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0.1.75

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guanjihuan
2024-01-09 19:46:17 +08:00
parent aca7b1ebe5
commit 7ecc569d80
11 changed files with 890 additions and 853 deletions
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2
PyPI/setup.cfg
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@@ -1,7 +1,7 @@
[metadata]
# replace with your username:
name = guan
version = 0.1.74
version = 0.1.75
author = guanjihuan
author_email = guanjihuan@163.com
description = An open source python package

2
PyPI/src/guan.egg-info/PKG-INFO
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@@ -1,6 +1,6 @@
Metadata-Version: 2.1
Name: guan
Version: 0.1.74
Version: 0.1.75
Summary: An open source python package
Home-page: https://py.guanjihuan.com
Author: guanjihuan

3
PyPI/src/guan.egg-info/SOURCES.txt
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@@ -9,7 +9,10 @@ src/guan/__init__.py
src/guan/band_structures_and_wave_functions.py
src/guan/basic_functions.py
src/guan/data_processing.py
src/guan/decorator.py
src/guan/density_of_states.py
src/guan/figure_plotting.py
src/guan/file_reading_and_writing.py
src/guan/machine_learning.py
src/guan/others.py
src/guan/quantum_transport.py

45
PyPI/src/guan/__init__.py
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@@ -1,47 +1,6 @@
# Guan is an open-source python package developed and maintained by https://www.guanjihuan.com/about (Ji-Huan Guan, 关济寰). The primary location of this package is on website https://py.guanjihuan.com. The GitHub location of this package is on https://github.com/guanjihuan/py.guanjihuan.com.
# 函数的装饰器,用于获取计算时间(秒)
def timer_decorator(func):
import time
def wrapper(*args, **kwargs):
start = time.time()
result = func(*args, **kwargs)
end = time.time()
print(f"Running time of {func.__name__}: {end - start} seconds")
return result
return wrapper
# 函数的装饰器,用于获取计算时间(分)
def timer_decorator_minutes(func):
import time
def wrapper(*args, **kwargs):
start = time.time()
result = func(*args, **kwargs)
end = time.time()
print(f"Running time of {func.__name__}: {(end - start)/60} minutes")
return result
return wrapper
# 函数的装饰器,用于获取计算时间(时)
def timer_decorator_hours(func):
import time
def wrapper(*args, **kwargs):
start = time.time()
result = func(*args, **kwargs)
end = time.time()
print(f"Running time of {func.__name__}: {(end - start)/3600} hours")
return result
return wrapper
# 函数的装饰器用于GUAN软件包的统计
def statistics_decorator(func):
def wrapper(*args, **kwargs):
result = func(*args, **kwargs)
import guan
guan.statistics_of_guan_package(func.__name__)
return result
return wrapper
from .decorator import *
from .basic_functions import *
from .Fourier_transform import *
from .Hamiltonian_of_examples import *
@@ -51,5 +10,7 @@ from .density_of_states import *
from .quantum_transport import *
from .topological_invariant import *
from .machine_learning import *
from .file_reading_and_writing import *
from .figure_plotting import *
from .data_processing import *
from .others import *

816
PyPI/src/guan/data_processing.py
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@@ -1,713 +1,6 @@
# Module: data_processing (including figure-plotting and file-reading/writing)
# Module: data_processing
import guan
# 导入plt, fig, ax
@guan.statistics_decorator
def import_plt_and_start_fig_ax(adjust_bottom=0.2, adjust_left=0.2, labelsize=20):
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
plt.subplots_adjust(bottom=adjust_bottom, left=adjust_left)
ax.grid()
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels()
[label.set_fontname('Times New Roman') for label in labels]
return plt, fig, ax
# 基于plt, fig, ax画图
@guan.statistics_decorator
def plot_without_starting_fig(plt, fig, ax, x_array, y_array, xlabel='x', ylabel='y', title='', fontsize=20, style='', y_min=None, y_max=None, linewidth=None, markersize=None, color=None):
if color==None:
ax.plot(x_array, y_array, style, linewidth=linewidth, markersize=markersize)
else:
ax.plot(x_array, y_array, style, linewidth=linewidth, markersize=markersize, color=color)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y_min=min(y_array)
if y_max==None:
y_max=max(y_array)
ax.set_ylim(y_min, y_max)
# 画图
@guan.statistics_decorator
def plot(x_array, y_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style='', y_min=None, y_max=None, linewidth=None, markersize=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x_array, y_array, style, linewidth=linewidth, markersize=markersize)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y_min=min(y_array)
if y_max==None:
y_max=max(y_array)
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 一组横坐标数据,两组纵坐标数据画图
@guan.statistics_decorator
def plot_two_array(x_array, y1_array, y2_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, markersize_1=None, markersize_2=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y_min=min([y1_min, y2_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y_max=max([y1_max, y2_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 两组横坐标数据,两组纵坐标数据画图
@guan.statistics_decorator
def plot_two_array_with_two_horizontal_array(x1_array, x2_array, y1_array, y2_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, markersize_1=None, markersize_2=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x1_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x2_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y_min=min([y1_min, y2_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y_max=max([y1_max, y2_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 一组横坐标数据,三组纵坐标数据画图
@guan.statistics_decorator
def plot_three_array(x_array, y1_array, y2_array, y3_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', style_3='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, linewidth_3=None,markersize_1=None, markersize_2=None, markersize_3=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.plot(x_array, y3_array, style_3, linewidth=linewidth_3, markersize=markersize_3)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y3_min=min(y3_array)
y_min=min([y1_min, y2_min, y3_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y3_max=max(y3_array)
y_max=max([y1_max, y2_max, y3_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 三组横坐标数据,三组纵坐标数据画图
@guan.statistics_decorator
def plot_three_array_with_three_horizontal_array(x1_array, x2_array, x3_array, y1_array, y2_array, y3_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', style_3='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, linewidth_3=None,markersize_1=None, markersize_2=None, markersize_3=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x1_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x2_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.plot(x3_array, y3_array, style_3, linewidth=linewidth_3, markersize=markersize_3)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y3_min=min(y3_array)
