动态图机制-DyGraph
PaddlePaddle的DyGraph模式是一种动态的图执行机制,可以立即执行结果,无需构建整个图。同时,和以往静态的执行计算图不同,DyGraph模式下您的所有操作可以立即获得执行结果,而不必等待所构建的计算图全部执行完成,这样可以让您更加直观地构建PaddlePaddle下的深度学习任务,以及进行模型的调试,同时还减少了大量用于构建静态计算图的代码,使得您编写、调试网络的过程变得更加便捷。
PaddlePaddle DyGraph是一个更加灵活易用的模式,可提供:
更加灵活便捷的代码组织结构: 使用python的执行控制流程和面向对象的模型设计
更加便捷的调试功能: 直接使用python的打印方法即时打印所需要的结果,从而检查正在运行的模型结果便于测试更改
和静态执行图通用的模型代码:同样的模型代码可以使用更加便捷的DyGraph调试,执行,同时也支持使用原有的静态图模式执行
设置和基本用法
- 升级到最新的PaddlePaddle 1.5:
pip install -q --upgrade paddlepaddle==1.5
- 使用
fluid.dygraph.guard(place=None)
上下文:
import paddle.fluid as fluid
with fluid.dygraph.guard():
# write your executable dygraph code here
现在您就可以在fluid.dygraph.guard()
上下文环境中使用DyGraph的模式运行网络了,DyGraph将改变以往PaddlePaddle的执行方式: 现在他们将会立即执行,并且将计算结果返回给Python。
Dygraph将非常适合和Numpy一起使用,使用fluid.dygraph.to_variable(x)
将会将ndarray转换为fluid.Variable
,而使用fluid.Variable.numpy()
将可以把任意时刻获取到的计算结果转换为Numpyndarray
:
x = np.ones([2, 2], np.float32)
with fluid.dygraph.guard():
inputs = []
for _ in range(10):
inputs.append(fluid.dygraph.to_variable(x))
ret = fluid.layers.sums(inputs)
print(ret.numpy())
[[10. 10.]
[10. 10.]]
Process finished with exit code 0
这里创建了一系列
ndarray
的输入,执行了一个sum
操作之后,我们可以直接将运行的结果打印出来
然后通过调用reduce_sum
后使用Variable.backward()
方法执行反向,使用Variable.gradient()
方法即可获得反向网络执行完成后的梯度值的ndarray
形式:
loss = fluid.layers.reduce_sum(ret)
loss.backward()
print(loss.gradient())
得到输出 :
[1.]
Process finished with exit code 0
基于DyGraph构建网络
编写一段用于DyGraph执行的Object-Oriented-Designed, PaddlePaddle模型代码主要由以下三个部分组成: 请注意,如果您设计的这一层结构是包含参数的,则必须要使用继承自
fluid.dygraph.Layer
的Object-Oriented-Designed的类来描述该层的行为。- 建立一个可以在DyGraph模式中执行的,Object-Oriented的网络,需要继承自
fluid.dygraph.Layer
,其中需要调用基类的init
方法,并且实现带有参数namescope
(用来标识本层的名字)的_init
构造函数,在构造函数中,我们通常会执行一些例如参数初始化,子网络初始化的操作,执行这些操作时不依赖于输入的动态信息:
- 建立一个可以在DyGraph模式中执行的,Object-Oriented的网络,需要继承自
class MyLayer(fluid.dygraph.Layer):
def __init__(self, name_scope):
super(MyLayer, self).__init__(name_scope)
- 实现一个
forward(self, *inputs)
的执行函数,该函数将负责执行实际运行时网络的执行逻辑, 该函数将会在每一轮训练/预测中被调用,这里我们将执行一个简单的relu
->elementwise add
->reduce sum
:
def forward(self, inputs):
x = fluid.layers.relu(inputs)
self._x_for_debug = x
x = fluid.layers.elementwise_mul(x, x)
x = fluid.layers.reduce_sum(x)
return [x]
在
fluid.dygraph.guard()
中执行:- 使用Numpy构建输入:
np_inp = np.array([1.0, 2.0, -1.0], dtype=np.float32)
- 转换输入的
ndarray
为Variable
, 并执行前向网络获取返回值: 使用fluid.dygraph.to_variable(np_inp)
转换Numpy输入为DyGraph接收的输入,然后使用my_layer(var_inp)[0]
调用callable object并且获取了x
作为返回值,利用x.numpy()
方法直接获取了执行得到的x
的ndarray
返回值。
with fluid.dygraph.guard():
var_inp = fluid.dygraph.to_variable(np_inp)
my_layer = MyLayer("my_layer")
x = my_layer(var_inp)[0]
dy_out = x.numpy()
- 计算梯度:自动微分对于实现机器学习算法(例如用于训练神经网络的反向传播)来说很有用, 使用
x.backward()
方法可以从某个fluid.Varaible
开始执行反向网络,同时利用my_layer._x_for_debug.gradient()
获取了网络中x
