maxScore } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test").toMatrix() part1(testInput) check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInput("Day08").toMatrix() println(part1(input)) println(part2(input)) } private fun List<String>.toMatrix() = map { line -> line.map { Character.getNumericValue(it) } } enum class Direction(val dr: Int = 0, val dc: Int = 0) { UP(dr = -1), LEFT(dc = -1), DOWN(dr = +1), RIGHT(dc = +1); fun next(coordinates: Pair<Int, Int>): Pair<Int, Int> { val (row, column) = coordinates return (row + dr) to (column + dc) } } private fun List<List<Int>>.treesByDirection( row: Int, column: Int, direction: Direction, ): Sequence<Int> = generateSequence(direction.next(row to column), direction::next) .takeWhile { (r, c) -> r in indices && c in first().indices } .map { (r, c) -> this[r][c] }

Kotlin

8c2211694111ee622ebb48f52f36547fe247be42

adventofcode-2022

Apache License 2.0

src/Day16.kt

sabercon

fun main() { data class Rule(val name: String, val range1: IntRange, val range2: IntRange) fun validRules(value: Int, rules: Set<Rule>): Set<Rule> { return rules.filter { (_, range1, range2) -> value in range1 || value in range2 }.toSet() } fun buildRuleMap(candidates: List<Pair<Int, Set<Rule>>>): Map<Int, Rule> { if (candidates.isEmpty()) return emptyMap() val (index, rules) = candidates.minBy { (_, rules) -> rules.size } val rule = rules.single() return candidates.map { (i, rs) -> i to (rs - rule) } .filter { (_, rs) -> rs.isNotEmpty() } .let { buildRuleMap(it) } .plus(index to rule) } fun buildRuleMap(rules: Set<Rule>, tickets: List<List<Int>>): Map<Int, Rule> { return rules.indices .map { it to tickets.fold(rules) { acc, t -> acc intersect validRules(t[it], rules) } } .let { buildRuleMap(it) } } val input = readText("Day16") val (rulesStr, myStr, nearbyStr) = """(.+)\n\nyour ticket:\n(.+)\n\nnearby tickets:\n(.+)""" .toRegex(RegexOption.DOT_MATCHES_ALL).destructureGroups(input) val rules = rulesStr.lines().map { val (name, f1, l1, f2, l2) = """(.+): (\d+)-(\d+) or (\d+)-(\d+)""".toRegex().destructureGroups(it) Rule(name, f1.toInt()..(l1.toInt()), f2.toInt()..(l2.toInt())) }.toSet() val myTicket = myStr.split(",").map { it.toInt() } val nearbyTickets = nearbyStr.lines().map { line -> line.split(",").map { it.toInt() } } nearbyTickets.flatten().filter { validRules(it, rules).isEmpty() }.sum().println() val validTickets = nearbyTickets.filter { line -> line.all { validRules(it, rules).isNotEmpty() } } val ruleMap = buildRuleMap(rules, validTickets) myTicket.filterIndexed { i, _ -> ruleMap[i]!!.name.startsWith("departure") } .fold(1L) { acc, v -> acc * v }.println() }

Kotlin

81b51f3779940dde46f3811b4d8a32a5bb4534c8

advent-of-code-2020

MIT License

2k23/aoc2k23/src/main/kotlin/19.kt

papey

{"Rust": 88237, "Kotlin": 63321, "Elixir": 54197, "Crystal": 47654, "Go": 44755, "Ruby": 24620, "Python": 23868, "TypeScript": 5612, "Scheme": 117}

package d19 fun main() { val (workflows, ratings) = input.raw("19.txt").split("\n\n").let { val workflows = it[0].split("\n") .map { line -> Workflow(line) }.associateBy { workflow -> workflow.id } val ratings = it[1].split("\n") .filter { line -> line.isNotBlank() } .map { rating -> Rating(rating) } workflows to ratings } println("Part 1: ${part1(workflows, ratings)}") println("Part 2: ${part2(workflows)}") } fun part1(workflows: Map<String, Workflow>, ratings: List<Rating>): Int { return ratings.filter { rating -> var res = workflows["in"]!!.run(rating) while (res != "A" && res != "R") { res = workflows[res]!!.run(rating) } res == "A" }.sumOf { it.sum() } } fun part2(workflows: Map<String, Workflow>): Long { return combinations( "in", workflows, mapOf( Rating.RatingKey.X to 1..4000, Rating.RatingKey.M to 1..4000, Rating.RatingKey.A to 1..4000, Rating.RatingKey.S to 1..4000 ) ) } fun combinations(id: String, workflows: Map<String, Workflow>, ranges: Map<Rating.RatingKey, IntRange>): Long = when (id) { "R" -> 0L "A" -> { ranges.values.map { it.count().toLong() }.reduce(Long::times) } else -> { val newRanges = ranges.toMap().toMutableMap() workflows[id]!!.steps.sumOf { step -> when (step) { is Workflow.SimpleStep -> { combinations(step.target(), workflows, newRanges) } is Workflow.ConditionalStep -> { when (step.operand) { Workflow.ConditionalStep.Operand.LessThan -> { val currentRange = newRanges[step.source]!! newRanges[step.source] = currentRange.first..<step.value combinations(step.target(), workflows, newRanges).also { newRanges[step.source] = step.value..currentRange.last } } Workflow.ConditionalStep.Operand.MoreThan -> { val currentRange = newRanges[step.source]!! newRanges[step.source] = step.value + 1..currentRange.last combinations(step.target(), workflows, newRanges).also { newRanges[step.source] = currentRange.first..step.value } } } } else -> { throw IllegalStateException("oops") } } } } } class Rating(input: String) { private val ratingsRegex = Regex("""\w=(\d+)""") val values: Map<RatingKey, Int> init { val rates = ratingsRegex.findAll(input).map { rate -> rate.groupValues[1] }.map { number -> number.toInt() }.toList() values = mapOf( RatingKey.X to rates[0], RatingKey.M to rates[1], RatingKey.A to rates[2], RatingKey.S to rates[3] ) } fun sum(): Int = values.values.sum() enum class RatingKey { X, M, A, S; companion object { fun fromString(input: String): RatingKey = when (input) { "x" -> X "m" -> M "a" -> A "s" -> S else -> throw IllegalStateException("oops") } } } } class Workflow(input: String) { private val workflowRegex = Regex("""(\w+)\{(.*)}""") val steps: List<StepRunner> val id: String init { val matches = workflowRegex.find(input) id = matches!!.groupValues[1] steps = matches.groupValues[2].split(",").map { rawStep -> if (rawStep.contains(":")) { ConditionalStep(rawStep) } else { SimpleStep(rawStep) } } } fun run(rating: Rating): String { return steps.find { step -> step.predicate(rating) }!!.target() } interface StepRunner { fun target(): String fun predicate(rating: Rating): Boolean } class SimpleStep(private val target: String) : StepRunner { override fun target(): String = target override fun predicate(rating: Rating): Boolean = true } class ConditionalStep(input: String) : StepRunner { private val stepRegex = Regex("""([xmas])([<>])(\d+):(\w+)""") enum class Operand { LessThan, MoreThan; companion object { fun fromString(input: String): Operand = when (input) { ">" -> MoreThan "<" -> LessThan else -> throw IllegalStateException("oops") } } } private val target: String val value: Int val source: Rating.RatingKey val operand: Operand init { val matches = stepRegex.find(input) source = Rating.RatingKey.fromString(matches!!.groupValues[1]) operand = Operand.fromString(matches.groupValues[2]) value = matches.groupValues[3].toInt() target = matches.groupValues.last() } override fun target(): String = target override fun predicate(rating: Rating): Boolean = when (operand) { Operand.LessThan -> rating.values[source]!! < value Operand.MoreThan -> rating.values[source]!! > value } } }

Rust

cb0ea2fc043ebef75aff6795bf6ce8a350a21aa5

aoc

The Unlicense

src/Day22/Day22.kt

martin3398

{"Kotlin": 63436, "Python": 5921}

import java.lang.Long.max import java.lang.Long.min data class Cube(val x: Pair<Long, Long>, val y: Pair<Long, Long>, val z: Pair<Long, Long>) { fun inSmallerCube() = x.first >= -50 && x.second <= 50 && y.first >= -50 && y.second <= 50 && z.first >= -50 && z.second <= 50 } fun Cube.intersect(other: Cube): Cube? { val minX = min(x.second, other.x.second) val maxX = max(x.first, other.x.first) val minY = min(y.second, other.y.second) val maxY = max(y.first, other.y.first) val minZ = min(z.second, other.z.second) val maxZ = max(z.first, other.z.first) if (maxX > minX || maxY > minY || maxZ > minZ) { return null } return Cube(Pair(maxX, minX), Pair(maxY, minY), Pair(maxZ, minZ)) } fun Cube.volume() = (x.second - x.first + 1) * (y.second - y.first + 1) * (z.second - z.first + 1) fun main() { fun preprocess(input: List<String>): List<Pair<Boolean, Cube>> { fun parseCube(s: String): Pair<Boolean, Cube> { val split = s.split(" ") val onOff = split[0] == "on" val pos = split[1].split(",") .map { it.split("=")[1].split("..").map { x -> x.toLong() }.zipWithNext()[0] } return Pair(onOff, Cube(pos[0], pos[1], pos[2])) } return input.map { parseCube(it) } } fun calc(input: List<Pair<Boolean, Cube>>): Long { var parts: Map<Cube, Long> = HashMap() for ((onOff, cube) in input) { val add = HashMap<Cube, Long>() if (onOff) { add[cube] = 1 } for ((part, count) in parts) { val intersection = cube.intersect(part) if (intersection != null) { add[intersection] = add.getOrDefault(intersection, 0) - count } } parts = (parts.asSequence() + add.asSequence()) .distinct() .groupBy({ it.key }, { it.value }) .mapValues { it.value.sum() } } return parts.map { it.key.volume() * it.value }.sum() } fun part1(input: List<Pair<Boolean, Cube>>): Long { return calc(input.filter { it.second.inSmallerCube() }) } fun part2(input: List<Pair<Boolean, Cube>>): Long { return calc(input) } val testInput = preprocess(readInput(22, true)) val input = preprocess(readInput(22)) check(part1(testInput) == 474140L) println(part1(input)) check(part2(testInput) == 2758514936282235L) println(part2(input)) }

Kotlin

085b1f2995e13233ade9cbde9cd506cafe64e1b5

advent-of-code-2021

Apache License 2.0

src/main/kotlin/Path.kt

alebedev

{"Kotlin": 82424}

fun main() = Path.solve() private typealias Matrix = List<List<Int>> private object Path { const val START = 0 const val TARGET = ('z'.code - 'a'.code) + 1 fun solve() { val input = readInput() val starts = findAll(input, START) val target = findAll(input, TARGET).first() val graph = buildGraph(input) println("Shorted max elevation path: ${starts.map { shortestPath(graph, it, target) }.filter { it > 0 }.min()}") } private fun readInput(): Matrix { return generateSequence(::readLine).map { it.splitToSequence("").filter { !it.isEmpty() }.map { when (val char = it.first()) { in 'a'..'z' -> char.code - 'a'.code 'S' -> START 'E' -> TARGET else -> throw Error("Unexpected input char $char") } }.toList() }.toList() } private fun findAll(matrix: Matrix, target: Int): List<Pos> { val result = mutableListOf<Pos>() for (y in matrix.indices) { for (x in matrix[y].indices) { if (matrix[y][x] == target) { result.add(Pos(x, y)) } } } return result } private fun buildGraph(matrix: Matrix): Map<Pos, Node> { val height = matrix.size val width = matrix.first().size fun neighbours(pos: Pos) = listOf( Pos(pos.x - 1, pos.y), Pos(pos.x + 1, pos.y), Pos(pos.x, pos.y - 1), Pos(pos.x, pos.y + 1) ).filter { it.x in 0 until width && it.y in 0 until height } val result = mutableMapOf<Pos, Node>() for (y in matrix.indices) { for (x in matrix[y].indices) { val pos = Pos(x, y) val node = result.getOrPut(pos) { Node(pos, matrix[y][x]) } for (nPos in neighbours(pos)) { val nNode = result.getOrPut(nPos) { Node(nPos, matrix[nPos.y][nPos.x]) } if (nNode.height <= node.height + 1) { node.edges.add(nPos) } } } } return result } private fun shortestPath(graph: Map<Pos, Node>, start: Pos, target: Pos): Int { val paths = mutableMapOf<Pos, Int>() val queue = mutableListOf(Pair(start, 0)) while (queue.size > 0) { val (pos, pathLen) = queue.removeAt(0) if (pos in paths) continue paths[pos] = pathLen for (edge in graph[pos]!!.edges) { if (edge in paths) continue if (edge == target) { return pathLen + 1 } queue.add(Pair(edge, pathLen + 1)) } } return -1 } data class Pos(val x: Int, val y: Int) data class Node(val pos: Pos, val height: Int, val edges: MutableList<Pos> = mutableListOf()) }

Kotlin

d6ba46bc414c6a55a1093f46a6f97510df399cd1

aoc2022

MIT License

2023/src/day07/day07.kt

Bridouille

{"Kotlin": 171124, "Go": 37047}

package day07 import GREEN import RESET import printTimeMillis import readInput data class CamelCards( val hand: String, val occurences: Map<Char, Int>, val occurencesWithJoker: Map<Char, Int>, val bid: Int ) private fun typeScore(occurences: Map<Char, Int>): Int { if (occurences.values.contains(5)) return 1_000_000 // Five of a kind if (occurences.values.contains(4)) return 100_000 // Four of a kind if (occurences.values.contains(3)) { if (occurences.values.contains(2)) return 10_000 // Full house return 1_000 // Three of a kind } val nbPairs = occurences.values.filter { it == 2 }.size if (nbPairs == 2) return 100 // Two pairs if (nbPairs == 1) return 10 // One pair return 1 // High card } private fun List<String>.toCards(): List<CamelCards> = map { str -> val occurences = str.split(" ")[0].groupingBy { it }.eachCount() val occurencesWithJoker = buildList { // Replace each 'J' card with a potential card // Calculate the score and sort them to get the best possible score listOf('A', 'K', 'Q', 'T', '9', '8', '7', '6', '5', '4', '3', '2').forEach { val replaced = str.split(" ")[0].replace('J', it) add(replaced.groupingBy { it }.eachCount()) } } .distinct() .sortedByDescending { typeScore(it) } .first() CamelCards( str.split(" ")[0], occurences, occurencesWithJoker, str.split(" ")[1].toInt() ) } private fun sortCards( cards: List<CamelCards>, withJokers: Boolean ): List<CamelCards> { val cardScore = if (withJokers) { mapOf( 'A' to 13, 'K' to 12, 'Q' to 11, 'T' to 10, '9' to 9, '8' to 8, '7' to 7, '6' to 6, '5' to 5, '4' to 4, '3' to 3, '2' to 2, 'J' to 1, ) } else { mapOf( 'A' to 13, 'K' to 12, 'Q' to 11, 'J' to 10, 'T' to 9, '9' to 8, '8' to 7, '7' to 6, '6' to 5, '5' to 4, '4' to 3, '3' to 2, '2' to 1 ) } val c = Comparator<CamelCards> { a, b -> val scoreA = typeScore(if (withJokers) a.occurencesWithJoker else a.occurences) val scoreB = typeScore(if (withJokers) b.occurencesWithJoker else b.occurences) if (scoreA == scoreB) { // Same type, compare card by card for (i in 0 until 5) { if (a.hand[i] != b.hand[i]) { return@Comparator cardScore[a.hand[i]]!! - cardScore[b.hand[i]]!! } } } scoreA - scoreB } return cards.sortedWith(c) } fun part1(input: List<String>): Int { val sorted = sortCards(input.toCards(), withJokers = false) return sorted.mapIndexed { index, camelCards -> (index + 1) * camelCards.bid }.sum() } fun part2(input: List<String>): Int { val sorted = sortCards(input.toCards(), withJokers = true) return sorted.mapIndexed { index, camelCards -> (index + 1) * camelCards.bid }.sum() } fun main() { val testInput = readInput("day07_example.txt") printTimeMillis { print("part1 example = $GREEN" + part1(testInput) + RESET) } printTimeMillis { print("part2 example = $GREEN" + part2(testInput) + RESET) } val input = readInput("day07.txt") printTimeMillis { print("part1 input = $GREEN" + part1(input) + RESET) } printTimeMillis { print("part2 input = $GREEN" + part2(input) + RESET) } }

Kotlin

8ccdcce24cecca6e1d90c500423607d411c9fee2

advent-of-code

Apache License 2.0

src/Day07.kt

palex65

{"Kotlin": 68582}

sealed class Entry(val name: String) class File(name: String, val size: Int): Entry(name) { override fun toString() = "File($name,$size)" } class Dir(name: String, val parent: Dir?, var entries: List<Entry> = emptyList(), var size: Int=0): Entry(name) { override fun toString() = "Dir($name,$size {$entries} )" fun processSize() { size = entries.sumOf { when (it) { is Dir -> { it.processSize(); it.size} is File -> it.size } } } fun allSizes(): List<Int> { val dirs: List<Dir> = entries.filterIsInstance<Dir>() return if (dirs.isEmpty()) listOf(size) else dirs.map { it.allSizes() }.flatten() + size } } fun processCommands(cmds: List<Command>): Dir { val root = Dir("/",null) var dir = root for (cmd in cmds) { when(cmd) { is LS -> dir.entries = cmd.entries.map { val (a,b) = it.split(' ') if (a=="dir") Dir(b,dir) else File(b,a.toInt()) } is CD -> dir = if (cmd.name=="..") dir.parent!! else dir.entries.first { cmd.name == it.name } as Dir } } return root } sealed class Command() class CD(val name: String) : Command() class LS(val entries: List<String>) : Command() fun List<String>.toCommands(): List<Command> { val lst = mutableListOf<Command>() var idx = 0 while (idx < size) { val cmd = this[idx++].substring(2).split(' ') when( cmd[0] ) { "ls" -> { var idxLast = idx while (idxLast < size && this[idxLast][0]!='$') ++idxLast lst.add( LS(subList(idx, idxLast) ) ) idx = idxLast } "cd" -> lst.add( CD( cmd[1] ) ) } } return lst } private fun part1(lines: List<String>): Int { val root = processCommands(lines.toCommands().drop(1)) root.processSize() return root.allSizes().sumOf { if (it<=100000) it else 0 } } private fun part2(lines: List<String>): Int { val root = processCommands(lines.toCommands().drop(1)) root.processSize() val toFree = 30000000 - (70000000-root.size) val allSizes = root.allSizes().sorted() return allSizes.first { it >= toFree } } fun main() { val testInput = readInput("Day07_test") check(part1(testInput) == 95437) check(part2(testInput) == 24933642) // 8381165 val input = readInput("Day07") println(part1(input)) // 306611 println(part2(input)) // 13210366 }

