#!/usb/bin/env python3 #run with: #gnome-terminal --hide-menubar --window-with-profile=manjaro -x python -i $HOME/.local/opt/python-interactive-imports.py import numpy as np from numpy import gcd, array, arange, linspace, meshgrid from numpy import cos, pi, sin, exp, log, log10, sqrt #from math import cos, pi, sin, exp, log, log10, sqrt, acos, asin, atan from math import acos, asin, atan, factorial from statistics import * from pprint import pprint from dis import dis import os, sys import functools import typing from functools import reduce from pathlib import Path from objexplore import explore p = pprint def plot(x, *args, label=[]): import matplotlib.pyplot as plt for i in args: plt.plot(x[:len(i)], i) plt.show() def hist(x, bins=20): import matplotlib.pyplot as plt plt.hist(x, bins) plt.show() def scatter(x, *args): import matplotlib.pyplot as plt for i in args: plt.plot(x[:len(i)], i, ".") plt.show() def imshow(image, cmap="gray"): import matplotlib.pyplot as plt plt.imshow(image.astype(np.float32), cmap=cmap) plt.show() def image(filepath=None, gray=False): if not filepath: import cv2 cam = cv2.VideoCapture(0) s, im = cam.read() # captures image cv2.destroyAllWindows() im = im.astype(np.float64) / 256 if not gray: return np.dstack(( im[:,:,2], im[:,:,1], im[:,:,0], )) else: return ( im[:,:,2] + im[:,:,1] + im[:,:,0]) / 3 else: import matplotlib.image as mpimg img=mpimg.imread('image_name.png') def rad(degrees): return degrees * pi / 180 def deg(radians): return radians / pi * 180 def clip(data): "xclip -sel clip" import subprocess p = subprocess.Popen(("xclip", "-sel", "clip"), stdin=subprocess.PIPE) p.communicate(str(data).encode("utf-8")) def prod(args): return functools.reduce(lambda x, y: x*y, args) def add(*args): return sum(args) def mul(*args): return prod(args) def history(n=None): import readline return "\n".join([ readline.get_history_item(i + 1) for i in range(readline.get_current_history_length()) ][-(n+1) if n is not None else 0:-1]) def integral(data, initial=0, step=None): if step is None: step = (data[-1] - data[0]) / len(data) out = [initial] for i in data: out.append(out[-1] + i*step) return out[1:]