梯度的ndarray
返回值:
x.backward()
dy_grad = my_layer._x_for_debug.gradient()
完整代码如下:
import paddle.fluid as fluid
import numpy as np
class MyLayer(fluid.dygraph.Layer):
def __init__(self, name_scope):
super(MyLayer, self).__init__(name_scope)
def forward(self, inputs):
x = fluid.layers.relu(inputs)
self._x_for_debug = x
x = fluid.layers.elementwise_mul(x, x)
x = fluid.layers.reduce_sum(x)
return [x]
if __name__ == '__main__':
np_inp = np.array([1.0, 2.0, -1.0], dtype=np.float32)
with fluid.dygraph.guard():
var_inp = fluid.dygraph.to_variable(np_inp)
my_layer = MyLayer("my_layer")
x = my_layer(var_inp)[0]
dy_out = x.numpy()
x.backward()
dy_grad = my_layer._x_for_debug.gradient()
my_layer.clear_gradients() # 将参数梯度清零以保证下一轮训练的正确性
使用DyGraph训练模型
接下来我们将以“手写数字识别”这个最基础的模型为例,展示如何利用DyGraph模式搭建并训练一个模型:
有关手写数字识别的相关理论知识请参考PaddleBook中的内容,我们在这里默认您已经了解了该模型所需的深度学习理论知识。
- 准备数据,我们使用
paddle.dataset.mnist
作为训练所需要的数据集:
train_reader = paddle.batch(
paddle.dataset.mnist.train(), batch_size=BATCH_SIZE, drop_last=True)
- 构建网络,虽然您可以根据之前的介绍自己定义所有的网络结构,但是您也可以直接使用
fluid.dygraph.Layer
当中我们为您定制好的一些基础网络结构,这里我们利用fluid.dygraph.Conv2D
以及fluid.dygraph.Pool2d
构建了基础的SimpleImgConvPool
:
class SimpleImgConvPool(fluid.dygraph.Layer):
def __init__(self,
name_scope,
num_filters,
filter_size,
pool_size,
pool_stride,
pool_padding=0,
pool_type='max',
global_pooling=False,
conv_stride=1,
conv_padding=0,
conv_dilation=1,
conv_groups=1,
act=None,
use_cudnn=False,
param_attr=None,
bias_attr=None):
super(SimpleImgConvPool, self).__init__(name_scope)
self._conv2d = fluid.dygraph.Conv2D(
self.full_name(),
num_filters=num_filters,
filter_size=filter_size,
stride=conv_stride,
padding=conv_padding,
dilation=conv_dilation,
groups=conv_groups,
param_attr=None,
bias_attr=None,
act=act,
use_cudnn=use_cudnn)
self._pool2d = fluid.dygraph.Pool2D(
self.full_name(),
pool_size=pool_size,
pool_type=pool_type,
pool_stride=pool_stride,
pool_padding=pool_padding,
global_pooling=global_pooling,
use_cudnn=use_cudnn)
def forward(self, inputs):
x = self._conv2d(inputs)
x = self._pool2d(x)
return x
注意: 构建网络时子网络的定义和使用请在
init
中进行, 而子网络的执行则在forward
函数中进行
- 利用已经构建好的
SimpleImgConvPool
组成最终的MNIST
网络:
class MNIST(fluid.dygraph.Layer):
def __init__(self, name_scope):
super(MNIST, self).__init__(name_scope)
self._simple_img_conv_pool_1 = SimpleImgConvPool(
self.full_name(), 20, 5, 2, 2, act="relu")
self._simple_img_conv_pool_2 = SimpleImgConvPool(
self.full_name(), 50, 5, 2, 2, act="relu")
pool_2_shape = 50 * 4 * 4
SIZE = 10
scale = (2.0 / (pool_2_shape**2 * SIZE))**0.5
self._fc = fluid.dygraph.FC(self.full_name(),
10,
param_attr=fluid.param_attr.ParamAttr(
initializer=fluid.initializer.NormalInitializer(
loc=0.0, scale=scale)),
act="softmax")
def forward(self, inputs, label=None):
x = self._simple_img_conv_pool_1(inputs)