Kotlin

35771fa36a8be9862f050496dba9ae89bea427c5

aoc2022

Apache License 2.0

src/year2023/day07/Day07.kt

lukaslebo

{"Kotlin": 222221}

package year2023.day07 import check import readInput import kotlin.math.pow fun main() { val testInput = readInput("2023", "Day07_test") check(part1(testInput), 6440) check(part2(testInput), 5905) val input = readInput("2023", "Day07") println(part1(input)) println(part2(input)) } private fun part1(input: List<String>): Int { return input.map { it.toHand() } .sortedWith(compareBy<Hand> { it.type }.thenBy { it.strength }) .mapIndexed { index, hand -> (index + 1) * hand.bid } .sum() } private fun part2(input: List<String>): Int { return input.map { it.toHand(withJokers = true) } .sortedWith(compareBy<Hand> { it.type }.thenBy { it.strength }) .mapIndexed { index, hand -> (index + 1) * hand.bid } .sum() } private data class Hand( val cards: String, val bid: Int, val type: Int, val strength: Int, ) private fun String.toHand(withJokers: Boolean = false): Hand { val (cards, bid) = split(" ") return Hand(cards, bid.toInt(), cards.getType(withJokers), cards.getStrength(withJokers)) } private fun String.getType(withJokers: Boolean = false): Int { val jokers = count { it == 'J' && withJokers } val groups = groupBy { it }.filter { it.key != 'J' || !withJokers }.map { it.value.size } val maxGroup = groups.maxOrNull() ?: 0 val pairs = groups.count { it == 2 } return when { maxGroup + jokers == 5 -> 7 maxGroup + jokers == 4 -> 6 (maxGroup == 3 && pairs == 1) || (pairs == 2 && jokers == 1) -> 5 maxGroup + jokers == 3 -> 4 pairs == 2 -> 3 maxGroup + jokers == 2 -> 2 else -> 1 } } private fun String.getStrength(withJokers: Boolean): Int { return reversed().mapIndexed { i, c -> val points = if (withJokers) cardsWithJokers.indexOf(c) else cards.indexOf(c) (points + 1) * 13.0.pow(i).toInt() }.sum() } private const val cardsWithJokers = "J23456789TQKA" private const val cards = "23456789TJQKA"

Kotlin

f3cc3e935bfb49b6e121713dd558e11824b9465b

AdventOfCode

Apache License 2.0

src/day07/Day07.kt

pnavais

{"Kotlin": 17859}

package day07 import readInput val cardValueMapping = mapOf('2' to 2, '3' to 3, '4' to 4, '5' to 5, '6' to 6, '7' to 7, '8' to 8, '9' to 9, 'T' to 10, 'J' to 11, 'Q' to 12, 'K' to 13, 'A' to 14) enum class Type(val value: Int) { FIVE_OF_A_KIND(7), FOUR_OF_A_KIND(6), FULL_HOUSE(5), THREE_OF_A_KIND(4), TWO_PAIR(3), ONE_PAIR(2), HIGH_CARD(1), WRONG_CARDS(0); companion object { fun fromCards(cards: String, useJokers: Boolean = false) : Type { val cardsProcessed = if (useJokers) { translateJokers(cards) } else cards val cardGroups = cardsProcessed.groupingBy { it }.eachCount() return when (cardGroups.size) { 5 -> HIGH_CARD 4 -> ONE_PAIR 3 -> if (cardGroups.maxBy { it.value }.value == 3) THREE_OF_A_KIND else TWO_PAIR // 3, 1, 1 or 2, 2, 1 2 -> if (cardGroups.maxBy { it.value }.value == 4) FOUR_OF_A_KIND else FULL_HOUSE // 4, 1 or 3, 2 1 -> FIVE_OF_A_KIND else -> WRONG_CARDS } } private fun translateJokers(cards: String): String { return if (cards != "JJJJJ") { // Transform jokers into the highest grouped card val maxCard = cards.replace("J", "").groupingBy { it }.eachCount() .map { it.value to it.key }.groupBy { it.first }.maxBy { it.key } .value .map { it.second } .sortedWith(Comparator { o1, o2 -> cardValueMapping[o2]?.compareTo(cardValueMapping[o1] ?: -1)!! })[0] cards.replace('J', maxCard) } else { cards } } } } data class Hand(val cards: String, val bid: Long, val useJokers: Boolean = false): Comparable<Hand> { private val type : Type = Type.fromCards(cards, useJokers) override fun compareTo(other: Hand): Int { var res = type.compareTo(other.type) // Compare equal hands by pos value if (res == 0) { for (i in 0..other.cards.length) { val aux = getCardValue(other.cards[i], useJokers)?.compareTo(getCardValue(cards[i], useJokers) ?: -1)!! if (aux != 0) { res = aux break } } } return res } private fun getCardValue(card: Char, useJokers: Boolean): Int? { return if ((useJokers) && (card == 'J')) { 1 } else { cardValueMapping[card] } } } fun part1(input: List<String>): Long { return input.map { s -> val (cards, bid) = s.split(" "); Hand(cards, bid.toLong()) } .sortedDescending() .mapIndexed { index,hand -> hand.bid.times(index+1) } .sum() } fun part2(input: List<String>): Long { return input.map { s -> val (cards, bid) = s.split(" "); Hand(cards, bid.toLong(), useJokers = true) } .sortedDescending() .mapIndexed { index,hand -> hand.bid.times(index+1) } .sum() } fun main() { val testInput = readInput("input/day07") println(part1(testInput)) println(part2(testInput)) }

Kotlin

f5b1f7ac50d5c0c896d00af83e94a423e984a6b1

advent-of-code-2k3

Apache License 2.0

src/Day12.kt

coolcut69

{"Kotlin": 36853}

import java.util.* fun main() { fun part1(input: List<String>): Int { val heightMap = parseInput(input) return heightMap.shortestPath( begin = heightMap.start, isGoal = { it == heightMap.end }, canMove = { from, to -> to - from <= 1 }) } fun part2(input: List<String>): Int { val heightMap = parseInput(input) return heightMap.shortestPath( begin = heightMap.end, isGoal = { heightMap.elevations[it] == 0 }, canMove = { from, to -> from - to <= 1 }) } // test if implementation meets criteria from the description, like: val testInput = readInput("Day12_test") check(part1(testInput) == 31) check(part2(testInput) == 29) val input = readInput("Day12") println(part1(input)) check(part1(input) == 394) println(part2(input)) check(part2(input) == 388) } private class HeightMap(val elevations: Map<Point2D, Int>, val start: Point2D, val end: Point2D) { fun shortestPath( begin: Point2D, isGoal: (Point2D) -> Boolean, canMove: (Int, Int) -> Boolean ): Int { val seen = mutableSetOf<Point2D>() val queue = PriorityQueue<PathCost>().apply { add(PathCost(begin, 0)) } while (queue.isNotEmpty()) { val nextPoint = queue.poll() if (nextPoint.point !in seen) { seen += nextPoint.point val neighbors = nextPoint.point.cardinalNeighbors() .filter { it in elevations } .filter { canMove(elevations.getValue(nextPoint.point), elevations.getValue(it)) } if (neighbors.any { isGoal(it) }) return nextPoint.cost + 1 queue.addAll(neighbors.map { PathCost(it, nextPoint.cost + 1) }) } } throw IllegalStateException("No valid path from $start to $end") } } data class Point2D(val x: Int = 0, val y: Int = 0) { fun cardinalNeighbors(): Set<Point2D> = setOf( copy(x = x - 1), copy(x = x + 1), copy(y = y - 1), copy(y = y + 1) ) } private fun parseInput(input: List<String>): HeightMap { var start: Point2D? = null var end: Point2D? = null val elevations = input.flatMapIndexed { y, row -> row.mapIndexed { x, char -> val here = Point2D(x, y) here to when (char) { 'S' -> 0.also { start = here } 'E' -> 25.also { end = here } else -> char - 'a' } } }.toMap() return HeightMap(elevations, start!!, end!!) } private data class PathCost(val point: Point2D, val cost: Int) : Comparable<PathCost> { override fun compareTo(other: PathCost): Int = this.cost.compareTo(other.cost) }

Kotlin

031301607c2e1c21a6d4658b1e96685c4135fd44

aoc-2022-in-kotlin

Apache License 2.0

src/Day19.kt

amelentev

{"Kotlin": 87839}

fun main() { val input = readInput("Day19") data class Rule(val c: Char, val cmp: Char, val v: Int, val to: String) data class Workflow(val name: String, val rules: List<Rule>, val elseTo: String) val workflows = input.take(input.indexOfFirst { it.isEmpty() }).map { val name = it.substringBefore('{') val rules = it.substringAfter('{').substringBefore('}').split(",") Workflow( name = name, rules = rules.dropLast(1).map { rule -> Rule( c = rule[0], cmp = rule[1], v = rule.substring(2).substringBefore(':').toInt(), to = rule.substringAfter(':') ) }, elseTo = rules.last() ) }.associateBy { it.name } val parts = input.drop(input.indexOfFirst { it.isEmpty() }+1).map { part -> part.trim('{', '}').split(',').associate { it[0] to it.substring(2).toLong() } } fun process(part: Map<Char, Long>, w: Workflow): String { for (r in w.rules) { var diff = part[r.c]!! - r.v if (r.cmp == '<') diff = -diff if (diff > 0) return r.to } return w.elseTo } fun solve1(part: Map<Char, Long>): Boolean { var w = workflows["in"]!! while (true) { val next = process(part, w) when (next) { "A" -> return true "R" -> return false } w = workflows[next]!! } } var res1 = 0L for (part in parts) { if (solve1(part)) { res1 += part.values.sum() } } println(res1) var res2 = 0L fun dfs(workflow: String, range: Map<Char, Pair<Int, Int>>) { if (workflow == "A") { res2 += range.values.fold(1L) { a, x -> a * (x.second - x.first + 1) } return } else if (workflow == "R" || range.values.any { it.first > it.second }) { return } val w = workflows[workflow]!! var r = range for (rule in w.rules) { val (x1, x2) = r[rule.c]!! val (rt,rf) = if (rule.cmp == '<') { (x1 to minOf(x2, rule.v-1)) to (maxOf(minOf(x2, rule.v-1)+1, x1) to x2) } else { (maxOf(x1, rule.v+1) to x2) to (x1 to minOf(maxOf(x1, rule.v+1)-1, x2)) } dfs(rule.to, r + mapOf(rule.c to rt)) r = r + mapOf(rule.c to rf) } dfs(w.elseTo, r) } dfs("in", mapOf( 'x' to (1 to 4000), 'm' to (1 to 4000), 'a' to (1 to 4000), 's' to (1 to 4000), )) println(res2) }

Kotlin

a137d895472379f0f8cdea136f62c106e28747d5

advent-of-code-kotlin

Apache License 2.0

src/day05/Day05.kt

mherda64

{"Kotlin": 10058}

package day05 import readInput fun main() { val pattern = Regex("(\\d*),(\\d*) -> (\\d*),(\\d*)") fun processInput(input: List<String>): List<Pair<Point, Point>> { return input.map { val (x1, y1, x2, y2) = pattern.find(it)!!.destructured Pair(Point(x1.toInt(), y1.toInt()), Point(x2.toInt(), y2.toInt())) } } fun part1(input: List<Pair<Point, Point>>): Int { val max = input.maxOf { maxOf(maxOf(it.first.x, it.first.y), maxOf(it.second.x, it.second.y)) } val map = Map(max + 1) map.mark(input.filter { (first, second) -> first.x == second.x || first.y == second.y }) return map.countOverlapping() } fun part2(input: List<Pair<Point, Point>>): Int { val max = input.maxOf { maxOf(maxOf(it.first.x, it.first.y), maxOf(it.second.x, it.second.y)) } val map = Map(max + 1) map.mark(input) return map.countOverlapping() } val testInput = readInput("Day05_test") check(part1(processInput(testInput)) == 5) check(part2(processInput(testInput)) == 12) val input = readInput("Day05") println(part1(processInput(input))) println(part2(processInput(input))) } class Map(val size: Int) { val map: Array<Array<Int>> = Array(size) { Array(size) { 0 } } fun mark(pairs: List<Pair<Point, Point>>) { pairs.map { (first, second) -> when { first.x == second.x -> (if (first.y > second.y) first.y downTo second.y else first.y..second.y) .map { map[first.x][it] += 1 } first.y == second.y -> (if (first.x > second.x) first.x downTo second.x else first.x..second.x) .map { map[it][first.y] += 1 } else -> { val xRange = if (first.x > second.x) first.x downTo second.x else first.x..second.x val yRange = if (first.y > second.y) first.y downTo second.y else first.y..second.y xRange.zip(yRange).map { map[it.first][it.second] += 1 } } } } } fun countOverlapping(): Int { var counter = 0 for ((rowIndex, row) in map.withIndex()) { for (column in row.indices) { counter += if (map[rowIndex][column] > 1) 1 else 0 } } return counter } } data class Point(val x: Int, val y: Int)

Kotlin

d04e179f30ad6468b489d2f094d6973b3556de1d

AoC2021_kotlin

Apache License 2.0

src/main/kotlin/days/y2023/day23/Day23.kt

jewell-lgtm

{"Kotlin": 161272, "Jupyter Notebook": 103410, "TypeScript": 78635, "JavaScript": 123}

package days.y2023.day23 import util.InputReader class Day23(val input: List<String>) { private val start = Position(0, input.first().indexOfOnly('.')) private val end = Position(input.size - 1, input.last().indexOfOnly('.')) private val neighbors = input.flatMapIndexed { y, row -> row.indices.map { x -> Position(y, x) to input.neighbors(Position(y, x)) } }.toMap() private val cells = input.flatMapIndexed { y, row -> row.indices.map { x -> Position(y, x) to row[x] } }.toMap() fun partOne(): Int = longestPath(true, start, setOf(start)) fun partTwo(): Int = longestPath(false, start, setOf(start)) private fun longestPath(slipperyHills: Boolean, from: Position, visited: Set<Position>): Int { if (from == end) return visited.size - 1 val unvisited = from.neighbors().filter { it !in visited } if (unvisited.isEmpty()) return -1 return if (!slipperyHills) { unvisited.maxOfOrNull { longestPath(false, it, visited + it) } ?: -1 } else { unvisited.mapNotNull { next -> when (cells.getValue(next)) { '.' -> longestPath(true, next, visited + next) '>' -> if (next.right() !in visited) longestPath( true, next.right(), visited + next + next.right() ) else null '<' -> if (next.left() !in visited) longestPath( true, next.left(), visited + next + next.left() ) else null '^' -> if (next.up() !in visited) longestPath( true, next.up(), visited + next + next.up() ) else null 'v' -> if (next.down() !in visited) longestPath( true, next.down(), visited + next + next.down() ) else null else -> null } }.max() } } data class Position(val y: Int, val x: Int) private fun String.indexOfOnly(char: Char): Int { require(count { it == char } == 1) { "The character $char should only appear once." } return indexOf(char) } private fun Position.neighbors(): Set<Position> = neighbors.getValue(this) private fun Position.down() = copy(y = y + 1) private fun Position.up() = copy(y = y - 1) private fun Position.left() = copy(x = x - 1) private fun Position.right() = copy(x = x + 1) private fun List<String>.neighbors(position: Position): Set<Position> { return listOf( position.up(), position.down(), position.left(), position.right() ).filter { it.y in indices && it.x in this[it.y].indices && this[it.y][it.x] != '#' }.toSet() } } fun main() { val year = 2023 val day = 23 val exampleInput = InputReader.getExampleLines(year, day) val puzzleInput = InputReader.getPuzzleLines(year, day) fun partOne(input: List<String>) = Day23(input).partOne() fun partTwo(input: List<String>) = Day23(input).partTwo() println("Example 1: ${partOne(exampleInput)}") println("Puzzle 1: ${partOne(puzzleInput)}") println("Example 2: ${partTwo(exampleInput)}") println("Puzzle 2: ${partTwo(puzzleInput)}") }

Kotlin

b274e43441b4ddb163c509ed14944902c2b011ab

AdventOfCode

Creative Commons Zero v1.0 Universal

src/Day24.kt

Flame239

{"Kotlin": 60685}

private fun map(): List<String> { val m = readInput("Day24") h = m.size w = m[0].length cycle = lcm(h - 2, w - 2) start = CC(0, m[0].indexOf(".")) finish = CC(m.size - 1, m[m.size - 1].indexOf(".")) return m } private var h = -1 private var w = -1 private var cycle = -1 private lateinit var start: CC private lateinit var finish: CC /* Just bfs, but 'visited' is tricky. Map repeats every 'cycle = lcm(h - 2, w - 2)' steps, so we should check if we visited cell on (step % cycle) before. e.g. if we visited a cell 600 steps before, we should skip it, as map looks exactly the same */ private fun shortestPathTo(map: List<String>, initStep: Int, start: CC, finish: CC): Int { val visited = HashMap<CC, BooleanArray>() var step = initStep val q = ArrayDeque(listOf(start)) while (q.isNotEmpty()) { repeat(q.size) { val pos = q.removeFirst() if (pos == finish) return step - 1 listOf(pos, pos.up(), pos.down(), pos.left(), pos.right()) .filter { p -> shouldVisit(map, visited, p, step) } .forEach(q::add) } step++ } return -1 } private fun shouldVisit(map: List<String>, visited: HashMap<CC, BooleanArray>, p: CC, step: Int): Boolean { if (p.i < 0 || p.i >= h || map[p.i][p.j] == '#') return false val pVis = visited.getOrPut(p) { BooleanArray(cycle) } if (pVis[step % cycle]) return false pVis[step % cycle] = true // IMPROVEMENT: pre-calculate all possible maps (there will be `cycle` of them) if (map[p.i][(p.j - 1 - step).mod(w - 2) + 1] == '>') return false if (map[p.i][(p.j - 1 + step).mod(w - 2) + 1] == '<') return false if (map[(p.i - 1 - step).mod(h - 2) + 1][p.j] == 'v') return false if (map[(p.i - 1 + step).mod(h - 2) + 1][p.j] == '^') return false return true } private fun part1(map: List<String>): Int = shortestPathTo(map, 1, start, finish) private fun part2(map: List<String>): Int { var step = shortestPathTo(map, 1, start, finish) step = shortestPathTo(map, step, finish, start) return shortestPathTo(map, step, start, finish) } fun main() { measure { part1(map()) } measure { part2(map()) } }