y_min=min([y1_min, y2_min, y3_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y3_max=max(y3_array)
y_max=max([y1_max, y2_max, y3_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 画三维图
@guan.statistics_decorator
def plot_3d_surface(x_array, y_array, matrix, xlabel='x', ylabel='y', zlabel='z', title='', fontsize=20, labelsize=15, show=1, save=0, filename='a', file_format='.jpg', dpi=300, z_min=None, z_max=None, rcount=100, ccount=100):
import numpy as np
import matplotlib.pyplot as plt
from matplotlib import cm
from matplotlib.ticker import LinearLocator
matrix = np.array(matrix)
fig, ax = plt.subplots(subplot_kw={"projection": "3d"})
plt.subplots_adjust(bottom=0.1, right=0.65)
x_array, y_array = np.meshgrid(x_array, y_array)
if len(matrix.shape) == 2:
surf = ax.plot_surface(x_array, y_array, matrix, rcount=rcount, ccount=ccount, cmap=cm.coolwarm, linewidth=0, antialiased=False)
elif len(matrix.shape) == 3:
for i0 in range(matrix.shape[2]):
surf = ax.plot_surface(x_array, y_array, matrix[:,:,i0], rcount=rcount, ccount=ccount, cmap=cm.coolwarm, linewidth=0, antialiased=False)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_zlabel(zlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.zaxis.set_major_locator(LinearLocator(5))
ax.zaxis.set_major_formatter('{x:.2f}')
if z_min!=None or z_max!=None:
if z_min==None:
z_min=matrix.min()
if z_max==None:
z_max=matrix.max()
ax.set_zlim(z_min, z_max)
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels() + ax.get_zticklabels()
[label.set_fontname('Times New Roman') for label in labels]
cax = plt.axes([0.8, 0.1, 0.05, 0.8])
cbar = fig.colorbar(surf, cax=cax)
cbar.ax.tick_params(labelsize=labelsize)
for l in cbar.ax.yaxis.get_ticklabels():
l.set_family('Times New Roman')
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 画Contour图
@guan.statistics_decorator
def plot_contour(x_array, y_array, matrix, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=15, cmap='jet', levels=None, show=1, save=0, filename='a', file_format='.jpg', dpi=300):
import numpy as np
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
plt.subplots_adjust(bottom=0.2, right=0.75, left=0.2)
x_array, y_array = np.meshgrid(x_array, y_array)
contour = ax.contourf(x_array,y_array,matrix,cmap=cmap, levels=levels)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels()
[label.set_fontname('Times New Roman') for label in labels]
cax = plt.axes([0.8, 0.2, 0.05, 0.68])
cbar = fig.colorbar(contour, cax=cax)
cbar.ax.tick_params(labelsize=labelsize)
for l in cbar.ax.yaxis.get_ticklabels():
l.set_family('Times New Roman')
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 画棋盘图/伪彩色图
@guan.statistics_decorator
def plot_pcolor(x_array, y_array, matrix, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=15, cmap='jet', levels=None, show=1, save=0, filename='a', file_format='.jpg', dpi=300):
import numpy as np
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
plt.subplots_adjust(bottom=0.2, right=0.75, left=0.2)
x_array, y_array = np.meshgrid(x_array, y_array)
contour = ax.pcolor(x_array,y_array,matrix, cmap=cmap)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels()
[label.set_fontname('Times New Roman') for label in labels]
cax = plt.axes([0.8, 0.2, 0.05, 0.68])
cbar = fig.colorbar(contour, cax=cax)
cbar.ax.tick_params(labelsize=labelsize)
for l in cbar.ax.yaxis.get_ticklabels():
l.set_family('Times New Roman')
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 通过坐标画点和线
@guan.statistics_decorator
def draw_dots_and_lines(coordinate_array, draw_dots=1, draw_lines=1, max_distance=1.1, line_style='-k', linewidth=1, dot_style='ro', markersize=3, show=1, save=0, filename='a', file_format='.eps', dpi=300):
import numpy as np
import matplotlib.pyplot as plt
coordinate_array = np.array(coordinate_array)
print(coordinate_array.shape)
x_range = max(coordinate_array[:, 0])-min(coordinate_array[:, 0])
y_range = max(coordinate_array[:, 1])-min(coordinate_array[:, 1])
fig, ax = plt.subplots(figsize=(6*x_range/y_range,6))
plt.subplots_adjust(left=0, bottom=0, right=1, top=1)
plt.axis('off')
if draw_lines==1:
for i1 in range(coordinate_array.shape[0]):
for i2 in range(coordinate_array.shape[0]):
if np.sqrt((coordinate_array[i1, 0] - coordinate_array[i2, 0])**2+(coordinate_array[i1, 1] - coordinate_array[i2, 1])**2) < max_distance:
ax.plot([coordinate_array[i1, 0], coordinate_array[i2, 0]], [coordinate_array[i1, 1], coordinate_array[i2, 1]], line_style, linewidth=linewidth)
if draw_dots==1:
for i in range(coordinate_array.shape[0]):
ax.plot(coordinate_array[i, 0], coordinate_array[i, 1], dot_style, markersize=markersize)
if show==1:
plt.show()
if save==1:
if file_format=='.eps':
plt.savefig(filename+file_format)
else:
plt.savefig(filename+file_format, dpi=dpi)
# 合并两个图片
@guan.statistics_decorator
def combine_two_images(image_path_array, figsize=(16,8), show=0, save=1, filename='a', file_format='.jpg', dpi=300):
import numpy as np
num = np.array(image_path_array).shape[0]
if num != 2:
print('Error: The number of images should be two!')
else:
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
fig = plt.figure(figsize=figsize)
plt.subplots_adjust(left=0, right=1, bottom=0, top=1, wspace=0, hspace=0)
ax1 = fig.add_subplot(121)
ax2 = fig.add_subplot(122)
image_1 = mpimg.imread(image_path_array[0])
image_2 = mpimg.imread(image_path_array[1])
ax1.imshow(image_1)
ax2.imshow(image_2)
ax1.axis('off')
ax2.axis('off')
if show == 1:
plt.show()
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
plt.close('all')
# 合并三个图片
@guan.statistics_decorator
def combine_three_images(image_path_array, figsize=(16,5), show=0, save=1, filename='a', file_format='.jpg', dpi=300):
import numpy as np
num = np.array(image_path_array).shape[0]
if num != 3:
print('Error: The number of images should be three!')
else:
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
fig = plt.figure(figsize=figsize)
plt.subplots_adjust(left=0, right=1, bottom=0, top=1, wspace=0, hspace=0)
ax1 = fig.add_subplot(131)
ax2 = fig.add_subplot(132)
ax3 = fig.add_subplot(133)
image_1 = mpimg.imread(image_path_array[0])
image_2 = mpimg.imread(image_path_array[1])
image_3 = mpimg.imread(image_path_array[2])
ax1.imshow(image_1)
ax2.imshow(image_2)
ax3.imshow(image_3)
ax1.axis('off')
ax2.axis('off')
ax3.axis('off')
if show == 1:
plt.show()
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
plt.close('all')
# 合并四个图片
@guan.statistics_decorator
def combine_four_images(image_path_array, figsize=(16,16), show=0, save=1, filename='a', file_format='.jpg', dpi=300):
import numpy as np
num = np.array(image_path_array).shape[0]
if num != 4:
print('Error: The number of images should be four!')