x = self._simple_img_conv_pool_2(x)
x = self._fc(x)
if label is not None:
acc = fluid.layers.accuracy(input=x, label=label)
return x, acc
else:
return x
- 在
fluid.dygraph.guard()
中定义配置好的MNIST
网络结构,此时即使没有训练也可以在fluid.dygraph.guard()
中调用模型并且检查输出:
with fluid.dygraph.guard():
mnist = MNIST("mnist")
id, data = list(enumerate(train_reader()))[0]
dy_x_data = np.array(
[x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
img = fluid.dygraph.to_variable(dy_x_data)
print("result is: {}".format(mnist(img).numpy()))
result is: [[0.10135901 0.1051138 0.1027941 ... 0.0972859 0.10221873 0.10165327]
[0.09735426 0.09970362 0.10198303 ... 0.10134517 0.10179105 0.10025002]
[0.09539858 0.10213123 0.09543551 ... 0.10613529 0.10535969 0.097991 ]
...
[0.10120598 0.0996111 0.10512722 ... 0.10067689 0.10088114 0.10071224]
[0.09889644 0.10033772 0.10151272 ... 0.10245881 0.09878646 0.101483 ]
[0.09097178 0.10078511 0.10198414 ... 0.10317434 0.10087223 0.09816764]]
Process finished with exit code 0
- 构建训练循环,在每一轮参数更新完成后我们调用
mnist.clear_gradients()
来重置梯度:
with fluid.dygraph.guard():
epoch_num = 5
BATCH_SIZE = 64
train_reader = paddle.batch(
paddle.dataset.mnist.train(), batch_size=32, drop_last=True)
mnist = MNIST("mnist")
id, data = list(enumerate(train_reader()))[0]
adam = fluid.optimizer.AdamOptimizer(learning_rate=0.001)
for epoch in range(epoch_num):
for batch_id, data in enumerate(train_reader()):
dy_x_data = np.array([x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(-1, 1)
img = fluid.dygraph.to_variable(dy_x_data)
label = fluid.dygraph.to_variable(y_data)
cost = mnist(img)
loss = fluid.layers.cross_entropy(cost, label)
avg_loss = fluid.layers.mean(loss)
if batch_id % 100 == 0 and batch_id is not 0:
print("epoch: {}, batch_id: {}, loss is: {}".format(epoch, batch_id, avg_loss.numpy()))
avg_loss.backward()
adam.minimize(avg_loss)
mnist.clear_gradients()
- 变量及优化器
模型的参数或者任何您希望检测的值可以作为变量封装在类中,然后通过对象获取并使用numpy()
方法获取其ndarray
的输出, 在训练过程中您可以使用mnist.parameters()
来获取到网络中所有的参数,也可以指定某一个Layer
的某个参数或者parameters()
来获取该层的所有参数,使用numpy()
方法随时查看参数的值
反向运行后调用之前定义的Adam
优化器对象的minimize
方法进行参数更新:
with fluid.dygraph.guard():
epoch_num = 5
BATCH_SIZE = 64
mnist = MNIST("mnist")
adam = fluid.optimizer.AdamOptimizer(learning_rate=0.001)
train_reader = paddle.batch(
paddle.dataset.mnist.train(), batch_size= BATCH_SIZE, drop_last=True)
np.set_printoptions(precision=3, suppress=True)
for epoch in range(epoch_num):
for batch_id, data in enumerate(train_reader()):
dy_x_data = np.array(
[x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(BATCH_SIZE, 1)
img = fluid.dygraph.to_variable(dy_x_data)
label = fluid.dygraph.to_variable(y_data)
label.stop_gradient = True
cost = mnist(img)
loss = fluid.layers.cross_entropy(cost, label)
avg_loss = fluid.layers.mean(loss)
dy_out = avg_loss.numpy()
