return [rgb_tuple[0], rgb_tuple[1], rgb_tuple[2], 1] if __name__ == '__main__': ''' Cool looking seed values 2, 52, 94, 124396, 123456789, 123454321''' from function_generator import FunctionGenerator as FG unary_ops = { "sin": lambda x: np.sin(x), "cos": lambda x: np.cos(x), "tan": lambda x: np.tan(x), "sinh": lambda x: np.sinh(x), "cosh": lambda x: np.cosh(x), "tanh": lambda x: np.tanh(x), "repr": lambda x: 1 / x, } f_gen = FG(unary_op=unary_ops) f1 = f_gen.generate_function(rand_seed=5) def f(z): ans = f1(z) if np.isfinite(ans): return ans else: return 0 d = Domain(-3, 3, -3, 3) f_p = FunctionPlot(f, domain_colouring, d, 512, 512, grid=False) f_p.save() f_p.plot()
"repr": lambda x: 1 / complex(x), "exp": lambda x: np.exp(x), "log": lambda x: np.log(x), } binary_ops = { "add": lambda x, y: complex(x) + complex(y), "sub": lambda x, y: complex(x) - complex(y), "mul": lambda x, y: complex(x) * complex(y), "div": lambda x, y: complex(x) / complex(y), } while True: done = False try: f_gen = FG(unary_op=unary_ops, binary_op=binary_ops) f1 = f_gen.generate_function() def f(z): ans = f1(z) if np.isfinite(ans): return ans else: return 0 d = d_c.Domain(-3, 3, -3, 3) f_p = d_c.FunctionPlot(f, d_c.domain_colouring, d, 512, 512, grid=False)