【Pytorch】学习记录分享1——Tensor张量初始化与基本操作
1. 基础资料汇总
资料汇总
pytroch中文版本教程
PyTorch入门教程
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1.PyTorch简介
2.PyTorch环境搭建
basic: python numpy pandas pytroch
theory: study mlp cnn transform rnn
model: AlexNet VGG ResNet Yolo SSD
2. Tensor张量初始化与基本操作(numpy对比)
2.1 tensor 创建的集中基本方式
import numpy as np
import torch
np_a = np.array([1,2,3]) #ndarrays
tensor_a = torch.tensor([1,2,3]) #tensor
# tensor function and computer
tensor_b = torch.empty(5,3)
tensor_c = torch.randn(5,3) #用于确定模型的输入维度,做数据头尾
tensor_d = torch.zeros(5,3) #用于 x->y 训练的一个映射 神经网络y truth_label one_hot表示
tensor_e = torch.zeros(5,3,dtype= torch.long) # dtype 数据格式
print("np_a",np_a)
print("tensor_a", tensor_a)
print("tensor_b", tensor_b)
print("tensor_c", tensor_c)
print("tensor_d", tensor_d)
print("tensor_e", tensor_e)
import torch
#通过数据直接创建张量:
data = [[1, 2, 3], [4, 5, 6]]
tensor1 = torch.tensor(data)
print("tensor1",tensor1)
#使用特定形状的全零张量:
import torch
tensor2 = torch.zeros(2, 3)
print("tensor2",tensor2)
#使用特定形状的全一张量:
import torch
tensor3 = torch.ones(2, 3)
print("tensor3",tensor3)
#利用随机数创建张量:
import torch
tensor4 = torch.rand(2, 3)
print("tensor4",tensor4)
2.2 修改tensor/numpy长度与维度
# 基于已经存在的 tensor进行操作
x = torch.tensor([1,2,3])
x.new_ones(5,3) # 修改 x 的维度
tensor_f = torch.randn_like(x,dtype=torch.float) # 修改x 的类型与维度
print("tensor_f = ", tensor_f)
# 维度查看 np shape | tensor size 层到另外一个层 矩阵相乘
np.array([1, 2, 3]).shape
torch.tensor([1,2,3]).size()
# 更改维度 np reshape
y.size()
y.view(15)
y.view(15,1)
y.view(-1,5) # -1 表示自动计算,根据总维度/5得到
2.3 取 tensor/numpy 元素
y = np.array([[1,2,3],[4,5,6]])
np.array([[1,2,3],[4,5,6]])[0]
np.array([[1,2,3],[4,5,6]])[0,:] #":"表示不指定行,默认为该行所有
np.array([[1,2,3],[4,5,6]])[:,0]
print(y[:,0]) # 取第一列
print(y[0,:]) # 取第一行
y[3,0].item() # 常用 loss 反向传导 日志 打印查看 loss 是否减少 查看具体数值
2.4 numpy 对象的基本运算
import numpy as np
# 加法
result_array_add = np.array([1, 2]) + np.array([3, 4])
# 减法
result_array_sub = np.array([1, 2]) - np.array([3, 4])
# 乘法
result_array_mul = np.array([1, 2]) * np.array([3, 4])
# 除法
result_array_div = np.array([1, 2]) / np.array([3, 4])
# 数乘
result_array_scalar_mul = 2 * np.array([3, 4])
# 内积
result_array_dot = np.dot(np.array([1, 2]), np.array([3, 4]))
# 外积
result_array_outer = np.outer(np.array([1, 2]), np.array([3, 4]))
print("add = ", result_array_add)
print("sub = ", result_array_sub)
print("mul = ", result_array_mul)
print("div = ", result_array_div)
print("scalar_mul = ", result_array_scalar_mul)
print("dot = ", result_array_dot)
print("outer = ", result_array_outer)
2.5 tensor 对象的基本运算
import torch
# 加法
result_tensor_add = torch.tensor([1, 2]) + torch.tensor([3, 4])
# 减法
result_tensor_sub = torch.tensor([1, 2]) - torch.tensor([3, 4])
# 乘法
result_tensor_mul = torch.tensor([1, 2]) * torch.tensor([3, 4])
# 除法
result_tensor_div = torch.tensor([1, 2], dtype=torch.float) / torch.tensor([3, 4], dtype=torch.float)
# 数乘
result_tensor_scalar_mul = 2 * torch.tensor([3, 4])
# 内积
result_tensor_dot = torch.dot(torch.tensor([1, 2]), torch.tensor([3, 4]))
# 外积
result_tensor_outer = torch.ger(torch.tensor([1, 2]), torch.tensor([3, 4]))
print("add = ", result_tensor_add)
print("sub = ", result_tensor_sub)
print("mul = ", result_tensor_mul)
print("div = ", result_tensor_div)
print("scalar_mul = ", result_tensor_scalar_mul)
print("dot = ", result_tensor_dot)
print("outer = ", result_tensor_outer)