else:
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
fig = plt.figure(figsize=figsize)
plt.subplots_adjust(left=0, right=1, bottom=0, top=1, wspace=0, hspace=0)
ax1 = fig.add_subplot(221)
ax2 = fig.add_subplot(222)
ax3 = fig.add_subplot(223)
ax4 = fig.add_subplot(224)
image_1 = mpimg.imread(image_path_array[0])
image_2 = mpimg.imread(image_path_array[1])
image_3 = mpimg.imread(image_path_array[2])
image_4 = mpimg.imread(image_path_array[3])
ax1.imshow(image_1)
ax2.imshow(image_2)
ax3.imshow(image_3)
ax4.imshow(image_4)
ax1.axis('off')
ax2.axis('off')
ax3.axis('off')
ax4.axis('off')
if show == 1:
plt.show()
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
plt.close('all')
# 对某个目录中的txt文件批量读取和画图
@guan.statistics_decorator
def batch_reading_and_plotting(directory, xlabel='x', ylabel='y'):
import re
import os
import guan
for root, dirs, files in os.walk(directory):
for file in files:
if re.search('^txt.', file[::-1]):
filename = file[:-4]
x_array, y_array = guan.read_one_dimensional_data(filename=filename)
guan.plot(x_array, y_array, xlabel=xlabel, ylabel=ylabel, title=filename, show=0, save=1, filename=filename)
# 将图片制作GIF动画
@guan.statistics_decorator
def make_gif(image_path_array, filename='a', duration=0.1):
import imageio
images = []
for image_path in image_path_array:
im = imageio.imread(image_path)
images.append(im)
imageio.mimsave(filename+'.gif', images, 'GIF', duration=duration)
# 选取Matplotlib颜色
@guan.statistics_decorator
def color_matplotlib():
color_array = ['tab:blue', 'tab:orange', 'tab:green', 'tab:red', 'tab:purple', 'tab:brown', 'tab:pink', 'tab:gray', 'tab:olive', 'tab:cyan']
return color_array
# 如果不存在文件夹,则新建文件夹
@guan.statistics_decorator
def make_directory(directory='./test'):
import os
if not os.path.exists(directory):
os.makedirs(directory)
# 如果不存在文件,则新建空文件
@guan.statistics_decorator
def make_file(file_path='./a.txt'):
import os
if not os.path.exists(file_path):
with open(file_path, 'w') as f:
pass
# 读取文本文件内容,如果不存在,则新建空文件
@guan.statistics_decorator
def read_text_file(file_path='./a.txt'):
import os
if not os.path.exists(file_path):
with open(file_path, 'w') as f:
pass
return ''
else:
with open(file_path, 'r') as f:
content = f.read()
return content
# 将变量存到文件
@guan.statistics_decorator
def dump_data(data, filename, file_format='.txt'):
import pickle
with open(filename+file_format, 'wb') as f:
pickle.dump(data, f)
# 从文件中恢复数据到变量
@guan.statistics_decorator
def load_data(filename, file_format='.txt'):
import pickle
with open(filename+file_format, 'rb') as f:
data = pickle.load(f)
return data
# 读取文件中的一维数据一行一组x和y
@guan.statistics_decorator
def read_one_dimensional_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
for row in row_list:
column = np.array(row.split())
if column.shape[0] != 0:
x_array = np.append(x_array, [float(column[0])], axis=0)
y_row = np.zeros(dim_column-1)
for dim0 in range(dim_column-1):
y_row[dim0] = float(column[dim0+1])
if np.array(y_array).shape[0] == 0:
y_array = [y_row]
else:
y_array = np.append(y_array, [y_row], axis=0)
return x_array, y_array
# 读取文件中的一维数据一行一组x和y支持复数形式
@guan.statistics_decorator
def read_one_dimensional_complex_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
for row in row_list:
column = np.array(row.split())
if column.shape[0] != 0:
x_array = np.append(x_array, [complex(column[0])], axis=0)
y_row = np.zeros(dim_column-1, dtype=complex)
for dim0 in range(dim_column-1):
y_row[dim0] = complex(column[dim0+1])
if np.array(y_array).shape[0] == 0:
y_array = [y_row]
else:
y_array = np.append(y_array, [y_row], axis=0)
return x_array, y_array
# 读取文件中的二维数据(第一行和第一列分别为横纵坐标)
@guan.statistics_decorator
def read_two_dimensional_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
matrix = np.array([])
for i0 in range(row_list.shape[0]):
column = np.array(row_list[i0].split())
if i0 == 0:
x_str = column[1::]
x_array = np.zeros(x_str.shape[0])
for i00 in range(x_str.shape[0]):
x_array[i00] = float(x_str[i00])
elif column.shape[0] != 0:
y_array = np.append(y_array, [float(column[0])], axis=0)
matrix_row = np.zeros(dim_column-1)
for dim0 in range(dim_column-1):
matrix_row[dim0] = float(column[dim0+1])
if np.array(matrix).shape[0] == 0:
matrix = [matrix_row]
else:
matrix = np.append(matrix, [matrix_row], axis=0)
return x_array, y_array, matrix
# 读取文件中的二维数据(第一行和第一列分别为横纵坐标)(支持复数形式)
@guan.statistics_decorator
def read_two_dimensional_complex_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
matrix = np.array([])
for i0 in range(row_list.shape[0]):
column = np.array(row_list[i0].split())
if i0 == 0:
x_str = column[1::]
x_array = np.zeros(x_str.shape[0], dtype=complex)
for i00 in range(x_str.shape[0]):
x_array[i00] = complex(x_str[i00])
elif column.shape[0] != 0:
y_array = np.append(y_array, [complex(column[0])], axis=0)
matrix_row = np.zeros(dim_column-1, dtype=complex)
for dim0 in range(dim_column-1):
matrix_row[dim0] = complex(column[dim0+1])
if np.array(matrix).shape[0] == 0:
matrix = [matrix_row]
else:
matrix = np.append(matrix, [matrix_row], axis=0)
return x_array, y_array, matrix
# 读取文件中的二维数据不包括x和y
@guan.statistics_decorator
def read_two_dimensional_data_without_xy_array(filename='a', file_format='.txt'):
import numpy as np
matrix = np.loadtxt(filename+file_format)
return matrix
# 打开文件用于新增内容
@guan.statistics_decorator
def open_file(filename='a', file_format='.txt'):
f = open(filename+file_format, 'a', encoding='UTF-8')
return f
# 在文件中写入一维数据一行一组x和y
@guan.statistics_decorator
def write_one_dimensional_data(x_array, y_array, filename='a', file_format='.txt'):
import guan
with open(filename+file_format, 'w', encoding='UTF-8') as f:
guan.write_one_dimensional_data_without_opening_file(x_array, y_array, f)
# 在文件中写入一维数据一行一组x和y需要输入已打开的文件
@guan.statistics_decorator
def write_one_dimensional_data_without_opening_file(x_array, y_array, f):
import numpy as np
x_array = np.array(x_array)
y_array = np.array(y_array)
i0 = 0
for x0 in x_array:
f.write(str(x0)+' ')
if len(y_array.shape) == 1:
f.write(str(y_array[i0])+'\n')
elif len(y_array.shape) == 2:
for j0 in range(y_array.shape[1]):
f.write(str(y_array[i0, j0])+' ')
f.write('\n')
i0 += 1
# 在文件中写入二维数据(第一行和第一列分别为横纵坐标)
@guan.statistics_decorator
def write_two_dimensional_data(x_array, y_array, matrix, filename='a', file_format='.txt'):
import guan
with open(filename+file_format, 'w', encoding='UTF-8') as f:
guan.write_two_dimensional_data_without_opening_file(x_array, y_array, matrix, f)
# 在文件中写入二维数据(第一行和第一列分别为横纵坐标)(需要输入已打开的文件)
@guan.statistics_decorator
def write_two_dimensional_data_without_opening_file(x_array, y_array, matrix, f):
import numpy as np