Kotlin

27f3133e4cd24b33767e18777187f09e1ed3c214

advent-of-code-2022

Apache License 2.0

src/day_8/kotlin/Day8.kt

Nxllpointer

{"Kotlin": 41751}

// AOC Day 8 fun Array<Array<Int>>.isTreeVisible(treePos: Pair<Int, Int>): Boolean { val maxTreeIndex = this.lastIndex val treeHeight = this[treePos.first][treePos.second] return ((0 until treePos.first).all { vIndex -> this[vIndex][treePos.second] < treeHeight } || (maxTreeIndex downUntil treePos.first).all { vIndex -> this[vIndex][treePos.second] < treeHeight } || (0 until treePos.second).all { hIndex -> this[treePos.first][hIndex] < treeHeight } || (maxTreeIndex downUntil treePos.second).all { hIndex -> this[treePos.first][hIndex] < treeHeight }) } fun Array<Array<Int>>.getColnumSection(colnum: Int, from: Int, to: Int): List<Int> = (from..to).filter { it in 0..this.lastIndex }.map { this[it][colnum] } fun Array<Array<Int>>.getRowSection(row: Int, from: Int, to: Int): List<Int> = (from..to).filter { it in 0..this.lastIndex }.map { this[row][it] } fun Array<Array<Int>>.getScenicScore(treePos: Pair<Int, Int>): Int { val maxTreeIndex = this.lastIndex val treeHeight = this[treePos.first][treePos.second] fun List<Int>.getDistance() = slice(0..indexOfFirstOr(lastIndex) { it >= treeHeight }).size val distanceUp = this.getColnumSection(treePos.second, 0, treePos.first - 1).reversed().getDistance() val distanceDown = this.getColnumSection(treePos.second, treePos.first + 1, maxTreeIndex).getDistance() val distanceLeft = this.getRowSection(treePos.first, 0, treePos.second - 1).reversed().getDistance() val distanceRight = this.getRowSection(treePos.first, treePos.second + 1, maxTreeIndex).getDistance() return distanceUp * distanceDown * distanceLeft * distanceRight } fun part1(trees: Array<Array<Int>>) { val maxTreeIndex = trees.lastIndex var visibleTreeCount = 0 for (vIndex in 0..maxTreeIndex) { for (hIndex in 0..maxTreeIndex) { if (trees.isTreeVisible(vIndex to hIndex)) visibleTreeCount++ } } println("Part 1: $visibleTreeCount trees are visible from the outside") } fun part2(trees: Array<Array<Int>>) { val maxTreeIndex = trees.lastIndex val scenicScores = mutableListOf<Int>() for (vIndex in 0..maxTreeIndex) { for (hIndex in 0..maxTreeIndex) { scenicScores += trees.getScenicScore(vIndex to hIndex) } } val maxScenicScore = scenicScores.max() println("Part 2: The highest scenic score is $maxScenicScore") } fun main() { val trees = getAOCInput { rawInput -> rawInput.trim().split("\n") .map { row -> row .map { colnum -> colnum.digitToInt() } .toTypedArray() }.toTypedArray() } part1(trees) part2(trees) }

Kotlin

b6d7ef06de41ad01a8d64ef19ca7ca2610754151

AdventOfCode2022

MIT License

src/Day12.kt

palex65

{"Kotlin": 68582}

private data class Pos(val x:Int, val y: Int) private fun Pos.neighbors() = listOf( Pos(x-1,y), Pos(x+1,y), Pos(x,y-1), Pos(x,y+1) ) private class Area(input: List<String>) { val area = input.map { it.map { c -> when(c) { 'S' -> 0 'E' -> 'z'-'a' else -> c-'a' } } } operator fun get(p: Pos) = area[p.y][p.x] fun isValid(p: Pos) = p.y in (0..area.lastIndex) && p.x in (0..area[0].lastIndex) fun allPosOf(level: Int) = buildList { area.forEachIndexed { y, line -> line.forEachIndexed { x, lev -> if (lev==level) add(Pos(x,y)) } } } } private fun List<String>.posOf(c: Char): Pos { forEachIndexed { y, line -> val x = line.indexOf(c) if (x!=-1) return Pos(x,y) } error("Position not found for $c") } private data class Node(val pos: Pos, val steps: Int) private fun part1(input: List<String>) = shortestPath(input.posOf('S'), input.posOf('E'), Area(input)) private fun part2(input: List<String>): Int { val area = Area(input) val end = input.posOf('E') return area.allPosOf(0).mapNotNull { shortestPath(it, end, area) }.min() } private fun shortestPath(start: Pos, end: Pos, area: Area): Int? { val visited = mutableMapOf<Pos, Int>() val open = mutableListOf(Node(start, 0)) while (open.isNotEmpty()) { val (pos, steps) = open.removeFirst() if (pos==end) return steps visited[pos] = steps pos.neighbors() .filter { area.isValid(it) && area[it] <= area[pos] + 1 } .forEach { p -> if (p !in visited && open.none { it.pos == p } ) open.add(Node(p, steps+1)) } } return null } fun main() { val testInput = readInput("Day12_test") check(part1(testInput) == 31) check(part2(testInput) == 29) val input = readInput("Day12") println(part1(input)) // 437 println(part2(input)) // 430 }

Kotlin

35771fa36a8be9862f050496dba9ae89bea427c5

aoc2022

Apache License 2.0

src/poyea/aoc/mmxxii/day16/Day16.kt

poyea

{"Kotlin": 68491}

package poyea.aoc.mmxxii.day16 import poyea.aoc.utils.readInput data class State(val current: String, val minutes: Int, val opened: Set<Valve>) data class Valve(val from: String, val to: List<String>, val rate: Int) { companion object { fun from(line: String): Valve { return Valve( from = line.substringAfter("Valve ").substringBefore(" "), to = line.substringAfter("to valve").substringAfter(" ").split(", "), rate = line.substringAfter("rate=").substringBefore(";").toInt() ) } } } fun findDistances(valves: Map<String, Valve>): Map<String, Map<String, Int>> { return valves.keys.map { valve -> val distances = mutableMapOf<String, Int>().withDefault { Int.MAX_VALUE }.apply { put(valve, 0) } val queue = mutableListOf(valve) while (queue.isNotEmpty()) { val current = queue.removeFirst() valves[current]!!.to.forEach { neighbour -> val dist = distances[current]!! + 1 if (dist < distances.getValue(neighbour)) { distances[neighbour] = dist queue.add(neighbour) } } } distances }.associateBy { it.keys.first() } } fun traverse( minutes: Int, start: Valve, current: Valve, remaining: Set<Valve>, cache: MutableMap<State, Int>, elephant: Boolean, distances: Map<String, Map<String, Int>> ): Int { val pressure = minutes * current.rate val currentState = State(current.from, minutes, remaining) return pressure + cache.getOrPut(currentState) { val maxCurrent = remaining .filter { to -> distances[current.from]!![to.from]!! < minutes } .takeIf { it.isNotEmpty() } ?.maxOf { to -> val remainingMinutes = minutes - 1 - distances[current.from]!![to.from]!! traverse(remainingMinutes, start, to, remaining - to, cache, elephant, distances) } ?: 0 maxOf(maxCurrent, if (elephant) traverse(26, start, start, remaining, mutableMapOf(), false, distances) else 0) } } fun part1(input: String): Int { val valves = input.split("\n").map(Valve::from).associateBy(Valve::from) val usefulValves = valves.filter { it.value.rate > 0 } val distances = findDistances(valves) return traverse(30, valves.getValue("AA"), valves.getValue("AA"), usefulValves.values.toSet(), mutableMapOf(), false, distances) } fun part2(input: String): Int { val valves = input.split("\n").map(Valve::from).associateBy(Valve::from) val usefulValves = valves.filter { it.value.rate > 0 } val distances = findDistances(valves) return traverse(26, valves.getValue("AA"), valves.getValue("AA"), usefulValves.values.toSet(), mutableMapOf(), true, distances) } fun main() { println(part1(readInput("Day16"))) println(part2(readInput("Day16"))) }

Kotlin

fd3c96e99e3e786d358d807368c2a4a6085edb2e

aoc-mmxxii

MIT License

src/Day12.kt

mathijs81

{"Kotlin": 167658, "Python": 725, "Shell": 57}

private const val EXPECTED_1 = 21L private const val EXPECTED_2 = 525152L private class Day12(isTest: Boolean) : Solver(isTest) { val resultMap = mutableMapOf<Pair<Int, Int>, Long>() fun arrangements(strLeft: String, groupsLeft: List<Int>): Long { val damageCount = groupsLeft.sum() val minDamage = strLeft.count { it == '#' } val maxDamage = strLeft.count { it != '.' } if (damageCount == 0 && minDamage == 0) { return 1 } if (minDamage > damageCount || damageCount > maxDamage) { return 0 } if (strLeft[0] == '?') { val key = strLeft.length to groupsLeft.size resultMap[key]?.let { return it } var sum = 0L if (strLeft.substring(0, groupsLeft[0]).all { it != '.' } && strLeft[groupsLeft[0]] != '#') { sum += arrangements(strLeft.substring(groupsLeft[0] + 1), groupsLeft.drop(1)) } sum += arrangements(strLeft.substring(1), groupsLeft) return sum.also { resultMap[key] = it } } else { if (strLeft[0] == '#') { if (strLeft.substring(0, groupsLeft[0]).all { it == '#' || it == '?' } && strLeft[groupsLeft[0]] != '#') { return arrangements(strLeft.substring(groupsLeft[0] + 1), groupsLeft.drop(1)) } else return 0 } else { return arrangements(strLeft.substring(1), groupsLeft) } } } fun part1() = readAsLines().sumOf { line -> resultMap.clear() val parts = line.split(" ") val nums = parts[1].splitInts() arrangements(parts[0] + ".", nums) } fun part2() = readAsLines().sumOf { line -> resultMap.clear() val parts = line.split(" ") val nums = parts[1].splitInts() val newNums = mutableListOf<Int>() var newStr = "" repeat(5) { newNums.addAll(nums) newStr += parts[0] if (it != 4) { newStr += "?" } } arrangements(newStr + ".", newNums) } } fun main() { val testInstance = Day12(true) val instance = Day12(false) testInstance.part1().let { check(it == EXPECTED_1) { "part1: $it != $EXPECTED_1" } } println("part1 ANSWER: ${instance.part1()}") testInstance.part2().let { check(it == EXPECTED_2) { "part2: $it != $EXPECTED_2" } println("part2 ANSWER: ${instance.part2()}") } }

Kotlin

92f2e803b83c3d9303d853b6c68291ac1568a2ba

advent-of-code-2022

Apache License 2.0

src/Day12.kt

inssein

{"Kotlin": 47333}

import java.util.PriorityQueue data class Edge(val point: Pair<Int, Int>, val elevation: Int) : Comparable<Edge> { override fun compareTo(other: Edge) = elevation.compareTo(other.elevation) } data class Grid(val grid: List<List<Int>>) { private val height = grid.size private val width = grid.first().size fun shortestPath( start: Pair<Int, Int>, isDestination: (Pair<Int, Int>) -> Boolean ): Int { val visited = mutableSetOf<Pair<Int, Int>>() val queue = PriorityQueue<Edge>() .apply { add(Edge(start, 0)) } while (queue.isNotEmpty()) { val (point, elevation) = queue.poll() if (!visited.add(point)) { continue } val neighbours = neighbours(point) if (neighbours.any { isDestination(it) }) { return elevation + 1 } queue.addAll(neighbours.map { Edge(it, elevation + 1) }) } error("No valid path.") } private fun neighbours(point: Pair<Int, Int>): List<Pair<Int, Int>> { val (x, y) = point return listOfNotNull( if (y == 0) null else x to y - 1, // up if (y == height - 1) null else x to y + 1, // down if (x == 0) null else x - 1 to y, // left if (x == width - 1) null else x + 1 to y // right ).filter { value(point) - value(it) <= 1 } } fun value(point: Pair<Int, Int>) = grid[point.second][point.first] } fun main() { fun List<String>.parse(): Triple<Grid, Pair<Int, Int>, Pair<Int, Int>> { var start: Pair<Int, Int>? = null var end: Pair<Int, Int>? = null val grid = this.foldIndexed(listOf<List<Int>>()) { y, acc, line -> val t = line.mapIndexed { x, it -> when (it) { 'S' -> 0.also { start = x to y } 'E' -> 25.also { end = x to y } else -> it - 'a' } } acc.plusElement(t) } return Triple(Grid(grid), start ?: error("invalid"), end ?: error("invalid")) } fun part1(input: List<String>): Int { val (grid, start, end) = input.parse() return grid.shortestPath(end) { it == start } } fun part2(input: List<String>): Int { val (grid, _, end) = input.parse() return grid.shortestPath(end) { grid.value(it) == 0 } } val testInput = readInput("Day12_test") println(part1(testInput)) // 31 println(part2(testInput)) // 29 val input = readInput("Day12") println(part1(input)) // 472 println(part2(input)) // 465 }

Kotlin

095d8f8e06230ab713d9ffba4cd13b87469f5cd5

advent-of-code-2022

Apache License 2.0

src/Day15.kt

rod41732

{"Kotlin": 85344}

import kotlin.math.absoluteValue import kotlin.math.max import kotlin.math.min data class Coord2D(val x: Int, val y: Int) { fun manhattanDistance(other: Coord2D): Int { return (x - other.x).absoluteValue + (y - other.y).absoluteValue } override fun toString(): String { return "($x, $y)" } } data class SensorResult(val sensor: Coord2D, val nearestBeacon: Coord2D) { var nearestDist = sensor.manhattanDistance(nearestBeacon) fun cannotContainBeacon(y: Int): IntRange { val dy = (sensor.y - y).absoluteValue if (dy > nearestDist) return IntRange.EMPTY val dx = nearestDist - dy return sensor.x - dx..sensor.x + dx } } fun main() { val input = readInput("Day15") fun part1(input: List<String>, yToConsider: Int): Int { val beacons = input.map(::parseBeaconLine) val nonPossiblePositions = beacons.map { it.cannotContainBeacon(yToConsider) }.filter { !it.isEmpty() } .sortedBy { it.first }.fold(Int.MIN_VALUE to 0) { (lastX, count), range -> val left = range.first val right = range.last val overlaps = min(max(lastX + 1 - left, 0), range.count()) max(right, lastX) to count + range.count() - overlaps }.second // be careful to not count the beacon at same position twice val beaconsInThatY = beacons.filter { it.nearestBeacon.y == yToConsider }.map { it.nearestBeacon.x }.toSet().size return nonPossiblePositions - beaconsInThatY } fun part2(input: List<String>, searchSpace: Int): Long { val beacons = input.map(::parseBeaconLine) (0 .. searchSpace) .forEach { yPos -> var lastX = -1 beacons.map { it.cannotContainBeacon(yPos) } .also { if (yPos == 1257) { println(it.filter{!it.isEmpty()}.sortedBy { it.first } ) } } .filter { !it.isEmpty() } .sortedBy { it.first } .forEach { range -> if (lastX > searchSpace) return@forEach val left = range.first val right = range.last if (left - lastX >= 2) { val foundX = lastX + 1 val foundY = yPos return 4_000_000L * foundX + foundY } lastX = max(lastX, right) } } throw Exception("Bad Input, no beacon found") } val inputTest = readInput("Day15_test") println(part1(inputTest, yToConsider = 10)) check(part1(inputTest, yToConsider = 10) == 26) println(part2(inputTest, searchSpace = 20)) check(part2(inputTest, searchSpace = 20) == 56000011L) println("Part1") println(part1(input, yToConsider = 2_000_000)) // 54036 println("Part2") println(part2(input, searchSpace = 4_000_000)) // 13237873355 } private fun parseBeaconLine(input: String): SensorResult { val (a, b, c, d) = Regex("[-0-9]+").findAll(input).map { it.value.toInt() }.toList() return SensorResult(Coord2D(a, b), Coord2D(c, d)) }

