self.next = next
class Player:
def __init__(self, elfID):
self.elfID = elfID
self.score = 0
def addScore(self, scoreToAdd):
self.score += scoreToAdd
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(9, True)
words = contents.split(' ')
totalPlayers = int(words[0])
totalMarbles = int(words[6])
# ------Parts 1 & 2------ #
# Place the first marble
currentMarble = Marble(0, 0, 0)
currentMarble.next = currentMarble
currentMarble.previous = currentMarble
part1Stop = totalMarbles
part2Stop = totalMarbles * 100
currentMarbleValue = 1
self.predecessors += 1
def removePredecessor(self):
self.predecessors -= 1
class TimeStamp:
def __init__(self, timeFinished, stepName):
self.timeFinished = timeFinished
self.stepName = stepName
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(7, True)
conditions = list(map(Condition, contents.split('\n')))
# ------Part 1------ #
# Make a conditions dictionary and save how many references a condition has:
stepsDictPt1 = {}
for condition in conditions:
if condition.parent not in stepsDictPt1:
stepsDictPt1[condition.parent] = Step(condition.parent)
stepsDictPt1[condition.parent].addChild(condition.child)
else:
stepsDictPt1[condition.parent].addChild(condition.child)
if condition.child not in stepsDictPt1:
stepsDictPt1[condition.child] = Step(condition.child)
stepsDictPt1[condition.child].addPredecessor()
from GetFile import getContents
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(1, True)
# Parse the frequencies and put them in a list
frequencies = list(map(int, contents.split("\n")))
# ------Part 1------ #
# Sum the entire list of frequencies
answer1 = sum(frequencies)
# ------Part 2------ #
# Keep track of frequencies we've seen
seenFrequencies = []
currentFrequency = 0
repeatFound = False
# Update the frequency list every step of the way
while not repeatFound:
for f in frequencies:
currentFrequency += f
# If we find a frequency we've already encoutered, stop and note the answer
if currentFrequency in seenFrequencies:
answer2 = currentFrequency
repeatFound = True
break
from GetFile import getContents
from blist import blist
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(5, True)
polymer = contents
# ------Part 1------ #
def collapsePolymer(polymerToCollapse, charToRemove):
# Remove any leading instances of the char to remove
while polymerToCollapse[-1].lower() == charToRemove.lower():
del polymerToCollapse[-1]
# Traverse the string backwards and delete any double entries.
# Only one pass is required due to how unit deletion works here.
for i in range(len(polymerToCollapse)-1, 0, -1):
# In case the units we collapsed were at the end of the string
if i > len(polymerToCollapse) - 1:
continue
currentUnit = polymerToCollapse[i]
nextUnit = polymerToCollapse[i-1]
# If we come across a forbidden char, we remove it.
# We continue the loop and have it decrease the index 1 by
# to continue where we left off.
if nextUnit.lower() == charToRemove.lower():
del polymerToCollapse[i-1]
continue
if currentUnit == nextUnit.swapcase():
# Deleting the units here moves all previous units down by 2 units.
from GetFile import getContents
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(2, True)
boxIDs = contents.split("\n")
# ------Part 1------ #
letter2 = 0
letter3 = 0
# Go through the entire list of boxes
for box in boxIDs:
# For a box ID, note how often each char appears
letterFreqs = {}
for char in box:
letterFreqs[char] = letterFreqs.get(char, 0) + 1
# Count whether or not this word has chars occurring twice or thrice
hasLetter2 = False
hasLetter3 = False
for letter, freq in letterFreqs.items():
if hasLetter2 and hasLetter3:
break
if freq == 2 and not hasLetter2:
hasLetter2 = True
elif freq == 3 and not hasLetter3:
hasLetter3 = True
lowerEdges = set()
else:
claims = self.sweepLineList[indexBefore].claims - self.sweepLineList[indexBefore].getLenLowerEdges()
lowerEdges = self.sweepLineList[indexBefore].rectIDs.difference(self.sweepLineList[indexBefore].lowerEdges)
newSLP = sweepLinePoint(point, claims, 1, lowerEdges)
if isLowerEdge:
newSLP.addLowerEdge(rectID)
self.sweepLineList.insert(insertAt, newSLP)
return insertAt
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(3, True)
rectangleStrings = contents.split("\n")
rectangles = list(map(Rectangle, rectangleStrings))
# ------Part 1 & 2------ #
rectangleDictionary = {rectObj.rectID: rectObj for rectObj in rectangles}
overlapsDictionary = {rectObj.rectID: 0 for rectObj in rectangles}
xLines = list(map(lambda rectObj: xLine(rectObj.x, rectObj.rectID, True), rectangles)) \
+ list(map(lambda rectObj: xLine(rectObj.x + rectObj.width, rectObj.rectID, False), rectangles))
xLines = sorted(xLines, key=lambda xl: (xl.x, xl.isLeftEdge, rectangleDictionary[xl.rectID].y))
sl = sweepLine()
previousX = 0
intersectionArea = 0
# Determine in which minute the guard slept the most
# Return tuple of form (Days slept, Minute slept on)
def getMinuteMostSleptIn(self):
currentDays = 0
currentBestMinute = (0, 0) # Days slept, Minute in question
for minit in range(0,60):
if minit in self.log:
currentDays += self.log[minit]
if currentDays > currentBestMinute[0]:
currentBestMinute = (currentDays, minit)
return currentBestMinute
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(4, True)
timestamps = list(map(TimeStamp, contents.split('\n')))
timestamps = sorted(timestamps, key=lambda ts: ts.date)
# ------Part 1------ #
# Loop through timestamps and update guards accordingly
guardList = {}
currentGuard = 0
minuteFellAsleep = 0
guardAsleep = False
sleepiestGuard = 0 # GuardID, minutes asleep
for ts in timestamps:
# Guard starts their shift
result.append((coordX, coordY))
return result
# Add a point captured by this coordinate
def addPointCaptured(self):
self.pointsCaptured += 1
# Remove a point captured by this coordinate
def removePointCaptured(self):
self.pointsCaptured -= 1
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(6, True)
# Adjust coordinate list to also add names to them
sepCoordinateStrList = contents.split('\n')
coordinateStrList = [
coordStr + ", " + str(chr(i + ord('a')))
for i, coordStr in enumerate(sepCoordinateStrList)
]
coordinateList = list(map(Coordinate, coordinateStrList))
coordinateDictionary = {coord.name: coord for coord in coordinateList}
# ------Part 1------ #
smallestX = int(min(crd.x for crd in coordinateList))
smallestY = int(min(crd.y for crd in coordinateList))
largestX = int(max(crd.x for crd in coordinateList))
words = split('<|>|, ', string)
self.position = (int(words[1]), int(words[2]))
self.velocity = (int(words[4]), int(words[5]))
def updatePosition(self):
self.position = (self.position[0] + self.velocity[0],
self.position[1] + self.velocity[1])
def addOffset(self, offset):
return self.position[0] + offset[0], self.position[1] + offset[1]
# ------Input------ #
answer1 = 0
answer2 = 0
contents = getContents(10, True)
starList = list(map(Star, contents.split('\n')))
# ------Part 1------ #
# Function that checks the score for a given list of stars
# It basically awards points for straight lines in one of the compass directions
def calculateScore(starDict):
score = 0
for starsAtThisPoint in starDict.values():
for star in starsAtThisPoint:
# We only need to look at two compass directions here: East and North
for k in range(0, 2):
scoreThisRound = 0
baseOffset = (int(sin(radians(90 * k))),