x_array = np.array(x_array)
y_array = np.array(y_array)
matrix = np.array(matrix)
f.write('0 ')
for x0 in x_array:
f.write(str(x0)+' ')
f.write('\n')
i0 = 0
for y0 in y_array:
f.write(str(y0))
j0 = 0
for x0 in x_array:
f.write(' '+str(matrix[i0, j0])+' ')
j0 += 1
f.write('\n')
i0 += 1
# 在文件中写入二维数据不包括x和y
@guan.statistics_decorator
def write_two_dimensional_data_without_xy_array(matrix, filename='a', file_format='.txt'):
import guan
with open(filename+file_format, 'w', encoding='UTF-8') as f:
guan.write_two_dimensional_data_without_xy_array_and_without_opening_file(matrix, f)
# 在文件中写入二维数据不包括x和y需要输入已打开的文件
@guan.statistics_decorator
def write_two_dimensional_data_without_xy_array_and_without_opening_file(matrix, f):
for row in matrix:
for element in row:
f.write(str(element)+' ')
f.write('\n')
import guan
# 以显示编号的样式,打印数组
@guan.statistics_decorator
def print_array_with_index(array, show_index=1, index_type=0):
if show_index==0:
for i0 in array:
print(i0)
else:
if index_type==0:
index = 0
for i0 in array:
print(index, i0)
index += 1
else:
index = 0
for i0 in array:
index += 1
print(index, i0)
# 获取目录中的所有文件名
@guan.statistics_decorator
def get_all_filenames_in_directory(directory='./', file_format=None):
import os
file_list = []
for root, dirs, files in os.walk(directory):
for i0 in range(len(files)):
if file_format == None:
file_list.append(files[i0])
else:
if file_format in files[i0]:
file_list.append(files[i0])
return file_list
# 获取目录中的所有文件名(不包括子目录)
@guan.statistics_decorator
def get_all_filenames_in_directory_without_subdirectory(directory='./', file_format=None):
import os
file_list = []
for root, dirs, files in os.walk(directory):
for i0 in range(len(files)):
if file_format == None:
file_list.append(files[i0])
else:
if file_format in files[i0]:
file_list.append(files[i0])
break
return file_list
# 获取文件夹中某种文本类型的文件路径以及读取内容
@guan.statistics_decorator
def read_text_files_in_directory(directory='./', file_format='.md'):
import os
file_list = []
for root, dirs, files in os.walk(directory):
for i0 in range(len(files)):
if file_format in files[i0]:
file_list.append(root+'/'+files[i0])
content_array = []
for file in file_list:
with open(file, 'r') as f:
content_array.append(f.read())
return file_list, content_array
# 在多个文本文件中查找关键词
@guan.statistics_decorator
def find_words_in_multiple_files(words, directory='./', file_format='.md'):
import guan
file_list, content_array = guan.read_text_files_in_directory(directory=directory, file_format=file_format)
num_files = len(file_list)
file_list_with_words = []
for i0 in range(num_files):
if words in content_array[i0]:
file_list_with_words.append(file_list[i0])
return file_list_with_words
# 并行计算前的预处理,把参数分成多份
@guan.statistics_decorator
def preprocess_for_parallel_calculations(parameter_array_all, cpus=1, task_index=0):
@@ -745,6 +38,24 @@ def generate_random_int_number_for_a_specific_seed(seed=0, x_min=0, x_max=10):
rand_num = np.random.randint(x_min, x_max) # 左闭右开[x_min, x_max)
return rand_num
# 以显示编号的样式,打印数组
@guan.statistics_decorator
def print_array_with_index(array, show_index=1, index_type=0):
if show_index==0:
for i0 in array:
print(i0)
else:
if index_type==0:
index = 0
for i0 in array:
print(index, i0)
index += 1
else:
index = 0
for i0 in array:
index += 1
print(index, i0)
# 使用jieba软件包进行分词
@guan.statistics_decorator
def divide_text_into_words(text):
@@ -752,18 +63,79 @@ def divide_text_into_words(text):
words = jieba.lcut(text)
return words
# 拼接两个PDF文件
# 根据一定的字符长度来分割文本
@guan.statistics_decorator
def combine_two_pdf_files(input_file_1='a.pdf', input_file_2='b.pdf', output_file='combined_file.pdf'):
import PyPDF2
output_pdf = PyPDF2.PdfWriter()
with open(input_file_1, 'rb') as file1:
pdf1 = PyPDF2.PdfReader(file1)
for page in range(len(pdf1.pages)):
output_pdf.add_page(pdf1.pages[page])
with open(input_file_2, 'rb') as file2:
pdf2 = PyPDF2.PdfReader(file2)
for page in range(len(pdf2.pages)):
output_pdf.add_page(pdf2.pages[page])
with open(output_file, 'wb') as combined_file:
output_pdf.write(combined_file)
def split_text(text, wrap_width=3000):
import textwrap
split_text_list = textwrap.wrap(text, wrap_width)
return split_text_list
# 判断某个字符是中文还是英文或其他
@guan.statistics_decorator
def check_Chinese_or_English(a):
if '\u4e00' <= a <= '\u9fff' :
word_type = 'Chinese'
elif '\x00' <= a <= '\xff':
word_type = 'English'
else:
word_type = 'Others'
return word_type
# 统计中英文文本的字数,默认不包括空格
@guan.statistics_decorator
def count_words(text, include_space=0, show_words=0):
import jieba
import guan
words = jieba.lcut(text)
new_words = []
if include_space == 0:
for word in words:
if word != ' ':
new_words.append(word)
else:
new_words = words
num_words = 0
new_words_2 = []
for word in new_words:
word_type = guan.check_Chinese_or_English(word[0])
if word_type == 'Chinese':
num_words += len(word)
for one_word in word:
new_words_2.append(one_word)
elif word_type == 'English' or 'Others':
num_words += 1
new_words_2.append(word)
if show_words == 1:
print(new_words_2)
return num_words
# 将RGB转成HEX
@guan.statistics_decorator
def rgb_to_hex(rgb, pound=1):
if pound==0:
return '%02x%02x%02x' % rgb
else:
return '#%02x%02x%02x' % rgb
# 将HEX转成RGB
@guan.statistics_decorator
def hex_to_rgb(hex):
hex = hex.lstrip('#')
length = len(hex)
return tuple(int(hex[i:i+length//3], 16) for i in range(0, length, length//3))
# 使用MD5进行散列加密
@guan.statistics_decorator
def encryption_MD5(password, salt=''):
import hashlib
password = salt+password
hashed_password = hashlib.md5(password.encode()).hexdigest()
return hashed_password
# 使用SHA-256进行散列加密
@guan.statistics_decorator
def encryption_SHA_256(password, salt=''):
import hashlib
password = salt+password
hashed_password = hashlib.sha256(password.encode()).hexdigest()
return hashed_password

41
PyPI/src/guan/decorator.py Normal file
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@@ -0,0 +1,41 @@
# 函数的装饰器,用于获取计算时间(秒)
def timer_decorator(func):
import time
def wrapper(*args, **kwargs):
start = time.time()
result = func(*args, **kwargs)
end = time.time()
print(f"Running time of {func.__name__}: {end - start} seconds")
return result
return wrapper
# 函数的装饰器,用于获取计算时间(分)
def timer_decorator_minutes(func):
import time
def wrapper(*args, **kwargs):
start = time.time()
result = func(*args, **kwargs)
end = time.time()
print(f"Running time of {func.__name__}: {(end - start)/60} minutes")
return result
return wrapper
# 函数的装饰器,用于获取计算时间(时)
def timer_decorator_hours(func):
import time
def wrapper(*args, **kwargs):
start = time.time()
result = func(*args, **kwargs)
end = time.time()
print(f"Running time of {func.__name__}: {(end - start)/3600} hours")
