advent-of-code/2022/python/shared.py

from contextlib import contextmanager
from timeit import default_timer
from pathlib import Path
import cProfile
import functools
import pstats


def profile(func):
    @functools.wraps(func)
    def inner(*args, **kwargs):
        profiler = cProfile.Profile()
        profiler.enable()
        try:
            retval = func(*args, **kwargs)
        finally:
            profiler.disable()
            with open("profile.out", "w") as profile_file:
                stats = pstats.Stats(profiler, stream=profile_file)
                stats.print_stats()
        return retval

    return inner


spl = lambda y: [int(w) for w in y]


def minmax(l):
    return min(l), max(l)


def load_rows(day):
    return [row for row in load(day)]


def load(day):
    path = Path(get_fname(day))
    return path.read_text().rstrip().split("\n")


def get_fname(day: int) -> str:
    import sys

    if sys.argv[-1] == "--sample":
        return f"../samples/day{day:02}.txt"
    else:
        return f"../full/day{day:02}.txt"


#############
def load_char_matrix(f):
    my_file = []
    for line in f:
        my_file.append(line.rstrip())
    return [list(x) for x in my_file]


def load_file_char_matrix(name):
    with open(name, "r") as f:
        return load_char_matrix(f)


def load_int_matrix(f):
    my_file = []
    for line in f:
        my_file.append(line.rstrip())
    return [list(map(int, x)) for x in my_file]


def load_file_int_matrix(name):
    with open(name, "r") as f:
        return load_int_matrix(f)


def load_word_matrix(f):
    my_file = []
    for line in f:
        my_file.append(line.rstrip())
    return [x.split(" ") for x in my_file]


def load_file_word_matrix(name):
    with open(name, "r") as f:
        return load_word_matrix(f)


#############


def rotate(WHAT, times=1):
    what = WHAT
    for x in range(times):
        what = list(zip(*what[::-1]))
    return what


@contextmanager
def elapsed_timer():
    start = default_timer()
    elapser = lambda: default_timer() - start
    yield lambda: elapser()
    end = default_timer()
    elapser = lambda: end - start


def render_cubes(maxX,maxY,maxZ, my_cubes):
    from mpl_toolkits.mplot3d import Axes3D
    import numpy as np
    import matplotlib.pyplot as plt
    from mpl_toolkits.mplot3d.art3d import Poly3DCollection
    
    def cuboid_data(o, size=(1,1,1)):
        X = [[[0, 1, 0], [0, 0, 0], [1, 0, 0], [1, 1, 0]],
             [[0, 0, 0], [0, 0, 1], [1, 0, 1], [1, 0, 0]],
             [[1, 0, 1], [1, 0, 0], [1, 1, 0], [1, 1, 1]],
             [[0, 0, 1], [0, 0, 0], [0, 1, 0], [0, 1, 1]],
             [[0, 1, 0], [0, 1, 1], [1, 1, 1], [1, 1, 0]],
             [[0, 1, 1], [0, 0, 1], [1, 0, 1], [1, 1, 1]]]
        X = np.array(X).astype(float)
        for i in range(3):
            X[:,:,i] *= size[i]
        X += np.array(o)
        return X
    
    def plotCubeAt(positions,sizes=None,colors=None, **kwargs):
        if not isinstance(colors,(list,np.ndarray)): colors=["C0"]*len(positions)
        if not isinstance(sizes,(list,np.ndarray)): sizes=[(1,1,1)]*len(positions)
        g = []
        for p,s,c in zip(positions,sizes,colors):
            g.append( cuboid_data(p, size=s) )
        return Poly3DCollection(np.concatenate(g),  
                                facecolors=np.repeat(colors,6, axis=0), **kwargs)
    
    N1 = maxX
    N2 = maxY
    N3 = maxZ
    ma = np.random.choice([0,1], size=(N1,N2,N3), p=[0.99, 0.01])
    x,y,z = np.indices((N1,N2,N3))-.5
    #positions = np.c_[x[ma==1],y[ma==1],z[ma==1]]
    positions = np.c_[my_cubes]
    colors= np.random.rand(len(positions),3)
    
    fig = plt.figure()
    ax = fig.add_subplot(projection='3d')
    ax.set_aspect('equal')
    
    pc = plotCubeAt(positions, colors=colors,edgecolor="k")
    ax.add_collection3d(pc)
    
    ax.set_xlim([0,maxX])
    ax.set_ylim([0,maxY])
    ax.set_zlim([0,maxZ])
    #plotMatrix(ax, ma)
    #ax.voxels(ma, edgecolor="k")
    
    plt.show()
day11 part1 - part 2 is stub only 2022-12-11 05:44:32 +00:00			`from contextlib import contextmanager`
			`from timeit import default_timer`
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`from pathlib import Path`
day14 make it go fasterrr 2022-12-14 19:00:11 +00:00			`import cProfile`
			`import functools`
			`import pstats`


day16 still working: 2022-12-17 03:07:17 +00:00			`def profile(func):`
day14 make it go fasterrr 2022-12-14 19:00:11 +00:00			`@functools.wraps(func)`
			`def inner(args, *kwargs):`
			`profiler = cProfile.Profile()`
			`profiler.enable()`
			`try:`
			`retval = func(args, *kwargs)`
			`finally:`
			`profiler.disable()`
day16 still working: 2022-12-17 03:07:17 +00:00			`with open("profile.out", "w") as profile_file:`
day14 make it go fasterrr 2022-12-14 19:00:11 +00:00			`stats = pstats.Stats(profiler, stream=profile_file)`
			`stats.print_stats()`
			`return retval`