Kotlin

1d2d3d00e90b222085e0989d2b19e6164dfdb1ce

advent-of-code-kotlin-2022

Apache License 2.0

src/main/kotlin/Day08.kt

alex859

{"Kotlin": 80552}

fun main() { val testInput = readInput("Day08_test.txt") check(testInput.visibleTrees() == 21) check(testInput.maxScore() == 8) val input = readInput("Day08.txt") println(input.visibleTrees()) println(input.maxScore()) } internal fun String.visibleTrees(): Int { val visibleInRows = this.rows().flatMapIndexed { i, row -> row.visibleTrees().map { i to it } } val visibleInColumns = this.columns().flatMapIndexed { i, col -> col.visibleTrees().map { it to i } } return (visibleInRows + visibleInColumns).distinct().size } internal fun String.rows(): List<List<Int>> { return lines().map { it.toList().map { tree -> tree.digitToInt() } } } internal fun String.columns(): List<List<Int>> { val columns = MutableList<MutableList<Int>>(lines().first().length) { mutableListOf() } lines().forEachIndexed { i, row -> row.forEachIndexed { j, tree -> val c = tree.digitToInt() val column = columns[j] column.add(c) } } return columns } internal fun List<Int>.leftOf(i: Int) = dropLast(size - i) internal fun List<Int>.rightOf(i: Int) = drop(i + 1) internal fun List<Int>.visibleTrees(): Set<Int> { if (size == 1) { return setOf(0) } val left = mapIndexed { i, tree -> val leftOf = leftOf(i) i to if (leftOf.isEmpty()) true else leftOf.count { it >= tree } == 0 }.filter { (_, visible) -> visible }.map { (i, _) -> i } val right = mapIndexed { i, tree -> val rightOf = rightOf(i) i to if (rightOf.isEmpty()) true else rightOf.count { it >= tree } == 0 }.filter { (_, visible) -> visible }.map { (i, _) -> i } return left.toSet() + right.toSet() } internal fun String.maxScore(): Int { val rowCount = rows().count() val colCount = columns().count() return (0 until rowCount).flatMap { row -> (0 until colCount).map { col -> scenicScore(row, col) } }.max() } internal fun String.scenicScore(rowIndex: Int, colIndex: Int): Int { val row = rows()[rowIndex] val col = columns()[colIndex] val height = rows()[rowIndex][colIndex] val leftScore = row.leftOf(colIndex).reversed().scenicScoreForHeight(height) val rightScore = row.rightOf(colIndex).scenicScoreForHeight(height) val topScore = col.leftOf(rowIndex).reversed().scenicScoreForHeight(height) val downScore = col.rightOf(rowIndex).scenicScoreForHeight(height) return leftScore * rightScore * topScore * downScore } internal fun List<Int>.scenicScoreForHeight(height: Int): Int { if (isEmpty()) { return 0 } val mapIndexed = mapIndexed { i, h -> i to h } val index = mapIndexed.filter { (_, h) -> h >= height }.firstOrNull()?.first?:(size - 1) return if (index == 0) 1 else index + 1 }

Kotlin

fbbd1543b5c5d57885e620ede296b9103477f61d

advent-of-code-kotlin-2022

Apache License 2.0

src/Day15.kt

proggler23

{"Kotlin": 27990}

import kotlin.math.abs import kotlin.math.max import kotlin.math.min fun main() { fun part1(input: List<String>, y: Int): Int { return input.parse15().getPositionsInRange(y) } fun part2(input: List<String>, boundary: Int): Long { return input.parse15().getTuningFrequency(boundary) } // test if implementation meets criteria from the description, like: val testInput = readInput("Day15_test") check(part1(testInput, 10) == 26) check(part2(testInput, 20) == 56000011L) val input = readInput("Day15") println(part1(input, 2000000)) println(part2(input, 4000000)) } val SENSOR_REGEX = Regex("Sensor at x=(-?\\d+), y=(-?\\d+): closest beacon is at x=(-?\\d+), y=(-?\\d+)") fun List<String>.parse15(): SensorGrid { return SensorGrid( mapNotNull { line -> SENSOR_REGEX.find(line)?.let { result -> Sensor( position = result.groupValues[1].toInt() to result.groupValues[2].toInt(), beacon = result.groupValues[3].toInt() to result.groupValues[4].toInt() ) } } ) } data class Sensor(val position: Pair<Int, Int>, val beacon: Pair<Int, Int>) { private val sensorRange = (beacon - position).length fun getRange(y: Int) = abs(y - position.second).let { yDistance -> if (yDistance > sensorRange) null else position.first - (sensorRange - yDistance)..position.first + (sensorRange - yDistance) } } data class SensorGrid(private val sensors: List<Sensor>) { fun getPositionsInRange(y: Int): Int { return sensors.mapNotNull { it.getRange(y) }.reduce().sumOf { it.last - it.first } } fun getTuningFrequency(boundary: Int): Long { return (0..boundary).firstNotNullOf { y -> sensors.mapNotNull { it.getRange(y) }.reduce() .takeIf { ranges -> ranges.size > 1 } ?.let { ranges -> 4000000L * (ranges.minOf { it.last } + 1) + y } } } } val Pair<Int, Int>.length: Int get() = abs(first) + abs(second) operator fun Pair<Int, Int>.minus(other: Pair<Int, Int>) = first - other.first to second - other.second operator fun Pair<Int, Int>.plus(other: Pair<Int, Int>) = first + other.first to second + other.second fun List<IntRange>.reduce(): List<IntRange> { infix fun IntRange.intersect(other: IntRange) = first <= other.last + 1 && last >= other.first - 1 infix fun IntRange.join(other: IntRange) = min(first, other.first)..max(last, other.last) val ranges = this.toMutableList() loop@ while (ranges.size > 1) { for (i1 in ranges.indices) { for (i2 in (i1 + 1) until ranges.size) { if (ranges[i1] intersect ranges[i2]) { ranges += ranges.removeAt(i2).join(ranges.removeAt(i1)) continue@loop } } } break } return ranges }

Kotlin

584fa4d73f8589bc17ef56c8e1864d64a23483c8

advent-of-code-2022

Apache License 2.0

src/Day15.kt

thpz2210

{"Kotlin": 50995}

import kotlin.math.abs private class Solution15(input: List<String>) { val sensors = input.map { getSensorFrom(it) } private fun getSensorFrom(line: String): Sensor { val split = line.split("x=", "y=", ",", ":") val position = Coordinate(split[1].toInt(), split[3].toInt()) val beacon = Coordinate(split[5].toInt(), split[7].toInt()) return Sensor(position, beacon) } fun part1(y: Int) = lineCover(y).sumOf { it.to - it.from + 1 } - beaconsInLine(y) private fun beaconsInLine(y: Int) = sensors.map { it.beacon }.filter { it.y == y }.toSet().size fun part2(max: Int): Long { for (y in (0..max)) { val lineCover = lineCover(y).singleOrNull() { it.from in 1..max } if (lineCover != null) return (lineCover.from - 1) * 4000000L + y } throw IllegalStateException() } private fun lineCover(y: Int): List<LineCover> = sensors.mapNotNull { it.lineCover(y) }.sortedBy { it.from } .fold<LineCover, List<LineCover>>(listOf()) { acc, fromTo -> reduceLineCovers(acc, fromTo) } .fold(listOf()) { acc, fromTo -> reduceLineCovers(acc, fromTo) } // here happens magic private fun reduceLineCovers(acc: List<LineCover>, rightCover: LineCover): List<LineCover> { if (acc.isEmpty()) return listOf(rightCover) val newAcc = mutableSetOf<LineCover>() acc.forEach { leftCover -> if (leftCover.from == rightCover.from && leftCover.to <= rightCover.to) newAcc.add(rightCover) else if (rightCover.to <= leftCover.to) newAcc.add(leftCover) else if (leftCover.to + 1 >= rightCover.from) newAcc.add(LineCover(leftCover.from, rightCover.to)) else { newAcc.add(leftCover) newAcc.add(rightCover) } } return newAcc.sortedBy { it.from } } data class Sensor(val position: Coordinate, val beacon: Coordinate) { val distance = abs(position.x - beacon.x) + abs(position.y - beacon.y) fun lineCover(y: Int): LineCover? { val dx = distance - abs(y - position.y) return if (dx >= 0) LineCover(position.x - dx, position.x + dx) else null } } data class LineCover(var from: Int, var to: Int) } fun main() { val testSolution = Solution15(readInput("Day15_test")) check(testSolution.part1(10) == 26) check(testSolution.part2(20) == 56000011L) val solution = Solution15(readInput("Day15")) println(solution.part1(2000000)) println(solution.part2(4000000)) }

Kotlin

69ed62889ed90692de2f40b42634b74245398633

aoc-2022

Apache License 2.0

src/Day08.kt

davedupplaw

{"Kotlin": 29190}

fun main() { fun makeMap(inputs: List<String>): Triple<List<List<Int>>, Int, Int> { val h = inputs.size val w = inputs[0].length val trees = inputs .map { it.split("") .filter { x -> x.isNotBlank() } .map { x -> x.toInt() } } return Triple(trees, w, h) } fun List<List<Int>>.column(y: Int) = this.map { it[y] } fun List<List<Int>>.row(x: Int) = this[x] fun List<List<Int>>.isVisibleFromAnywhere(x: Int, y: Int): Boolean { val col = this.column(x) val row = this.row(y) val value = this[y][x] val visibleFromAbove = col.take(y).all { v -> v < value } val visibleFromBelow = col.reversed().take(col.size - y - 1).all { v -> v < value } val visibleFromLeftSide = row.take(x).all { v -> v < value } val visibleFromRightSide = row.reversed().take(row.size - x - 1).all { v -> v < value } return visibleFromAbove || visibleFromBelow || visibleFromLeftSide || visibleFromRightSide } fun Sequence<Int>.chase(value: Int): List<Int> { var blocked = 0 return this.map { if (it >= value || blocked > 0) blocked++ it }.takeWhile { blocked < 2 }.toList() } fun List<List<Int>>.scenicScore(x: Int, y: Int): Int { val col = this.column(x) val row = this.row(y) val value = this[y][x] val toTopEdge = col.take(y).reversed().asSequence().chase(value).count() val toLeftEdge = row.take(x).reversed().asSequence().chase(value).count() val toBottomEdge = col.takeLast(col.size - y - 1).asSequence().chase(value).count() val toRightEdge = row.takeLast(row.size - x - 1).asSequence().chase(value).count() return toTopEdge * toLeftEdge * toBottomEdge * toRightEdge } fun part1(input: List<String>): Int { val (trees, w, h) = makeMap(input) val sum = (1 until w - 1).sumOf { y -> (1 until h - 1).sumOf { x -> if (trees.isVisibleFromAnywhere(x, y)) 1 else 0 as Int } } return sum + 2 * h + 2 * (w - 2) } fun part2(input: List<String>): Int { val (trees, w, h) = makeMap(input) return (0 until w).maxOf { y -> (0 until h).maxOf { x -> trees.scenicScore(x, y) } } } val test = readInput("Day08.test") val part1test = part1(test) println("part1 test: $part1test") check(part1test == 21) val part2test = part2(test) println("part2 test: $part2test") check(part2test == 8) val input = readInput("Day08") val part1 = part1(input) println("Part1: $part1") val part2 = part2(input) println("Part2: $part2") }

Kotlin

3b3efb1fb45bd7311565bcb284614e2604b75794

advent-of-code-2022

Apache License 2.0

src/poyea/aoc/mmxxii/day08/Day08.kt

poyea

{"Kotlin": 68491}

package poyea.aoc.mmxxii.day08 import poyea.aoc.utils.readInput fun part1(input: String): Int { input.split("\n").toList().map { it.map(Char::digitToInt).toList() }.let { rows -> fun sightLine(x: Int, y: Int) = listOf(listOf((x - 1 downTo 0), (x + 1 until rows.size)).map { it.map { xx -> xx to y } }, listOf((y - 1 downTo 0), (y + 1 until rows.size)).map { it.map { yy -> x to yy } }).flatten() .map { it.map { (x, y) -> rows[y][x] } } return rows.flatMapIndexed { y, l -> l.mapIndexed { x, h -> Triple(x, y, h) } }.count { (x, y, h) -> sightLine(x, y).any { it.all { ele -> ele < h } } } } } fun part2(input: String): Int { input.split("\n").toList().map { it.map(Char::digitToInt).toList() }.let { rows -> fun sightLine(x: Int, y: Int) = listOf(listOf((x - 1 downTo 0), (x + 1 until rows.size)).map { it.map { xx -> xx to y } }, listOf((y - 1 downTo 0), (y + 1 until rows.size)).map { it.map { yy -> x to yy } }).flatten() .map { it.map { (x, y) -> rows[y][x] } } return rows.flatMapIndexed { y, l -> l.mapIndexed { x, h -> Triple(x, y, h) } }.maxOf { (x, y, h) -> sightLine(x, y).map { it.indexOfFirst { tree -> tree >= h }.let { idx -> if (idx >= 0) idx + 1 else it.size } }.reduce(Int::times) } } } fun main() { println(part1(readInput("Day08"))) println(part2(readInput("Day08"))) }

Kotlin

fd3c96e99e3e786d358d807368c2a4a6085edb2e

aoc-mmxxii

MIT License

src/com/kingsleyadio/adventofcode/y2023/Day22.kt

kingsleyadio

{"Kotlin": 134666, "JavaScript": 5423}

package com.kingsleyadio.adventofcode.y2023 import com.kingsleyadio.adventofcode.util.readInput fun main() { val input = readInput(2023, 22).useLines { lines -> buildList { lines.forEachIndexed { index, line -> val (start, end) = line.split("~") val (sx, sy, sz) = start.split(",").map { it.toInt() } val (ex, ey, ez) = end.split(",").map { it.toInt() } add(Cube(index + 1, sx..ex, sy..ey, sz..ez)) } } } val (support, dependency) = simulate(input) part1(input, support, dependency) part2(support, dependency) } private fun part1(input: List<Cube>, support: Relationship, dependency: Relationship) { val redundant = support.count { (_, s) -> s.all { dependency.getValue(it).size > 1 } } val freeAgents = input.size - support.size + 1 println(redundant + freeAgents) } private fun part2(support: Relationship, dependency: Relationship) { val result = (support.keys - 0).sumOf { disintegrate(it, support, dependency) } println(result) } private fun disintegrate(id: Int, support: Relationship, dependency: Relationship): Int { val startDeps = dependency.getValue(id) val toDisintegrate = hashSetOf<Int>() val queue = ArrayDeque<Set<Int>>() queue.addLast(setOf(id)) toDisintegrate.addAll(startDeps) while (queue.isNotEmpty()) { val current = queue.removeFirst().filter { cId -> val unknown = cId !in toDisintegrate val canDisintegrate = dependency.getValue(cId).all { it in toDisintegrate } unknown && canDisintegrate } if (current.isEmpty()) continue toDisintegrate.addAll(current) val next = current.flatMapTo(hashSetOf()) { support.getOrDefault(it, emptySet()) } queue.addLast(next) } return toDisintegrate.size - startDeps.size - 1 } private fun simulate(input: List<Cube>): Pair<Relationship, Relationship> { val upwardSupport = hashMapOf<Int, MutableSet<Int>>() val downwardDependency = hashMapOf<Int, MutableSet<Int>>() val plane = Array(10) { Array(10) { Marker(0, 0) } } input.sortedBy { it.z.first }.forEach { cube -> val markers = arrayListOf<Marker>() for (y in cube.y) for (x in cube.x) markers.add(plane[y][x]) val highest = markers.maxBy { it.index } val contact = markers.filter { it.index == highest.index }.distinctBy { it.id } contact.forEach { marker -> upwardSupport.getOrPut(marker.id) { mutableSetOf() }.add(cube.id) downwardDependency.getOrPut(cube.id) { mutableSetOf() }.add(marker.id) } val newZ = highest.index + cube.z.size for (y in cube.y) for (x in cube.x) plane[y][x] = Marker(cube.id, newZ) } return upwardSupport to downwardDependency } private typealias Relationship = Map<Int, Set<Int>> private data class Cube(val id: Int, val x: IntRange, val y: IntRange, val z: IntRange) private data class Marker(val id: Int, val index: Int)

Kotlin

9abda490a7b4e3d9e6113a0d99d4695fcfb36422

adventofcode

Apache License 2.0

src/year_2022/day_03/Day03.kt

scottschmitz

{"Kotlin": 240069}

package year_2022.day_03 import readInput import util.toAlphabetPosition data class Rucksack( val compartmentOne: List<Char>, val compartmentTwo: List<Char> ) { val allItemTypes: List<Char> = compartmentOne + compartmentTwo val errorItemType: Char = compartmentOne.intersect(compartmentTwo.toSet()).first() } data class ElfGroup( val rucksacks: List<Rucksack> ) { val badge: Char get() { var commonItemGroups = rucksacks.first().allItemTypes.toSet() rucksacks.forEach { rucksack -> commonItemGroups = commonItemGroups.intersect(rucksack.allItemTypes.toSet()) } return commonItemGroups.first() } } object Day03 { /** * @return sum of the priority of items erroneously in both compartments */ fun solutionOne(rucksacksText: List<String>): Int { val rucksacks = parseRucksacks(rucksacksText) return rucksacks.sumOf { rucksack -> rucksack.errorItemType.toAlphabetPosition() } } /** * @return the total priority of elf group badges */ fun solutionTwo(rucksacksText: List<String>): Int { val rucksacks = parseRucksacks(rucksacksText) val elfGroups = groupRucksacks(rucksacks) return elfGroups.sumOf { group -> group.badge.toAlphabetPosition() } } private fun parseRucksacks(text: List<String>): List<Rucksack> { return text.map { rucksackText -> val rucksackSize = rucksackText.length Rucksack( compartmentOne = rucksackText.substring(0, (rucksackSize + 1) / 2).toList(), compartmentTwo = rucksackText.substring((rucksackSize + 1) / 2, rucksackSize).toList() ) } } private fun groupRucksacks(rucksacks: List<Rucksack>): List<ElfGroup> { return rucksacks.chunked(3).map { rucksackGroup -> ElfGroup(rucksacks = rucksackGroup) } } } fun main() { val rucksacksText = readInput("year_2022/day_03/Day03.txt") val solutionOne = Day03.solutionOne(rucksacksText) println("Solution 1: Total Priority of Error Items: $solutionOne") val solutionTwo = Day03.solutionTwo(rucksacksText) println("Solution 2: Total Elf Badge Priorities: $solutionTwo") }