return result
return wrapper
# 函数的装饰器用于GUAN软件包的统计
def statistics_decorator(func):
def wrapper(*args, **kwargs):
result = func(*args, **kwargs)
import guan
guan.statistics_of_guan_package(func.__name__)
return result
return wrapper

403
PyPI/src/guan/figure_plotting.py Normal file
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@@ -0,0 +1,403 @@
# Module: figure_plotting
import guan
# 导入plt, fig, ax
@guan.statistics_decorator
def import_plt_and_start_fig_ax(adjust_bottom=0.2, adjust_left=0.2, labelsize=20):
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
plt.subplots_adjust(bottom=adjust_bottom, left=adjust_left)
ax.grid()
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels()
[label.set_fontname('Times New Roman') for label in labels]
return plt, fig, ax
# 基于plt, fig, ax画图
@guan.statistics_decorator
def plot_without_starting_fig(plt, fig, ax, x_array, y_array, xlabel='x', ylabel='y', title='', fontsize=20, style='', y_min=None, y_max=None, linewidth=None, markersize=None, color=None):
if color==None:
ax.plot(x_array, y_array, style, linewidth=linewidth, markersize=markersize)
else:
ax.plot(x_array, y_array, style, linewidth=linewidth, markersize=markersize, color=color)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y_min=min(y_array)
if y_max==None:
y_max=max(y_array)
ax.set_ylim(y_min, y_max)
# 画图
@guan.statistics_decorator
def plot(x_array, y_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style='', y_min=None, y_max=None, linewidth=None, markersize=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x_array, y_array, style, linewidth=linewidth, markersize=markersize)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y_min=min(y_array)
if y_max==None:
y_max=max(y_array)
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 一组横坐标数据,两组纵坐标数据画图
@guan.statistics_decorator
def plot_two_array(x_array, y1_array, y2_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, markersize_1=None, markersize_2=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y_min=min([y1_min, y2_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y_max=max([y1_max, y2_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 两组横坐标数据,两组纵坐标数据画图
@guan.statistics_decorator
def plot_two_array_with_two_horizontal_array(x1_array, x2_array, y1_array, y2_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, markersize_1=None, markersize_2=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x1_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x2_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y_min=min([y1_min, y2_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y_max=max([y1_max, y2_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 一组横坐标数据,三组纵坐标数据画图
@guan.statistics_decorator
def plot_three_array(x_array, y1_array, y2_array, y3_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', style_3='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, linewidth_3=None,markersize_1=None, markersize_2=None, markersize_3=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.plot(x_array, y3_array, style_3, linewidth=linewidth_3, markersize=markersize_3)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y3_min=min(y3_array)
y_min=min([y1_min, y2_min, y3_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y3_max=max(y3_array)
y_max=max([y1_max, y2_max, y3_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 三组横坐标数据,三组纵坐标数据画图
@guan.statistics_decorator
def plot_three_array_with_three_horizontal_array(x1_array, x2_array, x3_array, y1_array, y2_array, y3_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', style_3='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, linewidth_3=None,markersize_1=None, markersize_2=None, markersize_3=None, adjust_bottom=0.2, adjust_left=0.2):
import guan
plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=adjust_bottom, adjust_left=adjust_left, labelsize=labelsize)
ax.plot(x1_array, y1_array, style_1, linewidth=linewidth_1, markersize=markersize_1)
ax.plot(x2_array, y2_array, style_2, linewidth=linewidth_2, markersize=markersize_2)
ax.plot(x3_array, y3_array, style_3, linewidth=linewidth_3, markersize=markersize_3)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
if y_min!=None or y_max!=None:
if y_min==None:
y1_min=min(y1_array)
y2_min=min(y2_array)
y3_min=min(y3_array)
y_min=min([y1_min, y2_min, y3_min])
if y_max==None:
y1_max=max(y1_array)
y2_max=max(y2_array)
y3_max=max(y3_array)
y_max=max([y1_max, y2_max, y3_max])
ax.set_ylim(y_min, y_max)
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 画三维图
@guan.statistics_decorator
def plot_3d_surface(x_array, y_array, matrix, xlabel='x', ylabel='y', zlabel='z', title='', fontsize=20, labelsize=15, show=1, save=0, filename='a', file_format='.jpg', dpi=300, z_min=None, z_max=None, rcount=100, ccount=100):
import numpy as np
import matplotlib.pyplot as plt
from matplotlib import cm
from matplotlib.ticker import LinearLocator
matrix = np.array(matrix)
fig, ax = plt.subplots(subplot_kw={"projection": "3d"})
plt.subplots_adjust(bottom=0.1, right=0.65)
x_array, y_array = np.meshgrid(x_array, y_array)
if len(matrix.shape) == 2:
surf = ax.plot_surface(x_array, y_array, matrix, rcount=rcount, ccount=ccount, cmap=cm.coolwarm, linewidth=0, antialiased=False)
elif len(matrix.shape) == 3:
for i0 in range(matrix.shape[2]):
surf = ax.plot_surface(x_array, y_array, matrix[:,:,i0], rcount=rcount, ccount=ccount, cmap=cm.coolwarm, linewidth=0, antialiased=False)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_zlabel(zlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.zaxis.set_major_locator(LinearLocator(5))
ax.zaxis.set_major_formatter('{x:.2f}')
if z_min!=None or z_max!=None:
if z_min==None:
z_min=matrix.min()
if z_max==None:
z_max=matrix.max()
ax.set_zlim(z_min, z_max)
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels() + ax.get_zticklabels()
[label.set_fontname('Times New Roman') for label in labels]
cax = plt.axes([0.8, 0.1, 0.05, 0.8])
cbar = fig.colorbar(surf, cax=cax)
cbar.ax.tick_params(labelsize=labelsize)
for l in cbar.ax.yaxis.get_ticklabels():
l.set_family('Times New Roman')
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 画Contour图
@guan.statistics_decorator
def plot_contour(x_array, y_array, matrix, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=15, cmap='jet', levels=None, show=1, save=0, filename='a', file_format='.jpg', dpi=300):
import numpy as np
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
plt.subplots_adjust(bottom=0.2, right=0.75, left=0.2)
x_array, y_array = np.meshgrid(x_array, y_array)
