def getDepthAndTargetLocationFromFile(fileName):
	for line in getFileAsListOfString(fileName):
		depthMatch = re.match("^depth: (\d+)$", line)
		targetMatch = re.match("^target: (\d+),(\d+)", line)
		if depthMatch:
			depth = int(depthMatch.group(1))
		elif targetMatch:
			target = (int(targetMatch.group(1)), int(targetMatch.group(2)))
	return (depth, target)
Beispiel #2
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 def getTrackSystemFromFile(self, fileName):
     trackSystem = TrackSystem()
     lines = getFileAsListOfString(fileName)
     for y in range(len(lines)):
         line = lines[y].rstrip()
         for x in range(len(line)):
             symbol = line[x]
             if symbol != " ":
                 self._addTrackAndOrCart(trackSystem, x, y, symbol)
     return trackSystem
Beispiel #3
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def getInstructionsAndExamplesFromFile(fileName):
	"""
	Returns (instructions, instructionExamples), where:
	- instructions is a list. Each element in the list (an instruction) is a list of integers.
	- instructionExamples is a list of InstructionExample.
	"""
	instructions = []
	instructionExamples = []
	lines = getFileAsListOfString(fileName)
	while len(lines) > 0:
		line = lines.pop(0)
		matchBefore = re.match("^Before: *(\[.*\])", line)
		if matchBefore:
			registersBefore = stringToIntegerList(matchBefore.group(1))
			instruction = stringToIntegerList(lines.pop(0))
			matchAfter = re.match("^After: *(\[.*\])", lines.pop(0))
			registersAfter = stringToIntegerList(matchAfter.group(1))
			instructionExample = InstructionExample(registersBefore, instruction, registersAfter)
			instructionExamples.append(instructionExample)
		elif len(line.strip()) > 0:
			instructions.append(stringToIntegerList(line))
	return (instructions, instructionExamples)
    print("Part 1: {} nanobots are in range".format(part1))


def part2(nanobots):
    (pos, size) = getBoundingBox([x.pos for x in nanobots])
    initialNode = SearchNode(pos, size, nanobots)
    (solutionNodes, stats) = AStar([initialNode],
                                   ascending=False).findBestSolutions()
    print(
        "Nodes created: {c}  Evaluated: {e}  Skipped: {s}  Remaining in list: {l}"
        .format(c=stats.created,
                e=stats.evaluated,
                s=stats.skipped,
                l=stats.created - (stats.evaluated + stats.skipped)))
    print("Number of solutions: {}".format(len(solutionNodes)))
    for node in solutionNodes:
        print("Part 2: Distance is {}".format(
            getManhattanDistance3((0, 0, 0), node.pos)))


########
# Main #
########
if __name__ == "__main__":
    nanobots = [
        Nanobot.createFromString(x)
        for x in getFileAsListOfString("input23.txt")
    ]
    part1(nanobots)
    part2(nanobots)
def getWorldFromFile(fileName):
    world = World()
    for line in getFileAsListOfString(fileName):
        (x, y, width, height) = stringToRectangle(line)
        world.addClay(x, y, width, height)
    return world
Beispiel #6
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def getPointsFromFile(fileName):
    return set(
        [getPointFromString(x) for x in getFileAsListOfString(fileName)])
def getEventsFromFile(fileName):
    return [
        Event.createFromString(s)
        for s in sorted(getFileAsListOfString(fileName))
    ]
    return positionToNrClaims


def findNonOverlappingClaim(positionToNrClaims, claims):
    for claim in claims:
        xRange = range(claim.x, claim.x + claim.width)
        yRange = range(claim.y, claim.y + claim.height)
        if not any(1 for x in xRange
                   for y in yRange if positionToNrClaims[(x, y)] > 1):
            return claim


########
# Main #
########
claims = [
    Claim.createFromString(line)
    for line in getFileAsListOfString("input03.txt")
]
positionToNrClaims = getPositionToNrClaims(claims)

# Part 1: How many squares are claimed by more than one elf?
numberOfOverlappingSquares = len(
    [1 for x in positionToNrClaims.values() if x > 1])
print("Number of squares with more than one claim: {}".format(
    numberOfOverlappingSquares))

# Part 2: What is the ID of the only claim that is not overlapping with any other claim?
nonOverlappingClaim = findNonOverlappingClaim(positionToNrClaims, claims)
print("Found non-overlapping claim: {}".format(nonOverlappingClaim))