Kotlin

70efc56e68771aa98eea6920eb35c8c17d0fc7ac

advent_of_code

Apache License 2.0

src/com/kingsleyadio/adventofcode/y2022/day12/Solution.kt

kingsleyadio

{"Kotlin": 134666, "JavaScript": 5423}

package com.kingsleyadio.adventofcode.y2022.day12 import com.kingsleyadio.adventofcode.util.readInput import java.util.* fun main() { val grid = buildGrid() part1(grid) part2(grid) } fun part1(grid: Grid) { println(shortestDistance(grid)) } fun part2(grid: Grid) { var shortestDistance = Int.MAX_VALUE val (outline, _, end) = grid for (i in outline.indices) { val row = outline[i] for (j in row.indices) { if (row[j] != 0) continue val newGrid = Grid(outline, Point(i, j), end) val nextShortestDistance = shortestDistance(newGrid) if (nextShortestDistance < 0) continue shortestDistance = minOf(shortestDistance, nextShortestDistance) } } println(shortestDistance) } fun shortestDistance(grid: Grid): Int { val (outline, start, end) = grid val costs = Array(outline.size) { IntArray(outline.first().size) { -1 } } val queue = PriorityQueue<Path> { a, b -> a.cost - b.cost } queue.add(Path(start, 0)) while (queue.isNotEmpty()) { val (point, cost) = queue.poll() if (costs[point.y][point.x] in 0..cost) continue costs[point.y][point.x] = cost val dx = intArrayOf(0, 1, 0, -1) val dy = intArrayOf(-1, 0, 1, 0) for (index in dx.indices) { val np = Point(point.y + dy[index], point.x + dx[index]) if (outline.getOrNull(np.y)?.getOrNull(np.x) == null) continue if (costs[np.y][np.x] >= 0) continue // already fixed cost to this point val potential = (outline[np.y][np.x] - outline[point.y][point.x]).coerceAtLeast(1) if (potential == 1) queue.add(Path(np, cost + potential)) } } return costs[end.y][end.x] } fun buildGrid(): Grid { var start = Point(0, 0) var end = Point(0, 0) var rowIndex = 0 val grid = buildList { readInput(2022, 12).forEachLine { line -> val row = line .onEachIndexed { index, char -> if (char == 'S') start = Point(rowIndex, index) } .onEachIndexed { index, char -> if (char == 'E') end = Point(rowIndex, index) } .map { (if (it == 'S') 'a' else if (it == 'E') 'z' else it) - 'a' } add(row) rowIndex++ } } return Grid(grid, start, end) } data class Grid(val outline: List<List<Int>>, val start: Point, val end: Point) data class Point(val y: Int, val x: Int) data class Path(val to: Point, val cost: Int)

Kotlin

9abda490a7b4e3d9e6113a0d99d4695fcfb36422

adventofcode

Apache License 2.0

kotlin/src/2022/Day19_2022.kt

regob

{"Kotlin": 50757, "Python": 46520, "Shell": 430}

import kotlin.math.* private data class State(val resources: List<Int>, val robots: List<Int>, val t: Int) // ore, clay, obsidian, geode fun maxGeodes(resources: List<Int>, robots: List<Int>, t: Int, costs: List<List<Int>>): Int { val cache = mutableMapOf<State, Int>() var allBest = 0 // best solution found yet var currentRes = 0 // result on the current path without the current node // maximum amount of each robot val maxRobot = robots.indices.map {i -> costs.maxOf {it[i]}} // maximum geodes that can be produced in the remaining time val maxGeodeLeft = (0..t).map {it * (it - 1) / 2} fun dfs(res: List<Int>, rob: List<Int>, t: Int, buildSkipped: List<Int> = emptyList()): Int { if (t <= 1) return 0 if (t == 2) return if (res.indices.any {res[it] < costs[3][it]}) 0 else 1 val state = State(res, rob, t) if (state in cache) return cache[state]!! // if we cannot improve the best solution, even if we build geode robots all the time, cut this branch if (currentRes + maxGeodeLeft[t] <= allBest) return -1 var branchCut = false var best = 0 val possibleRobots = costs.indices.asSequence() .filter {r -> r !in buildSkipped} .filter {r -> res.zip(costs[r]).all {it.first >= it.second}} .filter {r -> r == 3 || rob[r] < maxRobot[r]} .toList() for (r in possibleRobots) { val new_res = res.indices.map {res[it] + rob[it] - costs[r][it]} val new_rob = rob.indices.map {if(it == r) rob[it] + 1 else rob[it]} // if new robot is geode robot, it produces t-1 geodes in total val curr = if (r == 3) { currentRes += t - 1 (dfs(new_res, new_rob, t-1) + t-1).also {currentRes -= t - 1} } else { dfs(new_res, new_rob, t-1) } if (curr < 0) branchCut = true else best = max(best, curr) } // we can also skip building anything val new_res = res.indices.map {res[it] + rob[it]} dfs(new_res, rob, t-1, possibleRobots).let { if (it < 0) branchCut = true else best = max(best, it) } if (!branchCut) cache[state] = best allBest = max(allBest, best + currentRes) return best } return dfs(resources, robots, t) } fun main() { val bps = readInput(19).trim().lines() .map {"\\d+".toRegex().findAll(it).map {it.groupValues[0].toInt()}.toList()} .map { bp -> bp[0] to listOf(listOf(bp[1], 0, 0), listOf(bp[2], 0, 0), listOf(bp[3], bp[4], 0), listOf(bp[5], 0, bp[6])) } // part1 println(bps.sumOf { it.first * maxGeodes(listOf(0, 0, 0), listOf(1, 0, 0), 24, costs=it.second) }) // part2 println(bps.take(3).map { maxGeodes(listOf(0, 0, 0), listOf(1, 0, 0), 32, costs=it.second) }.reduce {x, y -> x * y}) }

Kotlin

cf49abe24c1242e23e96719cc71ed471e77b3154

adventofcode

Apache License 2.0

src/Day12.kt

mikrise2

{"Kotlin": 62406}

import java.lang.Integer.min import java.util.LinkedList fun main() { fun findPath(input: List<String>, start: Pair<Int, Int>, end: Pair<Int, Int>): Int { val distances = input.map { it.map { Int.MAX_VALUE }.toMutableList() } distances[start.second][start.first] = 0 val path = mutableSetOf<Pair<Int, Int>>() val queue = LinkedList<Pair<Int, Int>>() queue.add(start) while (queue.isNotEmpty()) { val current = queue.poll() if (path.contains(current)) continue val left = Pair(current.first - 1, current.second) val right = Pair(current.first + 1, current.second) val up = Pair(current.first, current.second - 1) val down = Pair(current.first, current.second + 1) if (current.first > 0 && input[current.second][current.first].code - input[current.second][current.first - 1].code >= -1 ) { distances[left.second][left.first] = min(distances[current.second][current.first] + 1, distances[left.second][left.first]) queue.add(left) } if (current.first < input[0].lastIndex && input[current.second][current.first].code - input[current.second][current.first + 1].code >= -1 ) { distances[right.second][right.first] = min(distances[current.second][current.first] + 1, distances[right.second][right.first]) queue.add(right) } if (current.second > 0 && input[current.second][current.first].code - input[current.second - 1][current.first].code >= -1 ) { distances[up.second][up.first] = min(distances[current.second][current.first] + 1, distances[up.second][up.first]) queue.add(up) } if (current.second < input.lastIndex && input[current.second][current.first].code - input[current.second + 1][current.first].code >= -1 ) { distances[down.second][down.first] = min(distances[current.second][current.first] + 1, distances[down.second][down.first]) queue.add(down) } path.add(current) } return distances[end.second][end.first] } fun part1(input: List<String>): Int { val startY = input.indexOfFirst { it.contains('S') } val startX = input[startY].indexOfFirst { it == 'S' } val endY = input.indexOfFirst { it.contains('E') } val endX = input[endY].indexOfFirst { it == 'E' } val copy = input.toMutableList().map { it.replace("S", "a").replace("E", "z") } return findPath(copy, Pair(startX, startY), Pair(endX, endY)) } fun part2(input: List<String>): Int { val endY = input.indexOfFirst { it.contains('E') } val endX = input[endY].indexOfFirst { it == 'E' } val copy = input.toMutableList().map { it.replace("S", "a").replace("E", "z") } val starts = copy.filter { it.contains('a') }.mapIndexed { index, s -> s.mapIndexed { indexC, c -> if (c == 'a') Pair(indexC, index ) else Pair( -1, -1 ) } }.flatten().filter { it.first != -1 } return starts.map { findPath(copy, it, Pair(endX, endY)) }.min() } val input = readInput("Day12") println(part1(input)) println(part2(input)) }

Kotlin

d5d180eaf367a93bc038abbc4dc3920c8cbbd3b8

Advent-of-code

Apache License 2.0

src/Day02.kt

brigittb

{"Kotlin": 46744}

fun main() { fun parse(input: List<String>): List<Pair<String, String>> = input .map { it.split(" ") } .filter { it.size == 2 } .map { (opponent, own) -> opponent to own } fun mapToAbc(own: String): String = when (own) { "X" -> "A" "Y" -> "B" else -> "C" } fun part1(input: List<String>): Int { return parse(input) .map { (opponent, own) -> opponent to mapToAbc(own) } .map { (opponent, own) -> Option.valueOf(opponent) to Option.valueOf(own) } .sumOf { (opponent, own) -> when (opponent.name) { own.win -> 6 + own.ordinal + 1 own.draw -> 3 + own.ordinal + 1 else -> own.ordinal + 1 } } } fun part2(input: List<String>): Int = parse(input) .map { (opponent, choice) -> Option.valueOf(opponent) to Choice.valueOf(choice) } .sumOf { (opponent, choice) -> when (choice) { Choice.X -> Option.valueOf(opponent.win).ordinal + 1 + choice.score Choice.Y -> Option.valueOf(opponent.draw).ordinal + 1 + choice.score Choice.Z -> Option.valueOf(opponent.loss).ordinal + 1 + choice.score } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day02_test") check(part1(testInput) == 15) val input = readInput("Day02") println(part1(input)) println(part2(input)) } private enum class Option( val win: String, val draw: String, val loss: String ) { A("C", "A", "B"), // rock B("A", "B", "C"), // paper C("B", "C", "A") // scissor } private enum class Choice(val score: Int) { X(0), Y(3), Z(6) }

Kotlin

470f026f2632d1a5147919c25dbd4eb4c08091d6

aoc-2022

Apache License 2.0

src/day08.kts

miedzinski

{"Kotlin": 22560, "Shell": 113}

fun Int(word: String): Int = word.fold(0) { acc, c -> acc or (1 shl (c - 'a')) } val input = generateSequence(::readLine).map { val words = it.split(' ') val delimiterIndex = words.indexOf("|") val signals: List<Int> = words.subList(0, delimiterIndex).map { Int(it) } val output: List<Int> = words.subList(delimiterIndex + 1, words.size).map { Int(it) } Pair(signals, output) }.toList() fun part1(): Int { val counts = MutableList(10) { 0 } for ((_, output) in input) { for (digit in output) { when (digit.countOneBits()) { 2 -> counts[1]++ 3 -> counts[7]++ 4 -> counts[4]++ 7 -> counts[8]++ } } } return counts.sum() } println("part1: ${part1()}") fun List<Int>.ofCount(length: Int): List<Int> = filter { it.countOneBits() == length } fun Int.contains(other: Int) = and(other) == other fun List<Int>.decode(): Map<Int, Int> { val digits = MutableList(10) { 0 } digits[1] = ofCount(2).single() digits[4] = ofCount(4).single() digits[7] = ofCount(3).single() digits[8] = ofCount(7).single() digits[9] = ofCount(6).single { it.contains(digits[4]) } digits[3] = ofCount(5).single { it.contains(digits[1]) } val e = digits[8] and digits[9].inv() digits[2] = ofCount(5).single { it.contains(e) } val b = digits[9] and digits[3].inv() digits[5] = ofCount(5).single { it.contains(b) } digits[6] = ofCount(6).single { it.contains(e) && !it.contains(digits[1]) } digits[0] = ofCount(6).single { it != digits[9] && it != digits[6] } return digits.withIndex().associate { (digit, segments) -> segments to digit } } fun part2(): Int = input.sumOf { (signals, output) -> val digits = signals.decode() output.asReversed() .withIndex() .sumOf { (idx, segments) -> val digit = digits[segments]!! val exp = generateSequence(1) { it * 10 }.elementAt(idx) digit * exp } } println("part2: ${part2()}")

Kotlin

6f32adaba058460f1a9bb6a866ff424912aece2e

aoc2021

The Unlicense

src/poyea/aoc/mmxxii/day13/Day13.kt

poyea

{"Kotlin": 68491}

package poyea.aoc.mmxxii.day13 import kotlin.collections.MutableList import poyea.aoc.utils.readInput fun wrap(list: MutableList<Char>, len: Int): MutableList<Char> { list.add(len, ']') list.add(0, '[') return list } fun isInOrder(l: MutableList<Char>, r: MutableList<Char>): Boolean { var left = l var right = r var left_number = if (!left.first().isDigit()) null else left.takeWhile { it.isDigit() }.joinToString("").toInt() var right_number = if (!right.first().isDigit()) null else right.takeWhile { it.isDigit() }.joinToString("").toInt() if (left[0] == '[' && right_number != null) right = wrap(right, 1 + right_number / 10) if (right[0] == '[' && left_number != null) left = wrap(left, 1 + left_number / 10) return when { left[0] == ']' && right[0] != ']' -> true left[0] != ']' && right[0] == ']' -> false left_number == (right_number ?: -1) -> isInOrder( left.subList(1 + left_number / 10, left.size), right.subList(1 + right_number!! / 10, right.size) ) left_number != null && right_number != null -> left_number < right_number else -> isInOrder(left.subList(1, left.size), right.subList(1, right.size)) } } fun compare(s1: String, s2: String): Int { return if (isInOrder(s1.toMutableList(), s2.toMutableList())) -1 else 1 } fun part1(input: String): Int { return input .split("\n") .windowed(2, 3) .mapIndexed { i, packets -> if (compare(packets.first(), packets.last()) != 1) i + 1 else 0 } .sum() } fun part2(input: String): Int { val lst = input.split("\n").windowed(2, 3) val comp: (String, String) -> Int = { s1: String, s2: String -> if (isInOrder(s1.toMutableList(), s2.toMutableList())) -1 else 1 } val sorted = (lst.flatten() + "[[2]]" + "[[6]]").sortedWith({ s1, s2 -> compare(s1, s2) }) return (1 + sorted.indexOf("[[2]]")) * (1 + sorted.indexOf("[[6]]")) } fun main() { println(part1(readInput("Day13"))) println(part2(readInput("Day13"))) }

Kotlin

fd3c96e99e3e786d358d807368c2a4a6085edb2e

aoc-mmxxii

MIT License

advent-of-code2015/src/main/kotlin/day9/Advent9.kt

REDNBLACK

package day9 import parseInput import permutations import splitToLines /** --- Day 9: All in a Single Night --- Every year, Santa manages to deliver all of his presents in a single night. This year, however, he has some new locations to visit; his elves have provided him the distances between every pair of locations. He can start and end at any two (different) locations he wants, but he must visit each location exactly once. What is the shortest distance he can travel to achieve this? For example, given the following distances: London to Dublin = 464 London to Belfast = 518 Dublin to Belfast = 141 The possible routes are therefore: Dublin -> London -> Belfast = 982 London -> Dublin -> Belfast = 605 London -> Belfast -> Dublin = 659 Dublin -> Belfast -> London = 659 Belfast -> Dublin -> London = 605 Belfast -> London -> Dublin = 982 The shortest of these is London -> Dublin -> Belfast = 605, and so the answer is 605 in this example. What is the distance of the shortest route? --- Part Two --- The next year, just to show off, Santa decides to take the route with the longest distance instead. He can still start and end at any two (different) locations he wants, and he still must visit each location exactly once. For example, given the distances above, the longest route would be 982 via (for example) Dublin -> London -> Belfast. What is the distance of the longest route? */ fun main(args: Array<String>) { val test = """ |London to Dublin = 464 |London to Belfast = 518 |Dublin to Belfast = 141 """.trimMargin() println(findDistance(test) == mapOf("first" to 605, "second" to 982)) val input = parseInput("day9-input.txt") println(findDistance(input)) } fun findDistance(input: String): Map<String, Int?> { val travels = parseTravels(input) return travels .flatMap(Travel::toList) .distinct() .permutations() .fold(setOf<Int>(), { distances, permute -> distances + permute.zip(permute.subList(1, permute.size)) .map { p -> travels.find { it.from == p.first && it.to == p.second } } .filterNotNull() .sumBy { it.distance } }) .let { mapOf("first" to it.min(), "second" to it.max()) } } data class Travel(val from: String, val to: String, val distance: Int) { fun toList() = listOf(from, to) } private fun parseTravels(input: String) = input.splitToLines() .map { val (from, _s1, to, _s2, distance) = it.split(" ") Travel(from = from, to = to, distance = distance.toInt()) } .flatMap { listOf(it, it.copy(from = it.to, to = it.from)) }

Kotlin

e282d1f0fd0b973e4b701c8c2af1dbf4f4a149c7

courses

MIT License

src/day5/Day5.kt

bartoszm

{"Kotlin": 39186}

package day5 import readInput fun main() { val testInput = parse(readInput("day05/test")) val input = parse(readInput("day05/input")) println(solve1(testInput.first, testInput.second)) println(solve1(input.first, input.second)) println(solve2(testInput.first, testInput.second)) println(solve2(input.first, input.second)) } fun solve1(stacks: List<Stack>, moves: List<Move>) : String { fun push(stack: Stack, content: String) = content.fold(stack) { acc, c -> Stack(c.toString() + acc.content) } return solve(stacks, moves, ::push) } fun solve2(stacks: List<Stack>, moves: List<Move>) : String { fun push(stack: Stack, content: String) = Stack( content +stack.content) return solve(stacks, moves, ::push) } fun solve(stacks: List<Stack>, moves: List<Move>, crane: (Stack, String) -> Stack): String { val subject = stacks.toMutableList() for(move in moves) { val f = move.from - 1 val t = move.to - 1 subject[t] = crane(subject[t], subject[f].take(move.quantity)) subject[f] = subject[f].drop(move.quantity) } return subject.map { it.content[0] }.joinToString("") } data class Stack(val content: String) { fun take(size: Int) = content.substring(0, size) fun drop(size: Int) = Stack(content.substring(size)) } data class Move(val from: Int, val to: Int, val quantity: Int) fun parse(input: List<String>): Pair<List<Stack>, List<Move>> { fun parseStacks(v: String): List<Stack> { return v.chunked(4) .map{if(it.isBlank()) Stack("") else Stack("" + it[1])} } fun parseMove(v: String): Move? { if(!v.startsWith("move")) { return null } val tokens = v.split("""\s+""".toRegex()).map { it.trim() } return Move(from = tokens[3].toInt(), to = tokens[5].toInt(), quantity = tokens[1].toInt()) } val seq = input.asSequence() val stacks = seq.takeWhile { it.trim().startsWith('[') } .map { parseStacks(it) } .fold(listOf<Stack>()) { acc, ns -> merge(ns, acc) } val moves = seq.mapNotNull { parseMove(it) }.toList() return stacks to moves } fun merge(newStack: List<Stack>, currentStack: List<Stack>): List<Stack> { val merged = (currentStack zip newStack).map { (c,n) -> Stack(c.content + n.content) } val (long, short) = if(newStack.size > currentStack.size) { newStack to currentStack } else { currentStack to newStack } return merged + long.subList(short.size, long.size) }