contour = ax.contourf(x_array,y_array,matrix,cmap=cmap, levels=levels)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels()
[label.set_fontname('Times New Roman') for label in labels]
cax = plt.axes([0.8, 0.2, 0.05, 0.68])
cbar = fig.colorbar(contour, cax=cax)
cbar.ax.tick_params(labelsize=labelsize)
for l in cbar.ax.yaxis.get_ticklabels():
l.set_family('Times New Roman')
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 画棋盘图/伪彩色图
@guan.statistics_decorator
def plot_pcolor(x_array, y_array, matrix, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=15, cmap='jet', levels=None, show=1, save=0, filename='a', file_format='.jpg', dpi=300):
import numpy as np
import matplotlib.pyplot as plt
fig, ax = plt.subplots()
plt.subplots_adjust(bottom=0.2, right=0.75, left=0.2)
x_array, y_array = np.meshgrid(x_array, y_array)
contour = ax.pcolor(x_array,y_array,matrix, cmap=cmap)
ax.set_title(title, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_xlabel(xlabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.set_ylabel(ylabel, fontsize=fontsize, fontfamily='Times New Roman')
ax.tick_params(labelsize=labelsize)
labels = ax.get_xticklabels() + ax.get_yticklabels()
[label.set_fontname('Times New Roman') for label in labels]
cax = plt.axes([0.8, 0.2, 0.05, 0.68])
cbar = fig.colorbar(contour, cax=cax)
cbar.ax.tick_params(labelsize=labelsize)
for l in cbar.ax.yaxis.get_ticklabels():
l.set_family('Times New Roman')
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
if show == 1:
plt.show()
plt.close('all')
# 通过坐标画点和线
@guan.statistics_decorator
def draw_dots_and_lines(coordinate_array, draw_dots=1, draw_lines=1, max_distance=1.1, line_style='-k', linewidth=1, dot_style='ro', markersize=3, show=1, save=0, filename='a', file_format='.eps', dpi=300):
import numpy as np
import matplotlib.pyplot as plt
coordinate_array = np.array(coordinate_array)
print(coordinate_array.shape)
x_range = max(coordinate_array[:, 0])-min(coordinate_array[:, 0])
y_range = max(coordinate_array[:, 1])-min(coordinate_array[:, 1])
fig, ax = plt.subplots(figsize=(6*x_range/y_range,6))
plt.subplots_adjust(left=0, bottom=0, right=1, top=1)
plt.axis('off')
if draw_lines==1:
for i1 in range(coordinate_array.shape[0]):
for i2 in range(coordinate_array.shape[0]):
if np.sqrt((coordinate_array[i1, 0] - coordinate_array[i2, 0])**2+(coordinate_array[i1, 1] - coordinate_array[i2, 1])**2) < max_distance:
ax.plot([coordinate_array[i1, 0], coordinate_array[i2, 0]], [coordinate_array[i1, 1], coordinate_array[i2, 1]], line_style, linewidth=linewidth)
if draw_dots==1:
for i in range(coordinate_array.shape[0]):
ax.plot(coordinate_array[i, 0], coordinate_array[i, 1], dot_style, markersize=markersize)
if show==1:
plt.show()
if save==1:
if file_format=='.eps':
plt.savefig(filename+file_format)
else:
plt.savefig(filename+file_format, dpi=dpi)
# 合并两个图片
@guan.statistics_decorator
def combine_two_images(image_path_array, figsize=(16,8), show=0, save=1, filename='a', file_format='.jpg', dpi=300):
import numpy as np
num = np.array(image_path_array).shape[0]
if num != 2:
print('Error: The number of images should be two!')
else:
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
fig = plt.figure(figsize=figsize)
plt.subplots_adjust(left=0, right=1, bottom=0, top=1, wspace=0, hspace=0)
ax1 = fig.add_subplot(121)
ax2 = fig.add_subplot(122)
image_1 = mpimg.imread(image_path_array[0])
image_2 = mpimg.imread(image_path_array[1])
ax1.imshow(image_1)
ax2.imshow(image_2)
ax1.axis('off')
ax2.axis('off')
if show == 1:
plt.show()
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
plt.close('all')
# 合并三个图片
@guan.statistics_decorator
def combine_three_images(image_path_array, figsize=(16,5), show=0, save=1, filename='a', file_format='.jpg', dpi=300):
import numpy as np
num = np.array(image_path_array).shape[0]
if num != 3:
print('Error: The number of images should be three!')
else:
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
fig = plt.figure(figsize=figsize)
plt.subplots_adjust(left=0, right=1, bottom=0, top=1, wspace=0, hspace=0)
ax1 = fig.add_subplot(131)
ax2 = fig.add_subplot(132)
ax3 = fig.add_subplot(133)
image_1 = mpimg.imread(image_path_array[0])
image_2 = mpimg.imread(image_path_array[1])
image_3 = mpimg.imread(image_path_array[2])
ax1.imshow(image_1)
ax2.imshow(image_2)
ax3.imshow(image_3)
ax1.axis('off')
ax2.axis('off')
ax3.axis('off')
if show == 1:
plt.show()
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
plt.close('all')
# 合并四个图片
@guan.statistics_decorator
def combine_four_images(image_path_array, figsize=(16,16), show=0, save=1, filename='a', file_format='.jpg', dpi=300):
import numpy as np
num = np.array(image_path_array).shape[0]
if num != 4:
print('Error: The number of images should be four!')
else:
import matplotlib.pyplot as plt
import matplotlib.image as mpimg
fig = plt.figure(figsize=figsize)
plt.subplots_adjust(left=0, right=1, bottom=0, top=1, wspace=0, hspace=0)
ax1 = fig.add_subplot(221)
ax2 = fig.add_subplot(222)
ax3 = fig.add_subplot(223)
ax4 = fig.add_subplot(224)
image_1 = mpimg.imread(image_path_array[0])
image_2 = mpimg.imread(image_path_array[1])
image_3 = mpimg.imread(image_path_array[2])
image_4 = mpimg.imread(image_path_array[3])
ax1.imshow(image_1)
ax2.imshow(image_2)
ax3.imshow(image_3)
ax4.imshow(image_4)
ax1.axis('off')
ax2.axis('off')
ax3.axis('off')
ax4.axis('off')
if show == 1:
plt.show()
if save == 1:
plt.savefig(filename+file_format, dpi=dpi)
plt.close('all')
# 对某个目录中的txt文件批量读取和画图
@guan.statistics_decorator
def batch_reading_and_plotting(directory, xlabel='x', ylabel='y'):
import re
import os
import guan
for root, dirs, files in os.walk(directory):
for file in files:
if re.search('^txt.', file[::-1]):
filename = file[:-4]
x_array, y_array = guan.read_one_dimensional_data(filename=filename)
guan.plot(x_array, y_array, xlabel=xlabel, ylabel=ylabel, title=filename, show=0, save=1, filename=filename)
# 将图片制作GIF动画
@guan.statistics_decorator
def make_gif(image_path_array, filename='a', duration=0.1):
import imageio
images = []
for image_path in image_path_array:
im = imageio.imread(image_path)
images.append(im)
imageio.mimsave(filename+'.gif', images, 'GIF', duration=duration)
# 选取Matplotlib颜色
@guan.statistics_decorator
def color_matplotlib():
color_array = ['tab:blue', 'tab:orange', 'tab:green', 'tab:red', 'tab:purple', 'tab:brown', 'tab:pink', 'tab:gray', 'tab:olive', 'tab:cyan']
return color_array

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PyPI/src/guan/file_reading_and_writing.py Normal file
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# Module: file_reading_and_writing
import guan
