AdventOfCode2021/source/day8/part1.d

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2021-12-08 06:58:28 +00:00
module day8.part1;
import std.file;
import std.stdio;
import std.string;
import std.algorithm;
import std.typecons;
import std.array;
import std.conv;
struct Entry {
string[] signalPatterns;
string[] outputValues;
}
Entry[] readEntries(string filename) {
return readText(filename).strip.split("\n")
.map!((line) {
auto parts = line.split("|");
return Entry(parts[0].strip.split(), parts[1].strip.split());
}).array;
}
ulong count1478(Entry[] entries) {
return entries.map!((entry) {
writeln(entry);
return entry.outputValues.filter!(v => v.length == 2 || v.length == 4 || v.length == 3 || v.length == 7).count;
}).sum();
}
int decodeEntry(Entry entry) {
int[string] knownSignals;
string[int] knownSignalsInverse;
void registerKnownSignal(string signal, int digit) {
knownSignals[signal] = digit;
knownSignalsInverse[digit] = signal;
}
// First we register all of the basic signals that will be used to identify others.
foreach (signal; entry.signalPatterns) {
if (signal.length == 2) {
registerKnownSignal(signal, 1);
}
if (signal.length == 3) {
registerKnownSignal(signal, 7);
}
if (signal.length == 4) {
registerKnownSignal(signal, 4);
}
if (signal.length == 7) {
registerKnownSignal(signal, 8);
}
}
bool matchesCount(string signal, int knownSignal, int requiredMatches = -1) {
int c = 0;
if (requiredMatches == -1) requiredMatches = cast(int) knownSignalsInverse[knownSignal].length;
foreach (segment; signal) {
if (knownSignalsInverse[knownSignal].canFind(segment)) c++;
}
return c == requiredMatches;
}
// Register all other signals using the ones we registered in the first pass.
foreach (signal; entry.signalPatterns) {
if (signal.length == 6) {
if (0 !in knownSignalsInverse && matchesCount(signal, 1) && matchesCount(signal, 7) && matchesCount(signal, 4, 3)) {
registerKnownSignal(signal, 0);
}
if (6 !in knownSignalsInverse && matchesCount(signal, 1, 1) && matchesCount(signal, 4, 3) && matchesCount(signal, 7, 2)) {
registerKnownSignal(signal, 6);
}
if (9 !in knownSignalsInverse && matchesCount(signal, 1) && matchesCount(signal, 4) && matchesCount(signal, 7)) {
registerKnownSignal(signal, 9);
}
}
if (signal.length == 5) {
if (2 !in knownSignalsInverse && matchesCount(signal, 1, 1) && matchesCount(signal, 4, 2) && matchesCount(signal, 7, 2)) {
registerKnownSignal(signal, 2);
}
if (3 !in knownSignalsInverse && matchesCount(signal, 1) && matchesCount(signal, 7) && matchesCount(signal, 4, 3)) {
registerKnownSignal(signal, 3);
}
if (5 !in knownSignalsInverse && matchesCount(signal, 1, 1) && matchesCount(signal, 4, 3) && matchesCount(signal, 7, 2)) {
registerKnownSignal(signal, 5);
}
}
}
bool areStringsPermutations(string a, string b) {
if (a.length != b.length) return false;
foreach (c; a) {
if (!b.canFind(c)) return false;
}
return true;
}
int[] resultDigits = [];
foreach (outputValue; entry.outputValues) {
foreach (knownSignal, digit; knownSignals) {
if (areStringsPermutations(outputValue, knownSignal)) {
resultDigits ~= digit;
break;
}
}
}
return resultDigits.map!(digit => digit.to!string).joiner().to!int;
}
void sevenSegmentSearch() {
"source/day8/input.txt".readEntries.map!(decodeEntry).sum.writeln;
}