Kotlin

f1ac6838de23beb71a5636976d6c157a5be344ac

aoc-2022

Apache License 2.0

src/main/kotlin/aoc2023/Day05.kt

j4velin

{"Kotlin": 285016, "Python": 1446}

package aoc2023 import cut import readInput import separateBy private data class MappingRange(val range: LongRange, val offset: Long) private data class ConversionMap(val name: String, private val mappings: List<MappingRange>) { companion object { private val MAP_REGEX = """(?<destination>\d+)\s+(?<source>\d+)\s+(?<size>\d+)""".toRegex() fun fromStringList(input: List<String>): ConversionMap { val name = input.first().replace(" map:", "") val mappings = mutableListOf<MappingRange>() input.drop(1).forEach { line -> val result = MAP_REGEX.find(line) if (result != null) { val size = result.groups["size"]!!.value.toInt() - 1 val sourceStart = result.groups["source"]!!.value.toLong() val destinationStart = result.groups["destination"]!!.value.toLong() mappings.add( MappingRange( LongRange(sourceStart, sourceStart + size), destinationStart - sourceStart ) ) } else { throw IllegalArgumentException("invalid input: $line") } } return ConversionMap(name, mappings.sortedBy { it.range.first }) } } fun map(input: Long) = mappings.find { input in it.range }?.let { it.offset + input } ?: input fun map(input: LongRange): Sequence<LongRange> = sequence { var gaps = listOf(input) mappings.filter { it.range.last >= input.first && it.range.first <= input.last }.forEach { val overlapStart = it.range.first.coerceAtLeast(input.first) val overlapEnd = it.range.last.coerceAtMost(input.last) val overlap = LongRange(overlapStart, overlapEnd) yield(LongRange(overlapStart + it.offset, overlapEnd + it.offset)) gaps = gaps.flatMap { gap -> gap.cut(overlap) } } if (gaps.isNotEmpty()) { gaps.forEach { yield(it) } } } } object Day05 { fun part1(input: List<String>): Long { val seeds = input.first().replace("seeds: ", "").split("\\s".toRegex()).map { it.toLong() } val maps = input.drop(2).separateBy { it.isEmpty() }.map { ConversionMap.fromStringList(it) } return seeds.minOf { seed -> var currentValue = seed maps.forEach { currentValue = it.map(currentValue) } currentValue } } fun part2(input: List<String>): Long { val regex = """(?<start>\d+)\s+(?<size>\d+)\s?""".toRegex() val seedRanges = regex.findAll(input.first()).map { result -> val start = result.groups["start"]!!.value.toLong() LongRange(start, start + result.groups["size"]!!.value.toLong() - 1L) } val maps = input.drop(2).separateBy { it.isEmpty() }.map { ConversionMap.fromStringList(it) } return seedRanges.minOf { seedRange -> var currentSequence = sequenceOf(seedRange) maps.forEach { conversionMap -> currentSequence = currentSequence.flatMap { conversionMap.map(it) } } currentSequence.minOf { it.first } } } } fun main() { val testInput = readInput("Day05_test", 2023) check(Day05.part1(testInput) == 35L) check(Day05.part2(testInput) == 46L) val input = readInput("Day05", 2023) println(Day05.part1(input)) println(Day05.part2(input)) }

Kotlin

f67b4d11ef6a02cba5b206aba340df1e9631b42b

adventOfCode

Apache License 2.0

src/year2023/day07/Day.kt

tiagoabrito

{"Kotlin": 73752}

package year2023.day07 import year2023.solveIt fun main() { val day = "07" val expectedTest1 = 6440L val expectedTest2 = 5905L val sortingOrder = listOf('A','K','Q','J','T','9','8','7','6','5','4','3','2') fun getHandValue(eachCount: Map<Char, Int>): Int { return when(eachCount.size){ 1 -> 7 2 -> when (eachCount.any { it.value == 4 }) { true -> 6 false -> 5 } 3 -> when (eachCount.any { it.value == 3 }) { true -> 4 false -> 3 } 4 -> 2 5 -> 1 else -> 0 } } fun getHandValueJ(eachCount: Map<Char, Int>): Int { val jokers = eachCount.getOrDefault('J', 0) val filter = eachCount.filter { it.key != 'J' }.entries.sortedWith(compareBy({it.value * -1}, {sortingOrder.indexOf(it.key)})) val optimal = when (filter.isEmpty()){ true -> eachCount false -> mapOf(filter[0].key to filter[0].value + jokers) + filter.drop(1).map { it.toPair() } } return getHandValue(optimal) } fun getIt(input: List<String>, kFunction1: (Map<Char, Int>) -> Int, sortingList: List<Char>): Long { val map = input.map { line -> val (cards, bet) = line.split(" ") val handValue = kFunction1(cards.groupingBy { it }.eachCount()) cards to (bet to handValue) } val sorted = map.sortedWith( compareBy( { it.second.second * -1 }, { sortingList.indexOf(it.first[0]) }, { sortingList.indexOf(it.first[1]) }, { sortingList.indexOf(it.first[2]) }, { sortingList.indexOf(it.first[3]) }, { sortingList.indexOf(it.first[4]) } )).reversed() sorted.map { it.first }.forEach { println(it) } val b = sorted.mapIndexed { k, v -> v.second.first.toLong() * (k + 1) } return b.sum() } fun part1(input: List<String>): Long { return getIt(input, ::getHandValue, sortingOrder) } fun part2(input: List<String>): Long { return getIt(input, ::getHandValueJ, sortingOrder.filter { l -> l != 'J' } + 'J') } solveIt(day, ::part1, expectedTest1, ::part2, expectedTest2) }

Kotlin

1f9becde3cbf5dcb345659a23cf9ff52718bbaf9

adventOfCode

Apache License 2.0

src/Day13.kt

shepard8

{"Kotlin": 73637}

sealed interface Tree13: Comparable<Tree13> class Node13(private vararg val subtrees: Tree13): Tree13, List<Tree13> by subtrees.toList() { override fun compareTo(other: Tree13): Int { return when(other) { is Leaf13 -> this.compareTo(Node13(other)) is Node13 -> compareToNode13(other) } } private fun compareToNode13(other: Node13): Int { return when { this.isEmpty() && other.isEmpty() -> 0 this.isEmpty() && other.isNotEmpty() -> -1 this.isNotEmpty() && other.isEmpty() -> 1 else -> { this.first().compareTo(other.first()).takeUnless { it == 0 } ?: Node13(*this.drop(1).toTypedArray()).compareTo(Node13(*other.drop(1).toTypedArray())) } } } } class Leaf13(val number: Int): Tree13 { override fun compareTo(other: Tree13): Int { return when(other) { is Leaf13 -> this.number.compareTo(other.number) is Node13 -> Node13(this).compareTo(other) } } } fun main() { fun part1(signals: List<Pair<Tree13, Tree13>>): Int { return signals.mapIndexedNotNull { index, (signal1, signal2) -> (index + 1).takeIf { signal1 < signal2 } }.sum() } fun part2(signals: List<Tree13>): Int { val sep1 = Node13(Node13(Leaf13(2))) val sep2 = Node13(Node13(Leaf13(6))) val all = signals + listOf(sep1, sep2) val sorted = all.sorted() val index1 = sorted.indexOf(sep1) + 1 val index2 = sorted.indexOf(sep2) + 1 return index1 * index2 } fun stringToTree(input: MutableList<Char>): Tree13 { fun readElement(): Tree13 { if (input[0] == ',') { input.removeAt(0) } return if (input[0] == '[') { input.removeAt(0) val elements = sequence { while (input[0] != ']') { yield(readElement()) } input.removeAt(0) }.toList() Node13(*elements.toTypedArray()) } else if (input[1].isDigit()) { Leaf13(input.removeAt(0).digitToInt() * 10 + input.removeAt(0).digitToInt()) } else { Leaf13(input.removeAt(0).digitToInt()) } } return readElement() } val signals = readInput("Day13").filterNot { it.isEmpty() }.map { s -> stringToTree(s.toMutableList()) } println(part1(signals.chunked(2).map { chunk -> Pair(chunk[0], chunk[1]) })) println(part2(signals)) }

Kotlin

81382d722718efcffdda9b76df1a4ea4e1491b3c

aoc2022-kotlin

Apache License 2.0

src/main/kotlin/day-08.kt

warriorzz

{"Kotlin": 16719}

package com.github.warriorzz.aoc import java.nio.file.Files import java.nio.file.Path private fun main() { println("Day 8:") val lines = Files.readAllLines(Path.of("./input/day-08.txt")) val part1 = lines.map { line -> line.split(" | ")[1].split(" ").map { it.length == 2 || it.length == 4 || it.length == 7 || it.length == 3 } .map { if (it) 1 else 0 }.reduce { acc, i -> acc + i } }.reduce { acc, i -> acc + i } println("Solution part 1: $part1") val part2 = lines.map { determineNumberSum(it.split(" | ")[0].split(" "), it.split(" | ")[1].split(" ")) } .reduce { acc, i -> acc + i } println("Solution part 2: $part2") } fun determineNumberSum(strings: List<String>, output: List<String>): Int { val map = mutableMapOf<Char, Char>() val seven = strings.first { it.length == 3 } val one = strings.first { it.length == 2 } map[seven.first { !one.contains(it) }] = 'a' map[charList.filter { one.contains(it) }.first { char -> strings.count { it.contains(char) } == 9 }] = 'f' map[charList.filter { one.contains(it) }.first { char -> strings.count { it.contains(char) } == 8 }] = 'c' map[charList.filter { map[it] != 'f' && map[it] != 'c' && map[it] != 'a' }.first { char -> strings.filter { it.length !in (2..4) }.all { it.contains(char) } }] = 'g' map[charList.filter { map[it] != 'f' && map[it] != 'c' && map[it] != 'a' }.first { char -> strings.filter { it.length !in (2..4) }.count { it.contains(char) } == 5 }] = 'b' map[charList.filter { map[it] != 'f' && map[it] != 'c' && map[it] != 'a' }.first { char -> strings.filter { it.length !in (2..4) }.count { it.contains(char) } == 4 }] = 'e' map[charList.filter { map[it] != 'f' && map[it] != 'c' && map[it] != 'a' }.first { char -> strings.filter { it.length !in (2..4) }.count { it.contains(char) } == 6 }] = 'd' val solution = output.map { numbers[it.map { char -> map[char]!! }.toCharArray().sortedArray().map { it.toString() } .reduce { acc, s -> acc + s }]!! }.reduce { acc, i -> acc + i }.toInt() charList.forEach { t -> println("$t " + map[t]) } println(solution) println() return solution } private val charList = listOf('a', 'b', 'c', 'd', 'e', 'f', 'g') private val numbers = mapOf( "abcefg" to "0", "cf" to "1", "acdeg" to "2", "acdfg" to "3", "bcdf" to "4", "abdfg" to "5", "abdefg" to "6", "acf" to "7", "abcdefg" to "8", "abcdfg" to "9" ) fun day08() = main()

Kotlin

0143f59aeb8212d4ff9d65ad30c7d6456bf28513

aoc-21

MIT License

src/main/kotlin/com/github/ferinagy/adventOfCode/aoc2023/2023-19.kt

ferinagy

{"Kotlin": 787586}

package com.github.ferinagy.adventOfCode.aoc2023 import com.github.ferinagy.adventOfCode.println import com.github.ferinagy.adventOfCode.readInputLines import kotlin.math.max import kotlin.math.min fun main() { val input = readInputLines(2023, "19-input") val test1 = readInputLines(2023, "19-test1") println("Part1:") part1(test1).println() part1(input).println() println() println("Part2:") part2(test1).println() part2(input).println() } private fun part1(input: List<String>): Int { val rules = input.takeWhile { it.isNotBlank() }.map(Rule::parse).associateBy { it.name } val accepted = acceptedRanges(rules) val parts = input.drop(rules.size + 1).map(Part::parse) return parts.filter { part -> accepted.any { ranges -> part.rates.all { it.value in ranges[it.key]!! } } }.sumOf { it.rating } } private fun part2(input: List<String>): Long { val rules = input.takeWhile { it.isNotBlank() }.map(Rule::parse).associateBy { it.name } val accepted = acceptedRanges(rules) return accepted.sumOf { it.values.fold(1L) { acc, range -> acc * (range.last - range.first + 1) } } } private fun acceptedRanges( rules: Map<String, Rule>, current: String = "in", ranges: Map<Char, LongRange> = mapOf('x' to 1..4000L, 'm' to 1..4000L, 'a' to 1..4000L, 's' to 1..4000L) ): List<Map<Char, LongRange>> { if (current == "A") return listOf(ranges) if (current == "R") return emptyList() return buildList { val rule = rules[current]!! var newRanges = ranges rule.conditions.forEach { val range = newRanges[it.name]!! this += acceptedRanges(rules, it.output, newRanges + (it.name to (it.range intersect range))) newRanges = newRanges + (it.name to (it.oppositeRange intersect range)) } this += acceptedRanges(rules, rule.fallback, newRanges) } } private infix fun LongRange.intersect(other: LongRange): LongRange = max(first, other.first)..min(last, other.last) private data class Part(val rates: Map<Char, Int>) { val rating: Int = rates.values.sum() companion object { fun parse(text: String): Part { val map = text.substring(1, text.length - 1).split(',') .associate { it.split('=').let { (name, value) -> name.single() to value.toInt() } } return Part(map) } } } private class Rule(val name: String, val conditions: List<Condition>, val fallback: String) { companion object { val regex = """(\w+)\{(.*)}""".toRegex() fun parse(text: String): Rule { val (name, c) = regex.matchEntire(text)!!.destructured val list = c.split(',') return Rule(name, list.dropLast(1).map { Condition.parse(it) }, list.last()) } } } private data class Condition(val name: Char, val range: LongRange, val output: String) { val oppositeRange = if (range.first == 1L) range.last + 1..4000 else 1..<range.first companion object { val regex = """([xmas])([<>])(\d+):(\w+)""".toRegex() fun parse(text: String): Condition { val (name, op, value, output) = regex.matchEntire(text)!!.destructured val range = if (op == "<") 1..<value.toLong() else value.toLong() + 1..4000L return Condition(name.single(), range, output) } } }

Kotlin

f4890c25841c78784b308db0c814d88cf2de384b

advent-of-code

MIT License

src/Day07.kt

qmchenry

{"Kotlin": 22260}

fun main() { data class File(val name: String, val size: Int) class DirectoryTree(val name: String, val parent: DirectoryTree?, var children: List<DirectoryTree> = emptyList(), var files: List<File> = emptyList()) { fun size(): Int = children.sumOf { it.size() } + files.sumOf { it.size } fun dirsOfSizeAtMost(size: Int): List<DirectoryTree> = children.filter { it.size() <= size } + children.flatMap { it.dirsOfSizeAtMost(size) } fun dirsOfSizeAtLeast(size: Int): List<DirectoryTree> = children.filter { it.size() >= size } + children.flatMap { it.dirsOfSizeAtLeast(size) } fun description(): String = "$name (${size()} bytes) with ${children.size} children and ${files.size} files\n" fun recursiveDescription(): String = description() + children.joinToString("") { it.recursiveDescription().prependIndent(" ") } } fun parseTree(input: List<String>): DirectoryTree { val root = DirectoryTree("/", null) var cwd = root input.forEach { line -> when { line == "$ cd /" -> cwd = root line == "$ cd .." -> cwd = cwd.parent ?: root line == "$ ls" -> Unit line.startsWith("$ cd ") -> { val dirName = line.substringAfter("$ cd ") val dir = cwd.children.find { it.name == dirName } ?: DirectoryTree(dirName, cwd).also { cwd.children += it } cwd = dir } else -> { val (dirOrSize, name) = line.split(" ") when (dirOrSize) { "dir" -> { val newDir = DirectoryTree(name, cwd) cwd.children += newDir } else -> { val newFile = File(name, dirOrSize.toInt()) cwd.files += newFile } } } } } return root } fun part1(input: List<String>): Int { val root = parseTree(input) return root.dirsOfSizeAtMost(size = 100000) .sumOf { it.size() } } fun part2(input: List<String>): Int { val totalSize = 70000000 val requiredSize = 30000000 val root = parseTree(input) val availableSize = totalSize - root.size() val neededSize = requiredSize - availableSize val dirSizes = root.dirsOfSizeAtLeast(size = neededSize).sortedBy { it.size() } return dirSizes.first().size() } // test if implementation meets criteria from the description, like: val testInput = readInput("Day07_sample") check(part1(testInput) == 95437) val realInput = readInput("Day07_input") println("Part 1: ${part1(realInput)}") println("Part 2: ${part2(realInput)}") }