# 使用pickle将变量保存到文件支持几乎所有对象类型
@guan.statistics_decorator
def dump_data(data, filename, file_format='.txt'):
import pickle
with open(filename+file_format, 'wb') as f:
pickle.dump(data, f)
# 使用pickle从文件中恢复数据到变量支持几乎所有对象类型
@guan.statistics_decorator
def load_data(filename, file_format='.txt'):
import pickle
with open(filename+file_format, 'rb') as f:
data = pickle.load(f)
return data
# 使用NumPy保存数组变量到npy文件二进制文件
@guan.statistics_decorator
def save_npy_data(data, filename):
import numpy as np
np.save(filename+'.npy', data)
# 使用NumPy从npy文件恢复数据到数组变量二进制文件
@guan.statistics_decorator
def load_npy_data(filename):
import numpy as np
data = np.load(filename+'.npy')
return data
# 使用NumPy保存数组变量到TXT文件文本文件
@guan.statistics_decorator
def save_txt_data(data, filename):
import numpy as np
np.savetxt(filename+'.txt', data)
# 使用NumPy从TXT文件恢复数据到数组变量文本文件
@guan.statistics_decorator
def load_txt_data(filename):
import numpy as np
data = np.loadtxt(filename+'.txt')
return data
# 读取文件中的一维数据一行一组x和y
@guan.statistics_decorator
def read_one_dimensional_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
for row in row_list:
column = np.array(row.split())
if column.shape[0] != 0:
x_array = np.append(x_array, [float(column[0])], axis=0)
y_row = np.zeros(dim_column-1)
for dim0 in range(dim_column-1):
y_row[dim0] = float(column[dim0+1])
if np.array(y_array).shape[0] == 0:
y_array = [y_row]
else:
y_array = np.append(y_array, [y_row], axis=0)
return x_array, y_array
# 读取文件中的一维数据一行一组x和y支持复数形式
@guan.statistics_decorator
def read_one_dimensional_complex_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
for row in row_list:
column = np.array(row.split())
if column.shape[0] != 0:
x_array = np.append(x_array, [complex(column[0])], axis=0)
y_row = np.zeros(dim_column-1, dtype=complex)
for dim0 in range(dim_column-1):
y_row[dim0] = complex(column[dim0+1])
if np.array(y_array).shape[0] == 0:
y_array = [y_row]
else:
y_array = np.append(y_array, [y_row], axis=0)
return x_array, y_array
# 读取文件中的二维数据(第一行和第一列分别为横纵坐标)
@guan.statistics_decorator
def read_two_dimensional_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
matrix = np.array([])
for i0 in range(row_list.shape[0]):
column = np.array(row_list[i0].split())
if i0 == 0:
x_str = column[1::]
x_array = np.zeros(x_str.shape[0])
for i00 in range(x_str.shape[0]):
x_array[i00] = float(x_str[i00])
elif column.shape[0] != 0:
y_array = np.append(y_array, [float(column[0])], axis=0)
matrix_row = np.zeros(dim_column-1)
for dim0 in range(dim_column-1):
matrix_row[dim0] = float(column[dim0+1])
if np.array(matrix).shape[0] == 0:
matrix = [matrix_row]
else:
matrix = np.append(matrix, [matrix_row], axis=0)
return x_array, y_array, matrix
# 读取文件中的二维数据(第一行和第一列分别为横纵坐标)(支持复数形式)
@guan.statistics_decorator
def read_two_dimensional_complex_data(filename='a', file_format='.txt'):
import numpy as np
f = open(filename+file_format, 'r')
text = f.read()
f.close()
row_list = np.array(text.split('\n'))
dim_column = np.array(row_list[0].split()).shape[0]
x_array = np.array([])
y_array = np.array([])
matrix = np.array([])
for i0 in range(row_list.shape[0]):
column = np.array(row_list[i0].split())
if i0 == 0:
x_str = column[1::]
x_array = np.zeros(x_str.shape[0], dtype=complex)
for i00 in range(x_str.shape[0]):
x_array[i00] = complex(x_str[i00])
elif column.shape[0] != 0:
y_array = np.append(y_array, [complex(column[0])], axis=0)
matrix_row = np.zeros(dim_column-1, dtype=complex)
for dim0 in range(dim_column-1):
matrix_row[dim0] = complex(column[dim0+1])
if np.array(matrix).shape[0] == 0:
matrix = [matrix_row]
else:
matrix = np.append(matrix, [matrix_row], axis=0)
return x_array, y_array, matrix
# 读取文件中的二维数据不包括x和y
@guan.statistics_decorator
def read_two_dimensional_data_without_xy_array(filename='a', file_format='.txt'):
import numpy as np
matrix = np.loadtxt(filename+file_format)
return matrix
# 打开文件用于新增内容
@guan.statistics_decorator
def open_file(filename='a', file_format='.txt'):
f = open(filename+file_format, 'a', encoding='UTF-8')
return f
# 在文件中写入一维数据一行一组x和y
@guan.statistics_decorator
def write_one_dimensional_data(x_array, y_array, filename='a', file_format='.txt'):
import guan
with open(filename+file_format, 'w', encoding='UTF-8') as f:
guan.write_one_dimensional_data_without_opening_file(x_array, y_array, f)
# 在文件中写入一维数据一行一组x和y需要输入已打开的文件
@guan.statistics_decorator
def write_one_dimensional_data_without_opening_file(x_array, y_array, f):
import numpy as np
x_array = np.array(x_array)
y_array = np.array(y_array)
i0 = 0
for x0 in x_array:
f.write(str(x0)+' ')
if len(y_array.shape) == 1:
f.write(str(y_array[i0])+'\n')
elif len(y_array.shape) == 2:
for j0 in range(y_array.shape[1]):
f.write(str(y_array[i0, j0])+' ')
f.write('\n')
i0 += 1
# 在文件中写入二维数据(第一行和第一列分别为横纵坐标)
@guan.statistics_decorator
def write_two_dimensional_data(x_array, y_array, matrix, filename='a', file_format='.txt'):
import guan
with open(filename+file_format, 'w', encoding='UTF-8') as f:
guan.write_two_dimensional_data_without_opening_file(x_array, y_array, matrix, f)
# 在文件中写入二维数据(第一行和第一列分别为横纵坐标)(需要输入已打开的文件)
@guan.statistics_decorator
def write_two_dimensional_data_without_opening_file(x_array, y_array, matrix, f):
import numpy as np
x_array = np.array(x_array)
y_array = np.array(y_array)
matrix = np.array(matrix)
f.write('0 ')
for x0 in x_array:
f.write(str(x0)+' ')
f.write('\n')
i0 = 0
for y0 in y_array:
f.write(str(y0))
j0 = 0
for x0 in x_array:
f.write(' '+str(matrix[i0, j0])+' ')
j0 += 1
f.write('\n')
i0 += 1
# 在文件中写入二维数据不包括x和y
@guan.statistics_decorator
def write_two_dimensional_data_without_xy_array(matrix, filename='a', file_format='.txt'):
import guan
with open(filename+file_format, 'w', encoding='UTF-8') as f:
guan.write_two_dimensional_data_without_xy_array_and_without_opening_file(matrix, f)
# 在文件中写入二维数据不包括x和y需要输入已打开的文件
@guan.statistics_decorator
def write_two_dimensional_data_without_xy_array_and_without_opening_file(matrix, f):
for row in matrix:
for element in row:
f.write(str(element)+' ')
f.write('\n')
# 如果不存在文件夹,则新建文件夹
@guan.statistics_decorator
def make_directory(directory='./test'):
import os
if not os.path.exists(directory):
os.makedirs(directory)
# 如果不存在文件,则新建空文件
@guan.statistics_decorator
def make_file(file_path='./a.txt'):
import os
if not os.path.exists(file_path):
with open(file_path, 'w') as f:
pass
# 读取文本文件内容,如果不存在,则新建空文件
@guan.statistics_decorator
def read_text_file(file_path='./a.txt'):
import os
if not os.path.exists(file_path):
with open(file_path, 'w') as f:
pass
return ''
else:
with open(file_path, 'r') as f:
content = f.read()
return content
# 获取目录中的所有文件名
@guan.statistics_decorator