			`return inner`
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00
day16 still working: 2022-12-17 03:07:17 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`spl = lambda y: [int(w) for w in y]`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
day 14 part 1 and 2 2022-12-14 07:38:19 +00:00			`def minmax(l):`
day16 still working: 2022-12-17 03:07:17 +00:00			`return min(l), max(l)`

day 14 part 1 and 2 2022-12-14 07:38:19 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def load_rows(day):`
			`return [row for row in load(day)]`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def load(day):`
			`path = Path(get_fname(day))`
			`return path.read_text().rstrip().split("\n")`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def get_fname(day: int) -> str:`
			`import sys`

			`if sys.argv[-1] == "--sample":`
			`return f"../samples/day{day:02}.txt"`
			`else:`
			`return f"../full/day{day:02}.txt"`


			`#############`
			`def load_char_matrix(f):`
			`my_file = []`
			`for line in f:`
			`my_file.append(line.rstrip())`
			`return [list(x) for x in my_file]`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def load_file_char_matrix(name):`
			`with open(name, "r") as f:`
			`return load_char_matrix(f)`


			`def load_int_matrix(f):`
			`my_file = []`
			`for line in f:`
			`my_file.append(line.rstrip())`
			`return [list(map(int, x)) for x in my_file]`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def load_file_int_matrix(name):`
			`with open(name, "r") as f:`
			`return load_int_matrix(f)`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def load_word_matrix(f):`
			`my_file = []`
			`for line in f:`
			`my_file.append(line.rstrip())`
			`return [x.split(" ") for x in my_file]`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def load_file_word_matrix(name):`
			`with open(name, "r") as f:`
			`return load_word_matrix(f)`
day12 not pretty at alllll 2022-12-12 07:41:14 +00:00

Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`#############`

day12 not pretty at alllll 2022-12-12 07:41:14 +00:00
Move 2022 and 2021 into place 2022-12-09 16:43:00 +00:00			`def rotate(WHAT, times=1):`
			`what = WHAT`
			`for x in range(times):`
			`what = list(zip(*what[::-1]))`
			`return what`
day11 part1 - part 2 is stub only 2022-12-11 05:44:32 +00:00

			`@contextmanager`
			`def elapsed_timer():`
			`start = default_timer()`
			`elapser = lambda: default_timer() - start`
			`yield lambda: elapser()`
			`end = default_timer()`
day12 not pretty at alllll 2022-12-12 07:41:14 +00:00			`elapser = lambda: end - start`
day18 almost 2022-12-18 16:02:25 +00:00



			`def render_cubes(maxX,maxY,maxZ, my_cubes):`
			`from mpl_toolkits.mplot3d import Axes3D`
			`import numpy as np`
			`import matplotlib.pyplot as plt`
			`from mpl_toolkits.mplot3d.art3d import Poly3DCollection`

			`def cuboid_data(o, size=(1,1,1)):`
			`X = [[[0, 1, 0], [0, 0, 0], [1, 0, 0], [1, 1, 0]],`
			`[[0, 0, 0], [0, 0, 1], [1, 0, 1], [1, 0, 0]],`
			`[[1, 0, 1], [1, 0, 0], [1, 1, 0], [1, 1, 1]],`
			`[[0, 0, 1], [0, 0, 0], [0, 1, 0], [0, 1, 1]],`
			`[[0, 1, 0], [0, 1, 1], [1, 1, 1], [1, 1, 0]],`
			`[[0, 1, 1], [0, 0, 1], [1, 0, 1], [1, 1, 1]]]`
			`X = np.array(X).astype(float)`
			`for i in range(3):`
			`X[:,:,i] *= size[i]`
			`X += np.array(o)`
			`return X`

			`def plotCubeAt(positions,sizes=None,colors=None, **kwargs):`
			`if not isinstance(colors,(list,np.ndarray)): colors=["C0"]*len(positions)`
			`if not isinstance(sizes,(list,np.ndarray)): sizes=[(1,1,1)]*len(positions)`
			`g = []`
			`for p,s,c in zip(positions,sizes,colors):`
			`g.append( cuboid_data(p, size=s) )`
			`return Poly3DCollection(np.concatenate(g),`
			`facecolors=np.repeat(colors,6, axis=0), **kwargs)`

			`N1 = maxX`
			`N2 = maxY`
			`N3 = maxZ`
			`ma = np.random.choice([0,1], size=(N1,N2,N3), p=[0.99, 0.01])`
			`x,y,z = np.indices((N1,N2,N3))-.5`
			`#positions = np.c_[x[ma==1],y[ma==1],z[ma==1]]`
			`positions = np.c_[my_cubes]`
			`colors= np.random.rand(len(positions),3)`

			`fig = plt.figure()`
			`ax = fig.add_subplot(projection='3d')`
			`ax.set_aspect('equal')`

			`pc = plotCubeAt(positions, colors=colors,edgecolor="k")`
			`ax.add_collection3d(pc)`

			`ax.set_xlim([0,maxX])`
			`ax.set_ylim([0,maxY])`
			`ax.set_zlim([0,maxZ])`
			`#plotMatrix(ax, ma)`
			`#ax.voxels(ma, edgecolor="k")`

			`plt.show()`