avg_loss.backward()
adam.minimize(avg_loss)
mnist.clear_gradients()
dy_param_value = {}
for param in mnist.parameters():
dy_param_value[param.name] = param.numpy()
if batch_id % 20 == 0:
print("Loss at step {}: {}".format(batch_id, avg_loss.numpy()))
print("Final loss: {}".format(avg_loss.numpy()))
print("_simple_img_conv_pool_1_conv2d W's mean is: {}".format(mnist._simple_img_conv_pool_1._conv2d._filter_param.numpy().mean()))
print("_simple_img_conv_pool_1_conv2d Bias's mean is: {}".format(mnist._simple_img_conv_pool_1._conv2d._bias_param.numpy().mean()))
Loss at step 0: [2.302]
Loss at step 20: [1.616]
Loss at step 40: [1.244]
Loss at step 60: [1.142]
Loss at step 80: [0.911]
Loss at step 100: [0.824]
Loss at step 120: [0.774]
Loss at step 140: [0.626]
Loss at step 160: [0.609]
Loss at step 180: [0.627]
Loss at step 200: [0.466]
Loss at step 220: [0.499]
Loss at step 240: [0.614]
Loss at step 260: [0.585]
Loss at step 280: [0.503]
Loss at step 300: [0.423]
Loss at step 320: [0.509]
Loss at step 340: [0.348]
Loss at step 360: [0.452]
Loss at step 380: [0.397]
Loss at step 400: [0.54]
Loss at step 420: [0.341]
Loss at step 440: [0.337]
Loss at step 460: [0.155]
Final loss: [0.164]
_simple_img_conv_pool_1_conv2d W's mean is: 0.00606656912714
_simple_img_conv_pool_1_conv2d Bias's mean is: -3.4576318285e-05
- 性能
在使用fluid.dygraph.guard()
时可以通过传入fluid.CUDAPlace(0)
或者fluid.CPUPlace()
来选择执行DyGraph的设备,通常如果不做任何处理将会自动适配您的设备。
模型参数的保存
在模型训练中可以使用fluid.dygraph.save_persistables(your_model_object.state_dict(), "save_dir", optimizers=None)
来保存your_model_object
中所有的模型参数, 以及使用learning rate decay
的优化器。也可以自定义需要保存的“参数名” - “参数对象”的Python Dictionary传入。
同样可以使用models,optimizers = fluid.dygraph.load_persistables("save_dir")
获取保存的模型参数和优化器。
再使用your_modle_object.load_dict(models)
接口来恢复保存的模型参数从而达到继续训练的目的。
以及使用your_optimizer_object.load(optimizers)
接口来恢复保存的优化器中的learning rate decay
值
下面的代码展示了如何在“手写数字识别”任务中保存参数并且读取已经保存的参数来继续训练。
with fluid.dygraph.guard():
epoch_num = 5
BATCH_SIZE = 64
mnist = MNIST("mnist")
adam = fluid.optimizer.Adam(learning_rate=0.001)
train_reader = paddle.batch(
paddle.dataset.mnist.train(), batch_size= BATCH_SIZE, drop_last=True)
np.set_printoptions(precision=3, suppress=True)
dy_param_init_value={}
for epoch in range(epoch_num):
for batch_id, data in enumerate(train_reader()):
dy_x_data = np.array(
[x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(BATCH_SIZE, 1)
img = fluid.dygraph.to_variable(dy_x_data)
label = fluid.dygraph.to_variable(y_data)
label.stop_gradient = True
cost = mnist(img)
loss = fluid.layers.cross_entropy(cost, label)
avg_loss = fluid.layers.mean(loss)
dy_out = avg_loss.numpy()
avg_loss.backward()
adam.minimize(avg_loss)
if batch_id == 20:
fluid.dygraph.save_persistables(mnist.state_dict(), "save_dir", adam)