Kotlin

2813db929801bcb117445d8c72398e4424706241

aoc-kotlin-2022

Apache License 2.0

src/main/day16/Part1.kt

ollehagner

{"Kotlin": 80353}

package day16 import addPermutation import readInput import java.util.* fun main() { val valves = readInput("day16/input.txt").map { Valve.parse(it) } val distances = valves .flatMap { valve -> valves .filter { it != valve && it.flowRate > 0 } .map { Pair(valve.id, it.id) to distance(valve.id, it.id, valves) } }.toMap() val openers = listOf(ValveOpener("You", "AA")) val bestpath = solve(State(openers, valves.filter { it.flowRate > 0 }), distances, 30) println("Day 16 part 1. Best path pressure release: ${bestpath.releasedPressure(30)}") } fun solve(start: State, distances: Map<Pair<String, String>, Int>, timeLimit: Int): State { val states = PriorityQueue<State>() { a, b -> a.score().compareTo(b.score()) * -1 } states.add(start) var currentMax = start while (states.isNotEmpty()) { val currentState = states.poll() val nextMoves = currentState.openers .map { opener -> distances .filter { (fromAndTo, _) -> fromAndTo.first == opener.position } .filter { (fromAndTo, _) -> currentState.valve(fromAndTo.second).closed() } .map { (fromAndTo, distance) -> OpenValveAction(fromAndTo.first, fromAndTo.second, distance) } .filter { action -> (opener.elapsedTime + action.time + 1) <= timeLimit } .distinct() } .fold(listOf(emptyList<OpenValveAction>())) { acc, actions -> acc.addPermutation(actions) } if (nextMoves.isEmpty()) { currentMax = if (currentState.releasedPressure(timeLimit) > currentMax.releasedPressure(timeLimit)) currentState else currentMax } else { states.addAll(nextMoves .filter { actions -> actions.map { it.to }.toSet().size == actions.size } .map { currentState.openValves(it) }) } states .removeIf { it.openedValves() == currentState.openedValves() && it.releasedPressure(timeLimit) < currentState.releasedPressure(timeLimit) } states.removeIf { it.potentialMax(timeLimit, distances) < currentState.releasedPressure(timeLimit) } } return currentMax } data class ValveOpener(val name: String, val position: String, val elapsedTime: Int = 0) { fun openValve(valveId: String, time: Int): ValveOpener { return copy(position = valveId, elapsedTime = elapsedTime + time) } } fun calculateDistances(valves: List<Valve>) = valves .flatMap { valve -> valves .filter { it != valve && it.flowRate > 0 } .map { Pair(valve.id, it.id) to distance(valve.id, it.id, valves) } }.toMap() fun distance(from: String, to: String, valves: List<Valve>): Int { if (from == to) return 0 val valvesWithDistance = PriorityQueue<Pair<String, Int>>() { a, b -> a.second.compareTo(b.second) } valvesWithDistance.add(from to 0) val valveMap = valves.associateBy { it.id } val visited = mutableSetOf<String>() while (true) { val toExpand = valvesWithDistance.poll() if (toExpand.first == to) return toExpand.second valveMap[toExpand.first]!! .connections .filter { !visited.contains(it) } .forEach { valvesWithDistance.add(it to toExpand.second + 1) } } } data class OpenValveAction(val from: String, val to: String, val time: Int)

Kotlin

6e12af1ff2609f6ef5b1bfb2a970d0e1aec578a1

aoc2022

Apache License 2.0

src/Day04.kt

ds411

{"Kotlin": 16415}

fun main() { fun part1(input: List<String>): Int { return input .map { it.split(',') } .fold(0) { acc, pair -> val range1 = pair[0].split('-').map(String::toInt) val range2 = pair[1].split('-').map(String::toInt) if (rangeEncompasses(range1, range2)) acc + 1 else acc } } fun part2(input: List<String>): Int { return input .map { it.split(',') } .fold(0) { acc, pair -> val range1 = pair[0].split('-').map(String::toInt) val range2 = pair[1].split('-').map(String::toInt) if (rangeOverlaps(range1, range2)) acc + 1 else acc } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day04_test") check(part1(testInput) == 2) check(part2(testInput) == 4) val input = readInput("Day04") println(part1(input)) println(part2(input)) } private fun rangeEncompasses(range1: List<Int>, range2: List<Int>): Boolean { val r1 = (range1[0]..range1[1]) val r2 = (range2[0]..range2[1]) return (r1.first <= r2.first && r1.last >= r2.last) || (r2.first <= r1.first && r2.last >= r1.last) } private fun rangeOverlaps(range1: List<Int>, range2: List<Int>): Boolean { val r1 = (range1[0]..range1[1]) val r2 = (range2[0]..range2[1]) return r1.contains(r2.first) || r1.contains(r2.last) || r2.contains(r1.first) || r2.contains(r1.last) }

Kotlin

6f60b8e23ee80b46e7e1262723960af14670d482

advent-of-code-2022

Apache License 2.0

src/day04/Day04.kt

martinhrvn

{"Kotlin": 27307, "Jupyter Notebook": 1336}

package day04 import println import readInput data class Scratchcard(val id: Int, val winningNumbers: Set<Int>, val numbers: Set<Int>) { fun getScore(): Int { val common = getMatchedNumbers() if (common == 0) { return 0 } return 1 shl (common - 1) } fun getMatchedNumbers(): Int { return winningNumbers.intersect(numbers).size } companion object { fun parse(input: String): Scratchcard { val (id, numbers) = input.split(": ") val (winningNumbers, numbersOnScratchcard) = numbers.split(" | ") return Scratchcard( id.replace("Card\\s+".toRegex(), "").toInt(), winningNumbers.trim().split("\\s+".toRegex()).map { it.trim().toInt() }.toSet(), numbersOnScratchcard.trim().split("\\s+".toRegex()).map { it.trim().toInt() }.toSet(), ) } } } class ScratchcardChecker(private val input: List<String>) { fun part1(): Int { return input.sumOf { Scratchcard.parse(it).getScore() } } fun part2(): Int { val scratchcards = input.map { val scratchcard = Scratchcard.parse(it) scratchcard.id to scratchcard } val counts = scratchcards.associate { (k, _) -> k to 1 } val wonTickets = scratchcards.fold(counts) { acc, (k, v) -> val score = v.getMatchedNumbers() val tickets = acc.getOrDefault(k, 0) if (score > 0) { val updatedCounts = (k + 1..k + score).fold(acc) { counts, i -> counts.mapValues { (k, v) -> if (k == i) v + tickets else v } } acc.plus(updatedCounts) } else { acc } } return wonTickets.entries.sumOf { it.value } } } fun main() { val testInput = readInput("day04/Day04_test") println(ScratchcardChecker(testInput).part1()) check(ScratchcardChecker(testInput).part1() == 13) check(ScratchcardChecker(testInput).part2() == 30) val cube = ScratchcardChecker(readInput("day04/Day04")) cube.part1().println() cube.part2().println() }

Kotlin

59119fba430700e7e2f8379a7f8ecd3d6a975ab8

advent-of-code-2023-kotlin

Apache License 2.0

src/twentythree/Day02.kt

mihainov

{"Kotlin": 42574}

package twentythree import readInputTwentyThree typealias Turn = Map<Color, Int> fun Turn.isPossible(constraints: Turn): Boolean { return constraints.entries.all { constraint -> // if no balls of a given color are drawn, element is null // in this case use -1, as it's always possible to draw 0 balls of a color (this[constraint.key]?.compareTo(constraint.value) ?: -1) <= 0 } } data class Game(val index: Int, val turns: List<Turn>) enum class Color(val string: String) { Red("red"), Green("green"), Blue("blue") } fun String.toColor(): Color { return Color.values().find { it.string == this }!! } fun String.parseGame(): Game { val index = this.substring(5, this.indexOf(':')).toInt().also { println("Parsed index: $it") } val stringTurns = this.substring(this.indexOf(':') + 1).split(';') val turns = stringTurns.map { it.split(", ") } // "7 green, 2 red, 1 blue" .map { untrimmedCombination -> // " 7 green" untrimmedCombination.map(String::trim) // "7 green" .map { it.split(" ") } // ["7", "green"] .associate { Pair(it.component2().toColor(), it.component1().toInt()) } } return Game(index, turns) } fun main() { val bag = mapOf(Pair(Color.Red, 12), Pair(Color.Blue, 14), Pair(Color.Green, 13)) fun part1(input: List<String>): Int { val games = input.map { it.parseGame() } return games.filter { game: Game -> game.turns.all { it.isPossible(bag) } }.sumOf { game: Game -> game.index } } fun part2(input: List<String>): Int { val games = input.map { it.parseGame() } return games.sumOf { it.turns.fold(mutableMapOf<Color, Int>()) { acc, map -> map.forEach { entry -> acc.merge(entry.key, entry.value) { new, old -> maxOf(new, old) } } acc }.values.reduce { acc, i -> acc * i } } } // test if implementation meets criteria from the description, like: val testInput = readInputTwentyThree("Day02_test") check(part1(testInput).also(::println) == 8) check(part2(testInput).also(::println) == 2286) val input = readInputTwentyThree("Day02") println(part1(input)) println(part2(input)) }

Kotlin

a9aae753cf97a8909656b6137918ed176a84765e

kotlin-aoc-1

Apache License 2.0

app/src/main/kotlin/codes/jakob/aoc/solution/Day05.kt

loehnertz

{"Kotlin": 59236}

package codes.jakob.aoc.solution import codes.jakob.aoc.shared.splitByLines object Day05 : Solution() { private val mapPattern = Regex("(\\w+)-to-(\\w+)\\smap:") override fun solvePart1(input: String): Any { val splitInput: List<List<String>> = input.split("\n\n").map { it.splitByLines() } val seeds: List<Long> = splitInput.first().first().let { line -> line.substringAfter("seeds: ").split(" ").map { it.toLong() } } val instructionMaps: List<InstructionMap> = parseInstructionMaps(splitInput.drop(1)) // Find the seed that produces the lowest location number return seeds.minOf { seed: Long -> instructionMaps.findLocationNumber(seed) } } override fun solvePart2(input: String): Any { val splitInput: List<List<String>> = input.split("\n\n").map { it.splitByLines() } val seedRanges: List<LongRange> = splitInput.first().first().let { line -> line .substringAfter("seeds: ") .split(" ") .map { it.toLong() } .chunked(2) .map { (startRange, length) -> startRange until (startRange + length) } } val instructionMaps: List<InstructionMap> = parseInstructionMaps(splitInput.drop(1)) // Find the seed that produces the lowest location number for each range, by just brute-forcing it return seedRanges.minOf { seedRange: LongRange -> seedRange.fold(Long.MAX_VALUE) { currentLowest, seed -> val locationNumber: Long = instructionMaps.findLocationNumber(seed) if (locationNumber < currentLowest) locationNumber else currentLowest } } } private fun parseInstructionMaps(splitInput: List<List<String>>): List<InstructionMap> { return splitInput.map { map: List<String> -> val (source, destination) = mapPattern.find(map.first())!!.destructured val type: Pair<String, String> = source to destination val ranges: List<InstructionMap.Ranges> = map .drop(1) .map { line -> line.split(" ").map { it.toLong() } } .map { (destinationRangeStart, sourceRangeStart, length) -> InstructionMap.Ranges( source = sourceRangeStart until (sourceRangeStart + length), destination = destinationRangeStart until (destinationRangeStart + length), ) } InstructionMap(type, ranges) } } private fun List<InstructionMap>.findLocationNumber(seed: Long): Long { return this.fold(seed) { currentNumber, instructionMap -> instructionMap.getMapping(currentNumber) } } private data class InstructionMap( val type: Pair<String, String>, val mappings: List<Ranges>, ) { fun getMapping(source: Long): Long { val ranges: Ranges = mappings.find { ranges -> source in ranges.source } ?: return source return ranges.destination.first + (source - ranges.source.first) } data class Ranges( val source: LongRange, val destination: LongRange, ) } } fun main() = Day05.solve()

Kotlin

6f2bd7bdfc9719fda6432dd172bc53dce049730a

advent-of-code-2023

MIT License

src/Day15.kt

jimmymorales

{"Kotlin": 33914}

import kotlin.math.abs fun main() { fun List<String>.parseSensorAreas() = map { line -> val regex = """Sensor at x=(.*), y=(.*): closest beacon is at x=(.*), y=(.*)""".toRegex() val (sx, sy, bx, by) = regex.find(line)!!.destructured (sx.toInt() to sy.toInt()) to (bx.toInt() to by.toInt()) }.map { (sensor, beacon) -> val distance = abs(sensor.first - beacon.first) + abs(sensor.second - beacon.second) MapArea(sensor, beacon, distance) } fun part1(input: List<String>, row: Int = 10): Int { val areas = input.parseSensorAreas() val min = areas.minOf { it.sensor.first - it.distance } val max = areas.maxOf { it.sensor.first + it.distance } return (min..max).asSequence() .map { x -> x to row } .filter { point -> areas.all { point != it.beacon && point != it.sensor } } .count { point -> areas.any { point in it } } } fun part2(input: List<String>, range: Int = 20): Long { val areas = input.parseSensorAreas() return (0..range) .firstNotNullOf { y -> areas.filter { abs(y - it.sensor.second) <= it.distance } .flatMap { val diff = it.distance - abs(y - it.sensor.second) listOf(it.sensor.first - diff to 1, it.sensor.first + diff + 1 to -1) } .sortedWith(compareBy(Pair<Int, Int>::first, Pair<Int, Int>::second)) .let { var x = it.first().first var count = 0 for (e in it) { if (e.first > x) { if (count == 0 && x in 0..range) { return@let x to y } x = e.first } count += e.second } null } } .let { (x, y) -> (x * 4_000_000L) + y } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day15_test") check(part1(testInput) == 26) val input = readInput("Day15") println(part1(input, row = 2_000_000)) // part 2 check(part2(testInput) == 56000011L) println(part2(input, range = 4_000_000)) } typealias Point = Pair<Int, Int> private data class MapArea(val sensor: Point, val beacon: Point, val distance: Int) private operator fun MapArea.contains(point: Point): Boolean { if (point.second !in sensor.second - distance..sensor.second + distance) return false val diff = abs(point.second - sensor.second) return point.first in sensor.first - distance + diff..sensor.first + distance - diff }

Kotlin

fb72806e163055c2a562702d10a19028cab43188

advent-of-code-2022

Apache License 2.0

src/Day08.kt

cypressious

{"Kotlin": 77610}

fun main() { fun parseGrid(input: List<String>) = input.map { it.asIterable().map { c -> c - '0' } } fun <T> List<List<T>>.transpose() = this[0].indices.map { i -> map { it[i] } } fun List<Int>.runningMax(): List<Int> { return listOf(-1) + runningReduce(::maxOf).dropLast(1) } fun List<Int>.computeDistances(): List<IntArray> { var next = IntArray(10) { -1 } return map { value -> val distances = next distances.forEachIndexed { index, d -> if (d >= 0) distances[index]++ } val prevOwnValueDistance = distances[value] distances[value] = 0 next = distances.copyOf() distances[value] = prevOwnValueDistance distances } } fun part1(input: List<String>): Int { val grid = parseGrid(input) val maxima = buildList { add(grid.map { it.runningMax() }) add(grid.map { it.reversed().runningMax().reversed() }) add(grid.transpose().map { it.runningMax() }.transpose()) add(grid.transpose().map { it.reversed().runningMax().reversed() }.transpose()) } var count = 0 for (x in grid.indices) { for (y in grid[x].indices) { if (grid[x][y] > maxima.minOf { it[x][y] }) { count++ } } } return count } fun part2(input: List<String>): Int { val grid = parseGrid(input) val allDistanceArrays = buildList { add(grid.map { row -> row.computeDistances() }) add(grid.map { row -> row.reversed().computeDistances().reversed() }) add(grid.transpose().map { row -> row.computeDistances() }.transpose()) add(grid.transpose().map { row -> row.reversed().computeDistances().reversed() } .transpose()) } val scores = grid.mapIndexed { y, row -> row.mapIndexed { x, value -> val directionScores = allDistanceArrays.mapIndexed { d, distanceArrays -> val distances = distanceArrays[y][x] distances.drop(value).filter { it >= 0 }.minOrNull() ?: when (d) { 0 -> x 1 -> row.lastIndex - x 2 -> y else -> grid.lastIndex - y } } directionScores.reduce(Int::times) } } return scores.maxOf { it.max() } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInput("Day08") println(part1(input)) println(part2(input)) }

Kotlin

7b4c3ee33efdb5850cca24f1baa7e7df887b019a

AdventOfCode2022

Apache License 2.0

src/Day08.kt

azat-ismagilov

{"Kotlin": 75114}

fun main() { fun List<String>.parseTrees(): List<List<Int>> = this.map { line -> line.map { it.digitToInt() } } fun getPossibleDirections(n: Int, m: Int): List<List<List<Pair<Int, Int>>>> { val xCoordinates = (0 until n) val yCoordinates = (0 until m) return listOf( xCoordinates.map { x -> yCoordinates.map { y -> Pair(x, y) } }, xCoordinates.map { x -> yCoordinates.reversed().map { y -> Pair(x, y) } }, yCoordinates.map { y -> xCoordinates.map { x -> Pair(x, y) } }, yCoordinates.map { y -> xCoordinates.reversed().map { x -> Pair(x, y) } } ) } fun List<List<Int>>.isVisible(): List<List<Boolean>> { val n = this.size val m = this.first().size val result = List(n) { MutableList(m) { false } } val possibleDirections = getPossibleDirections(n, m) for (indexes in possibleDirections) for (indexSequence in indexes) { var maxHeight = -1 indexSequence.forEach { (x, y) -> if (maxHeight < this[x][y]) { result[x][y] = true maxHeight = this[x][y] } } } return result } data class TreeInLine(val position: Int, val height: Int) fun List<List<Int>>.treeHouseVisible(): List<List<Int>> { val n = this.size val m = this.first().size val result = List(n) { MutableList(m) { 1 } } val possibleDirections = getPossibleDirections(n, m) for (indexes in possibleDirections) for (indexSequence in indexes) { val queueVisible = mutableListOf(TreeInLine(0, Int.MAX_VALUE)) indexSequence.forEachIndexed { index, (x, y) -> val currentTreeHeight = this[x][y] while (queueVisible.last().height < currentTreeHeight) queueVisible.removeLast() result[x][y] *= index - queueVisible.last().position queueVisible.add(TreeInLine(index, currentTreeHeight)) } } return result } fun part1(input: List<String>): Int = input.parseTrees().isVisible().sumOf { it.count { it } } fun part2(input: List<String>): Int = input.parseTrees().treeHouseVisible().maxOf { it.maxOf { it } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInput("Day08") println(part1(input)) println(part2(input)) }