def get_all_filenames_in_directory(directory='./', file_format=None):
import os
file_list = []
for root, dirs, files in os.walk(directory):
for i0 in range(len(files)):
if file_format == None:
file_list.append(files[i0])
else:
if file_format in files[i0]:
file_list.append(files[i0])
return file_list
# 获取目录中的所有文件名(不包括子目录)
@guan.statistics_decorator
def get_all_filenames_in_directory_without_subdirectory(directory='./', file_format=None):
import os
file_list = []
for root, dirs, files in os.walk(directory):
for i0 in range(len(files)):
if file_format == None:
file_list.append(files[i0])
else:
if file_format in files[i0]:
file_list.append(files[i0])
break
return file_list
# 获取文件夹中某种文本类型的文件路径以及读取内容
@guan.statistics_decorator
def read_text_files_in_directory(directory='./', file_format='.md'):
import os
file_list = []
for root, dirs, files in os.walk(directory):
for i0 in range(len(files)):
if file_format in files[i0]:
file_list.append(root+'/'+files[i0])
content_array = []
for file in file_list:
with open(file, 'r') as f:
content_array.append(f.read())
return file_list, content_array
# 在多个文本文件中查找关键词
@guan.statistics_decorator
def find_words_in_multiple_files(words, directory='./', file_format='.md'):
import guan
file_list, content_array = guan.read_text_files_in_directory(directory=directory, file_format=file_format)
num_files = len(file_list)
file_list_with_words = []
for i0 in range(num_files):
if words in content_array[i0]:
file_list_with_words.append(file_list[i0])
return file_list_with_words
# 复制一份文件
@guan.statistics_decorator
def copy_file(file1='./a.txt', file2='./b.txt'):
import shutil
shutil.copy(file1, file2)
# 拼接两个PDF文件
@guan.statistics_decorator
def combine_two_pdf_files(input_file_1='a.pdf', input_file_2='b.pdf', output_file='combined_file.pdf'):
import PyPDF2
output_pdf = PyPDF2.PdfWriter()
with open(input_file_1, 'rb') as file1:
pdf1 = PyPDF2.PdfReader(file1)
for page in range(len(pdf1.pages)):
output_pdf.add_page(pdf1.pages[page])
with open(input_file_2, 'rb') as file2:
pdf2 = PyPDF2.PdfReader(file2)
for page in range(len(pdf2.pages)):
output_pdf.add_page(pdf2.pages[page])
with open(output_file, 'wb') as combined_file:
output_pdf.write(combined_file)

6
PyPI/src/guan/machine_learning.py
View File

@@ -165,9 +165,9 @@ def batch_train_model(model, train_loader, optimizer='Adam', learning_rate=0.001
loss.backward()
optimizer.step()
losses.append(loss.item())
if print_show == 1:
if (epoch + 1) % 100 == 0:
print(epoch, loss.item())
if print_show == 1:
if (epoch + 1) % 100 == 0:
print(epoch, loss.item())
return model, losses
# 保存模型参数到文件

83
PyPI/src/guan/others.py
View File

@@ -19,76 +19,6 @@ def get_time(colon=True):
datetime_time = datetime_time.replace(':', '')
return datetime_time
# 判断某个字符是中文还是英文或其他
@guan.statistics_decorator
def check_Chinese_or_English(a):
if '\u4e00' <= a <= '\u9fff' :
word_type = 'Chinese'
elif '\x00' <= a <= '\xff':
word_type = 'English'
else:
word_type = 'Others'
return word_type
# 统计中英文文本的字数,默认不包括空格
@guan.statistics_decorator
def count_words(text, include_space=0, show_words=0):
import jieba
import guan
words = jieba.lcut(text)
new_words = []
if include_space == 0:
for word in words:
if word != ' ':
new_words.append(word)
else:
new_words = words
num_words = 0
new_words_2 = []
for word in new_words:
word_type = guan.check_Chinese_or_English(word[0])
if word_type == 'Chinese':
num_words += len(word)
for one_word in word:
new_words_2.append(one_word)
elif word_type == 'English' or 'Others':
num_words += 1
new_words_2.append(word)
if show_words == 1:
print(new_words_2)
return num_words
# 将RGB转成HEX
@guan.statistics_decorator
def rgb_to_hex(rgb, pound=1):
if pound==0:
return '%02x%02x%02x' % rgb
else:
return '#%02x%02x%02x' % rgb
# 将HEX转成RGB
@guan.statistics_decorator
def hex_to_rgb(hex):
hex = hex.lstrip('#')
length = len(hex)
return tuple(int(hex[i:i+length//3], 16) for i in range(0, length, length//3))
# 使用MD5进行散列加密
@guan.statistics_decorator
def encryption_MD5(password, salt=''):
import hashlib
password = salt+password
hashed_password = hashlib.md5(password.encode()).hexdigest()
return hashed_password
# 使用SHA-256进行散列加密
@guan.statistics_decorator
def encryption_SHA_256(password, salt=''):
import hashlib
password = salt+password
hashed_password = hashlib.sha256(password.encode()).hexdigest()
return hashed_password
# 自动先后运行程序
@guan.statistics_decorator
def run_programs_sequentially(program_files=['./a.py', './b.py'], execute='python ', show_time=0):
@@ -109,12 +39,6 @@ def run_programs_sequentially(program_files=['./a.py', './b.py'], execute='pytho
end = time.time()
print('Total running time = '+str((end-start)/60)+' min')
# 复制一份文件
@guan.statistics_decorator
def copy_file(file1='./a.txt', file2='./b.txt'):
import shutil
shutil.copy(file1, file2)
# 获取CPU使用率
@guan.statistics_decorator
def get_cpu_usage(interval=1):
@@ -197,13 +121,6 @@ def count_number_of_import_statements(filename, file_format='.py', num=1000):
import_statement_counter = Counter(import_array).most_common(num)
return import_statement_counter
# 根据一定的字符长度来分割文本
@guan.statistics_decorator
def split_text(text, wrap_width=3000):
import textwrap
split_text_list = textwrap.wrap(text, wrap_width)
return split_text_list
# 获取本月的所有日期
@guan.statistics_decorator
def get_days_of_the_current_month(str_or_datetime='str'):

5
README.md
View File

@@ -1,6 +1,6 @@
## Guan package
Guan is an open-source python package developed and maintained by https://www.guanjihuan.com/about (Ji-Huan Guan, 关济寰). With this package, you can calculate band structures, density of states, quantum transport and topological invariant of tight-binding models by invoking the functions you need. Other frequently used functions are also integrated, such as machine learning, figure plotting and file reading/writing.
Guan is an open-source python package developed and maintained by https://www.guanjihuan.com/about (Ji-Huan Guan, 关济寰). With this package, you can calculate band structures, density of states, quantum transport and topological invariant of tight-binding models by invoking the functions you need. Other frequently used functions are also integrated, such as machine learning, figure plotting, file reading and writing, and data processing.
The primary location of this package is on https://py.guanjihuan.com.
@@ -14,6 +14,7 @@ import guan
## Summary of API Reference
+ decorator
+ basic functions
+ Fourier transform
+ Hamiltonian of examples
@@ -23,6 +24,8 @@ import guan
+ quantum transport
+ topological invariant
+ machine learning
+ file reading and writing
+ figure plotting
+ data processing
+ others