mnist.clear_gradients()
if batch_id == 20:
for param in mnist.parameters():
dy_param_init_value[param.name] = param.numpy()
model, _ = fluid.dygraph.load_persistables("save_dir")
mnist.load_dict(model)
break
if epoch == 0:
break
restore = mnist.parameters()
# check save and load
success = True
for value in restore:
if (not np.array_equal(value.numpy(), dy_param_init_value[value.name])) or (not np.isfinite(value.numpy().all())) or (np.isnan(value.numpy().any())):
success = False
print("model save and load success? {}".format(success))
模型评估
当我们需要在DyGraph模式下利用搭建的模型进行预测任务,可以使用YourModel.eval()
接口,在之前的手写数字识别模型中我们使用mnist.eval()
来启动预测模式(我们默认在fluid.dygraph.guard()
上下文中是训练模式),在预测的模式下,DyGraph将只会执行前向的预测网络,而不会进行自动求导并执行反向网络:
下面的代码展示了如何使用DyGraph模式训练一个用于执行“手写数字识别”任务的模型并保存,并且利用已经保存好的模型进行预测。
我们在fluid.dygraph.guard()
上下文中进行了模型的保存和训练,值得注意的是,当我们需要在训练的过程中进行预测时需要使用YourModel.eval()
切换到预测模式,并且在预测完成后使用YourModel.train()
切换回训练模式继续训练。
我们在inference_mnist
中启用另一个fluid.dygraph.guard()
,并在其上下文中load
之前保存的checkpoint
进行预测,同样的在执行预测前需要使用YourModel.eval()
来切换到预测模式。
def test_mnist(reader, model, batch_size):
acc_set = []
avg_loss_set = []
for batch_id, data in enumerate(reader()):
dy_x_data = np.array([x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(batch_size, 1)
img = fluid.dygraph.to_variable(dy_x_data)
label = fluid.dygraph.to_variable(y_data)
label.stop_gradient = True
prediction, acc = model(img, label)
loss = fluid.layers.cross_entropy(input=prediction, label=label)
avg_loss = fluid.layers.mean(loss)
acc_set.append(float(acc.numpy()))
avg_loss_set.append(float(avg_loss.numpy()))
# get test acc and loss
acc_val_mean = np.array(acc_set).mean()
avg_loss_val_mean = np.array(avg_loss_set).mean()
return avg_loss_val_mean, acc_val_mean
def inference_mnist():
with fluid.dygraph.guard():
mnist_infer = MNIST("mnist")
# load checkpoint
model_dict, _ = fluid.dygraph.load_persistables("save_dir")
mnist_infer.load_dict(model_dict)
print("checkpoint loaded")
# start evaluate mode
mnist_infer.eval()
def load_image(file):
im = Image.open(file).convert('L')
im = im.resize((28, 28), Image.ANTIALIAS)
im = np.array(im).reshape(1, 1, 28, 28).astype(np.float32)
im = im / 255.0 * 2.0 - 1.0
return im
cur_dir = os.path.dirname(os.path.realpath(__file__))
tensor_img = load_image(cur_dir + '/image/2.png')
results = mnist_infer(fluid.dygraph.to_variable(tensor_img))
lab = np.argsort(results.numpy())
print("Inference result of image/infer_3.png is: %d" % lab[0][-1])
with fluid.dygraph.guard():
epoch_num = 1
BATCH_SIZE = 64
mnist = MNIST("mnist")
adam = fluid.optimizer.AdamOptimizer(learning_rate=0.001)
test_reader = paddle.batch(
paddle.dataset.mnist.test(), batch_size=BATCH_SIZE, drop_last=True)
train_reader = paddle.batch(
paddle.dataset.mnist.train(),
batch_size=BATCH_SIZE,
drop_last=True)