Kotlin

abdd1b8d93b8afb3372cfed23547ec5a8b8298aa

advent-of-code-kotlin-2022

Apache License 2.0

2k23/aoc2k23/src/main/kotlin/23.kt

papey

{"Rust": 88237, "Kotlin": 63321, "Elixir": 54197, "Crystal": 47654, "Go": 44755, "Ruby": 24620, "Python": 23868, "TypeScript": 5612, "Scheme": 117}

package d23 import input.read fun main() { println("Part 1: ${part1(read("23.txt"))}") println("Part 2: ${part2(read("23.txt"))}") } fun part1(input: List<String>): Int = Maze(input).findLongestPath() // C'est Noël, on optimise keud' fun part2(input: List<String>): Int = Maze(input, false).findLongestPath() class Maze(input: List<String>, withSlope: Boolean = true) { val map = input.mapIndexed { y, line -> line.toCharArray().mapIndexed { x, c -> val p = Point(x, y) when (c) { '.' -> Element.Path(p) '#' -> Element.Forest(p) '^' -> if (withSlope) { Element.Slope(p, Direction.Up) } else { Element.Path(p) } 'v' -> if (withSlope) { Element.Slope(p, Direction.Down) } else { Element.Path(p) } '<' -> if (withSlope) { Element.Slope(p, Direction.Left) } else { Element.Path(p) } '>' -> if (withSlope) { Element.Slope(p, Direction.Right) } else { Element.Path(p) } else -> throw IllegalStateException("Unknown character: $c") } } } private val start = Point(1, 0) private val end = Point(map[0].size - 2, map.size - 1) fun findLongestPath(): Int { return dfs(start, mutableSetOf()) } private fun dfs(point: Point, visited: MutableSet<Point>): Int { if (point == end) { return 0 } var longestPath = Int.MIN_VALUE visited.add(point) get(point).neighbours().filter { inBound(it) }.map { get(it) } .filter { it is Element.Path || it is Element.Slope }.forEach { neighbour -> if (neighbour.point !in visited) { longestPath = maxOf(longestPath, 1 + dfs(neighbour.point, visited)) } } visited.remove(point) return longestPath } fun get(point: Point): Element = map[point.y][point.x] private fun inBound(point: Point): Boolean = point.x >= 0 && point.y >= 0 && point.y < map.size && point.x < map[point.y].size sealed class Element(open val point: Point) { data class Forest(override val point: Point) : Element(point) data class Path(override val point: Point) : Element(point) data class Slope(override val point: Point, val direction: Direction) : Element(point) { override fun neighbours(): List<Point> = listOf(point.move(direction.point)) } open fun neighbours(): List<Point> = Direction.entries.map { direction -> point.move(direction.point) } } } enum class Direction(val point: Point) { Up(Point(0, -1)), Down(Point(0, 1)), Left(Point(-1, 0)), Right(Point(1, 0)) } data class Point(val x: Int, val y: Int) { fun move(delta: Point): Point = Point(x + delta.x, y + delta.y) }

Rust

cb0ea2fc043ebef75aff6795bf6ce8a350a21aa5

aoc

The Unlicense

src/main/kotlin/be/swsb/aoc2021/day14/Day14.kt

Sch3lp

{"Kotlin": 90751}

package be.swsb.aoc2021.day14 object Day14 { fun solve1(input: List<String>): Int { val (initialTemplate, rules) = parse(input) val polymer = (1..10).fold(initialTemplate) { template, _ -> expandPolymer(template, rules) } val mostCommon = polymer.maxOf { c -> polymer.count { it == c } } val leastCommon = polymer.minOf { c -> polymer.count { it == c } } return mostCommon - leastCommon } fun expandPolymer(template: String, rules: List<Rule>): String = template.windowed(2) { combination -> combination.first() with combination.last() } .joinToString("", prefix = template.take(1)) { combination -> val insertion = rules.find { rule -> rule.combination == combination }?.insertion combination.inject(insertion).drop(1) } fun solve2(input: List<String>): Long { val (initialTemplate, rules) = parse(input) val initialElementCount: Map<Element, Long> = initialTemplate.groupBy { it }.mapValues { (_,v) -> v.size.toLong() } val initialCombinations: List<Combination> = initialTemplate.zipWithNext { first, second -> first with second } val initialCombinationOccurrences : Map<Combination, Long> = initialCombinations.groupBy { it }.mapValues { (_,v) -> v.size.toLong() } val initialPolymer = Polymer(initialCombinationOccurrences, initialElementCount) val polymer = (1..40).fold(initialPolymer) { polymer, _ -> polymer.expand(rules) } val mostCommon = polymer.mostCommon val leastCommon = polymer.leastCommon return mostCommon - leastCommon } fun parse(input: List<String>): Pair<String, List<Rule>> { val rules = input.subList(input.indexOf("") + 1, input.size) val template = input.subList(0, input.indexOf("")).first() return template to rules.map { it.parseToRule() } } } data class Rule(val combination: Combination, val insertion: Char) private fun String.parseToRule(): Rule { val (combo, insert) = this.split(" -> ") val (one, two) = combo.toCharArray() return Rule(one with two, insert.toCharArray()[0]) } data class Combination(val left: Element, val right: Element) { fun inject(insertion: Element?) = insertion?.let { "$left$it$right" } ?: "$left$right" fun insert(insertion: Element?) = insertion?.let { listOf(left with insertion, insertion with right) } ?: emptyList() override fun toString() = "$left$right" } typealias Element = Char infix fun Element.with(other: Element): Combination = Combination(this, other) data class Polymer( private val combinationOccurrences: Map<Combination, Long>, private val countPerElement: Map<Element, Long> ) { val mostCommon: Long by lazy { countPerElement.values.maxOf { it } } val leastCommon: Long by lazy { countPerElement.values.minOf { it } } fun expand(rules: List<Rule>): Polymer { val newCombinationOccurrences : MutableMap<Combination, Long> = mutableMapOf() val mutablePolymer = countPerElement.toMutableMap() combinationOccurrences.entries.forEach { (combination, occ) -> val insertion = rules.find { rule -> rule.combination == combination }?.insertion?.also { insertedElement -> mutablePolymer[insertedElement] = mutablePolymer[insertedElement]?.plus(occ) ?: occ } combination.insert(insertion).forEach { newCombo -> newCombinationOccurrences[newCombo] = newCombinationOccurrences[newCombo]?.plus(occ) ?: occ } } return Polymer(newCombinationOccurrences, mutablePolymer) } }

Kotlin

7662b3861ca53214e3e3a77c1af7b7c049f81f44

Advent-of-Code-2021

MIT License

src/Day08.kt

mkfsn

{"Kotlin": 29625}

fun main() { fun <T> rotate(table: MutableList<MutableList<T>>): MutableList<MutableList<T>> { val rows = table.size val cols = if (table.isNotEmpty()) table[0].size else 0 return MutableList<MutableList<T>>(cols) { _ -> ArrayList(rows) }.apply { table.forEachIndexed { i, row -> row.forEachIndexed { j, col -> this[j].add(i, col) } } } } fun part1(input: List<String>): Int { var treeMap: MutableList<MutableList<Int>> = input.toMutableList().map { row -> row.map { it - '0' }.toMutableList() }.toMutableList() var visibleMap: MutableList<MutableList<Boolean>> = input.map { MutableList(it.length) { false } }.toMutableList() fun traverse(treeMap: List<List<Int>>, visibleMap: MutableList<MutableList<Boolean>>) { treeMap.forEachIndexed { i, row -> var (leftMax, rightMax) = listOf(-1, -1) var leftIncrements = MutableList(row.size) { -1 } var rightIncrements = MutableList(row.size) { -1 } row.forEachIndexed { j, v -> leftIncrements[j] = leftMax leftMax = if (leftMax < v) v else leftMax } row.asReversed().forEachIndexed { j, v -> rightIncrements[row.size - j - 1] = rightMax rightMax = if (rightMax < v) v else rightMax } row.forEachIndexed { j, v -> if (v > leftIncrements[j] || v > rightIncrements[j]) visibleMap[i][j] = true } } } traverse(treeMap, visibleMap) treeMap = rotate(treeMap) visibleMap = rotate(visibleMap) traverse(treeMap, visibleMap) return visibleMap.sumOf { row -> row.count { it } } } fun part2(input: List<String>): Int { var treeMap: MutableList<MutableList<Int>> = input.toMutableList().map { row -> row.map { it - '0' }.toMutableList() }.toMutableList() var scoreMap: MutableList<MutableList<Int>> = input.map { MutableList(it.length) { 1 } }.toMutableList() fun countVisibleTrees(cur: Int, others: List<Int>) = others.indexOfFirst { it >= cur }.also { if (it == -1) return others.count { v -> v < cur } return it + 1 } fun traverse(treeMap: List<List<Int>>, scoreMap: MutableList<MutableList<Int>>) { treeMap.forEachIndexed { i, row -> row.forEachIndexed { j, v -> scoreMap[i][j] *= countVisibleTrees(v, (j - 1 downTo 0).map { k -> row[k] }) scoreMap[i][j] *= countVisibleTrees(v, (j + 1 until row.size).map { k -> row[k] }) } } } traverse(treeMap, scoreMap) treeMap = rotate(treeMap) scoreMap = rotate(scoreMap) traverse(treeMap, scoreMap) return scoreMap.maxOfOrNull { row -> row.max() }!! } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") check(part1(testInput) == 21) check(part2(testInput) == 8) val input = readInput("Day08") println(part1(input)) println(part2(input)) }

Kotlin

8c7bdd66f8550a82030127aa36c2a6a4262592cd

advent-of-code-kotlin-2022

Apache License 2.0

src/Day08.kt

buczebar

{"Kotlin": 39213}

fun main() { fun parseInput(name: String) = readInput(name).map { it.toList() }.map { row -> row.map { height -> height.digitToInt() } } fun getListOfTrees(input: List<List<Int>>): List<Tree> { val columns = input.transpose() val (width, height) = columns.size to input.size val resultList = mutableListOf<Tree>() input.forEachIndexed { rowIndex, row -> columns.forEachIndexed { colIndex, column -> resultList.add(Tree( height = input[rowIndex][colIndex], allOnLeft = row.subList(0, colIndex).reversed(), allOnRight = colIndex.takeIf { it < width - 1 }?.let { row.subList(it + 1, width) } ?: emptyList(), allOnTop = column.subList(0, rowIndex).reversed(), allOnBottom = rowIndex.takeIf { it < height - 1 }?.let { column.subList(it + 1, height) } ?: emptyList() )) } } return resultList } fun part1(input: List<Tree>) = input.count { it.isVisible } fun part2(input: List<Tree>) = input.maxOfOrNull { it.scenicScore } val testInput = getListOfTrees(parseInput("Day08_test")) check(part1((testInput)) == 21) check(part2(testInput) == 8) val input = getListOfTrees(parseInput("Day08")) println(part1(input)) println(part2(input)) } private data class Tree( val height: Int, val allOnLeft: List<Int>, val allOnRight: List<Int>, val allOnTop: List<Int>, val allOnBottom: List<Int> ) { private val maxInAllDirections: List<Int> get() = allDirections.map { it.takeIf { it.isNotEmpty() }?.max() ?: 0 } private val allDirections: List<List<Int>> get() = listOf(allOnLeft, allOnRight, allOnTop, allOnBottom) private val visibleTreesInAllDirection: List<Int> get() = allDirections.map { it.numberOfVisibleTrees() } val isVisible: Boolean get() = allDirections.any { it.isEmpty() }.or(maxInAllDirections.min() < height) val scenicScore: Int get() = visibleTreesInAllDirection.reduce { acc, numOfTrees -> acc * numOfTrees } private fun List<Int>.numberOfVisibleTrees(): Int = indexOfFirst { it >= height }.takeIf { it >= 0 }?.plus(1) ?: size }

Kotlin

cdb6fe3996ab8216e7a005e766490a2181cd4101

advent-of-code

Apache License 2.0

src/main/kotlin/aoc2020/TicketTranslation.kt

komu

{"Kotlin": 395919}

package komu.adventofcode.aoc2020 import komu.adventofcode.utils.nonEmptyLines import komu.adventofcode.utils.product fun ticketTranslation1(input: String): Int { val (rules, _, nearbyTickets) = parseTicketData(input) return nearbyTickets.sumBy { ticket -> ticket.filter { v -> !rules.any { it.isSatisfiedBy(v) } }.sum() } } fun ticketTranslation2(input: String): Long { val (rules, myTicket, nearbyTickets) = parseTicketData(input) val validNearbyTickets = nearbyTickets.filter { t -> t.none { v -> !rules.any { it.isSatisfiedBy(v) } } } val assignment = resolveAssignments(rules, validNearbyTickets) val indices = assignment.filterKeys { it.name.startsWith("departure") }.values return indices.map { i -> myTicket[i].toLong() }.product() } private typealias Ticket = List<Int> private fun resolveAssignments(rules: List<TicketRule>, tickets: Collection<Ticket>): Map<TicketRule, Int> { val candidatesByIndex = List(rules.size) { index -> rules.filter { rule -> tickets.all { rule.isSatisfiedBy(it[index]) } }.toMutableSet() } while (candidatesByIndex.any { it.size > 1 }) { val uniqueRules = candidatesByIndex.filter { it.size == 1 }.map { it.first() } for (ruleSet in candidatesByIndex) if (ruleSet.size > 1) ruleSet -= uniqueRules } return candidatesByIndex.map { it.single() }.mapIndexed { index, rule -> rule to index }.toMap() } private class TicketRule( val name: String, private val range1: ClosedRange<Int>, private val range2: ClosedRange<Int> ) { fun isSatisfiedBy(value: Int) = value in range1 || value in range2 companion object { private val ruleRegex = Regex("""([\w\s]+): (\d+)-(\d+) or (\d+)-(\d+)""") fun parse(rule: String): TicketRule { val (name, min1, max1, min2, max2) = ruleRegex.matchEntire(rule)?.groupValues?.drop(1) ?: error("invalid rule '$rule'") return TicketRule(name, min1.toInt()..max1.toInt(), min2.toInt()..max2.toInt()) } } } private fun parseTicketData(input: String): Triple<List<TicketRule>, Ticket, List<Ticket>> { val (rulesStr, myTicketStr, nearbyTicketsStr) = input.split("\n\n") val rules = rulesStr.nonEmptyLines().map { TicketRule.parse(it) } val myTicket = parseTicket(myTicketStr.removePrefix("your ticket:\n")) val nearbyTickets = nearbyTicketsStr.removePrefix("nearby tickets:\n").nonEmptyLines().map { parseTicket(it) } return Triple(rules, myTicket, nearbyTickets) } private fun parseTicket(line: String) = line.split(",").map { it.toInt() }

Kotlin

8e135f80d65d15dbbee5d2749cccbe098a1bc5d8

advent-of-code

MIT License

src/Day08.kt

jstapels

{"Kotlin": 74335}

fun main() { fun getCol(nums: List<List<Int>>, col: Int) = nums.indices.map { nums[it][col] } fun visible(trees: List<List<Int>>, pos: Pos) = { h:Int -> h < trees[pos.y][pos.x] }.let { trees[pos.y].take(pos.x).all(it) || trees[pos.y].takeLast(trees[pos.y].size - pos.x - 1).all(it) || getCol(trees, pos.x).take(pos.y).all(it) || getCol(trees, pos.x).takeLast(trees[pos.y].size - pos.y - 1).all(it) } fun parseInput(input: List<String>) = input.map { it.toCharArray().map { c -> c.digitToInt() } } fun part1(input: List<String>): Int { val trees = parseInput(input) return trees.indices .flatMap { row -> trees[row].indices.map { col -> Pos(col, row) } } .count { visible(trees, it) } } fun treeCount(trees: List<Int>, height: Int) = trees.indexOfFirst { it >= height } .let { if (it == -1) trees.size else it + 1 } fun scenic(trees: List<List<Int>>, pos: Pos): Int { val (col, row) = pos val height = trees[row][col] val maxRow = trees.size - 1 val maxCol = trees[0].size - 1 return treeCount(trees[row].take(col).reversed(), height) * treeCount(trees[row].takeLast(maxCol - col), height) * treeCount(getCol(trees, col).take(row).reversed(), height) * treeCount(getCol(trees, col).takeLast(maxRow - row), height) } fun part2(input: List<String>): Int { val trees = parseInput(input) return trees.indices .flatMap { row -> trees[row].indices.map { col -> Pos(col, row) } } .maxOf { scenic(trees, it) } } // test if implementation meets criteria from the description, like: val testInput = readInput("Day08_test") checkThat(part1(testInput), 21) checkThat(part2(testInput), 8) val input = readInput("Day08") println(part1(input)) println(part2(input)) }

Kotlin

0d71521039231c996e2c4e2d410960d34270e876

aoc22

Apache License 2.0

src/day13/Day13.kt

Volifter

{"Kotlin": 65483}

package day13 import utils.* class Packet(private val items: List<Any>) : Comparable<Packet> { constructor(str: String) : this( splitList(str.substring(1 until str.lastIndex)) .filter { it.isNotEmpty() } .map { it.toIntOrNull() ?: Packet(it) } ) override fun compareTo(other: Packet): Int = (items + null) .zip(other.items + null) .asSequence() .map { (left, right) -> when { (left is Int && right is Int) -> left - right (left is Packet && right is Packet) -> left.compareTo(right) (left is Packet && right is Int) -> left.compareTo( Packet(listOf(right)) ) (left is Int && right is Packet) -> -right.compareTo( Packet(listOf(left)) ) (left == null && right == null) -> 0 (left == null) -> -1 (right == null) -> 1 else -> 0 } } .find { it != 0 } ?: 0 companion object { private fun splitList(str: String): List<String> = str.fold(Pair(listOf(""), 0)) { (lists, depth), c -> val groups = ( if (c == ',' && depth == 0) lists + "" else lists.dropLast(1) + (lists.last() + c) ) val deltaDepth = when (c) { '[' -> 1 ']' -> -1 else -> 0 } Pair(groups, depth + deltaDepth) }.first } } fun readPackets(input: List<String>): List<Packet> = input.mapNotNull { line -> line .takeIf(String::isNotEmpty) ?.let(::Packet) } fun part1(input: List<String>): Int = readPackets(input) .chunked(2) .withIndex() .filter { (_, pair) -> pair[0] <= pair[1] } .sumOf { (i, _) -> i + 1 } fun part2(input: List<String>): Int { val packets = readPackets(input) val packetA = Packet("[[2]]") val packetB = Packet("[[6]]") return (packets.count { it < packetA } + 1) * (packets.count { it < packetB } + 2) } fun main() { val testInput = readInput("Day13_test") expect(part1(testInput), 13) expect(part2(testInput), 140) val input = readInput("Day13") println(part1(input)) println(part2(input)) }

Kotlin

c2c386844c09087c3eac4b66ee675d0a95bc8ccc

AOC-2022-Kotlin

Apache License 2.0