for epoch in range(epoch_num):
for batch_id, data in enumerate(train_reader()):
dy_x_data = np.array([x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape(-1, 1)
img = fluid.dygraph.to_variable(dy_x_data)
label = fluid.dygraph.to_variable(y_data)
label.stop_gradient = True
cost, acc = mnist(img, label)
loss = fluid.layers.cross_entropy(cost, label)
avg_loss = fluid.layers.mean(loss)
avg_loss.backward()
adam.minimize(avg_loss)
# save checkpoint
mnist.clear_gradients()
if batch_id % 100 == 0:
print("Loss at epoch {} step {}: {:}".format(
epoch, batch_id, avg_loss.numpy()))
mnist.eval()
test_cost, test_acc = test_mnist(test_reader, mnist, BATCH_SIZE)
mnist.train()
print("Loss at epoch {} , Test avg_loss is: {}, acc is: {}".format(
epoch, test_cost, test_acc))
fluid.dygraph.save_persistables(mnist.state_dict(), "save_dir")
print("checkpoint saved")
inference_mnist()
Loss at epoch 0 step 0: [2.2991252]
Loss at epoch 0 step 100: [0.15491392]
Loss at epoch 0 step 200: [0.13315125]
Loss at epoch 0 step 300: [0.10253005]
Loss at epoch 0 step 400: [0.04266362]
Loss at epoch 0 step 500: [0.08894891]
Loss at epoch 0 step 600: [0.08999012]
Loss at epoch 0 step 700: [0.12975612]
Loss at epoch 0 step 800: [0.15257305]
Loss at epoch 0 step 900: [0.07429226]
Loss at epoch 0 , Test avg_loss is: 0.05995981965082674, acc is: 0.9794671474358975
checkpoint saved
No optimizer loaded. If you didn't save optimizer, please ignore this. The program can still work with new optimizer.
checkpoint loaded
Inference result of image/infer_3.png is: 3
编写兼容的模型
以上一步中手写数字识别的例子为例,动态图的模型代码可以直接用于静态图中作为模型代码,执行时,直接使用PaddlePaddle静态图执行方式即可,这里以静态图中的executor
为例, 模型代码可以直接使用之前的模型代码,执行时使用Executor
执行即可
epoch_num = 1
BATCH_SIZE = 64
exe = fluid.Executor(fluid.CPUPlace())
mnist = MNIST("mnist")
sgd = fluid.optimizer.SGDOptimizer(learning_rate=1e-3)
train_reader = paddle.batch(
paddle.dataset.mnist.train(), batch_size=BATCH_SIZE, drop_last=True)
img = fluid.layers.data(
name='pixel', shape=[1, 28, 28], dtype='float32')
label = fluid.layers.data(name='label', shape=[1], dtype='int64')
cost = mnist(img)
loss = fluid.layers.cross_entropy(cost, label)
avg_loss = fluid.layers.mean(loss)
sgd.minimize(avg_loss)
out = exe.run(fluid.default_startup_program())
for epoch in range(epoch_num):
for batch_id, data in enumerate(train_reader()):
static_x_data = np.array(
[x[0].reshape(1, 28, 28)
for x in data]).astype('float32')
y_data = np.array(
[x[1] for x in data]).astype('int64').reshape([BATCH_SIZE, 1])
fetch_list = [avg_loss.name]
out = exe.run(
fluid.default_main_program(),
feed={"pixel": static_x_data,
"label": y_data},
fetch_list=fetch_list)
static_out = out[0]
if batch_id % 100 == 0 and batch_id is not 0:
print("epoch: {}, batch_id: {}, loss: {}".format(epoch, batch_id, static_out))