{ "cells": [ { "cell_type": "markdown", "id": "69a92ef2", "metadata": {}, "source": [ "[![下载Notebook](https://mindspore-website.obs.cn-north-4.myhuaweicloud.com/website-images/master/resource/_static/logo_notebook.svg)](https://mindspore-website.obs.cn-north-4.myhuaweicloud.com/notebook/master/tutorials/zh_cn/beginner/mindspore_accelerate_with_static_graph.ipynb) [![下载样例代码](https://mindspore-website.obs.cn-north-4.myhuaweicloud.com/website-images/master/resource/_static/logo_download_code.svg)](https://mindspore-website.obs.cn-north-4.myhuaweicloud.com/notebook/master/tutorials/zh_cn/beginner/mindspore_accelerate_with_static_graph.py) [![查看源文件](https://mindspore-website.obs.cn-north-4.myhuaweicloud.com/website-images/master/resource/_static/logo_source.svg)](https://gitee.com/mindspore/docs/blob/master/tutorials/source_zh_cn/beginner/accelerate_with_static_graph.ipynb)\n", "\n", "[基本介绍](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/introduction.html) || [快速入门](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/quick_start.html) || [张量 Tensor](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/tensor.html) || [数据集 Dataset](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/dataset.html) || [数据变换 Transforms](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/transforms.html) || [网络构建](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/model.html) || [函数式自动微分](https://gitee.com/mindspore/docs/blob/master/tutorials/source_zh_cn/beginner/autograd.ipynb) || [模型训练](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/train.html) || [保存与加载](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/save_load.html) || **使用静态图加速**\n", "\n", "# 使用静态图加速\n", "\n", "## 背景介绍\n", "\n", "AI编译框架分为两种运行模式,分别是动态图模式以及静态图模式。MindSpore默认情况下是以动态图模式运行,但也支持手工切换为静态图模式。两种运行模式的详细介绍如下:\n", "\n", "### 动态图模式\n", "\n", "动态图的特点是计算图的构建和计算同时发生(Define by run),其符合Python的解释执行方式,在计算图中定义一个Tensor时,其值就已经被计算且确定,因此在调试模型时较为方便,能够实时得到中间结果的值,但由于所有节点都需要被保存,导致难以对整个计算图进行优化。\n", "\n", "在MindSpore中,动态图模式又被称为PyNative模式。由于动态图的解释执行特性,在脚本开发和网络流程调试过程中,推荐使用动态图模式进行调试。\n", "如需要手动控制框架采用PyNative模式,可以通过以下代码进行网络构建:" ] }, { "cell_type": "code", "execution_count": 1, "id": "6dc8d4c5", "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " ...\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]\n", " [-0.00134926 -0.13563682 -0.02863023 -0.05452826 0.03290743 -0.12423715\n", " -0.0582641 -0.10854103 -0.08558805 0.06099342]]\n" ] } ], "source": [ "import numpy as np\n", "import mindspore as ms\n", "from mindspore import nn, Tensor\n", "ms.set_context(mode=ms.PYNATIVE_MODE) # 使用set_context进行动态图模式的配置\n", "\n", "class Network(nn.Cell):\n", " def __init__(self):\n", " super().__init__()\n", " self.flatten = nn.Flatten()\n", " self.dense_relu_sequential = nn.SequentialCell(\n", " nn.Dense(28*28, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 10)\n", " )\n", "\n", " def construct(self, x):\n", " x = self.flatten(x)\n", " logits = self.dense_relu_sequential(x)\n", " return logits\n", "\n", "model = Network()\n", "input = Tensor(np.ones([64, 1, 28, 28]).astype(np.float32))\n", "output = model(input)\n", "print(output)" ] }, { "cell_type": "markdown", "id": "6a9a195c", "metadata": {}, "source": [ "### 静态图模式\n", "\n", "相较于动态图而言,静态图的特点是将计算图的构建和实际计算分开(Define and run)。有关静态图模式的运行原理,可以参考[静态图语法支持](https://www.mindspore.cn/docs/zh-CN/master/note/static_graph_syntax_support.html#概述)。\n", "\n", "在MindSpore中,静态图模式又被称为Graph模式,在Graph模式下,基于图优化、计算图整图下沉等技术,编译器可以针对图进行全局的优化,获得较好的性能,因此比较适合网络固定且需要高性能的场景。\n", "\n", "如需要手动控制框架采用静态图模式,可以通过以下代码进行网络构建:" ] }, { "cell_type": "code", "execution_count": 2, "id": "2476e059", "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " ...\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]\n", " [ 0.05363735 0.05117104 -0.03343301 0.06347139 0.07546629 0.03263091\n", " 0.02790363 0.06269836 0.01838502 0.04387159]]\n" ] } ], "source": [ "import numpy as np\n", "import mindspore as ms\n", "from mindspore import nn, Tensor\n", "ms.set_context(mode=ms.GRAPH_MODE) # 使用set_context进行运行静态图模式的配置\n", "\n", "class Network(nn.Cell):\n", " def __init__(self):\n", " super().__init__()\n", " self.flatten = nn.Flatten()\n", " self.dense_relu_sequential = nn.SequentialCell(\n", " nn.Dense(28*28, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 10)\n", " )\n", "\n", " def construct(self, x):\n", " x = self.flatten(x)\n", " logits = self.dense_relu_sequential(x)\n", " return logits\n", "\n", "model = Network()\n", "input = Tensor(np.ones([64, 1, 28, 28]).astype(np.float32))\n", "output = model(input)\n", "print(output)" ] }, { "cell_type": "markdown", "id": "89825897", "metadata": {}, "source": [ "## 静态图模式的使用场景\n", "\n", "MindSpore编译器重点面向Tensor数据的计算以及其微分处理。因此使用MindSpore API以及基于Tensor对象的操作更适合使用静态图编译优化。其他操作虽然可以部分入图编译,但实际优化作用有限。另外,静态图模式先编译后执行的模式导致其存在编译耗时。因此,如果函数无需反复执行,那么使用静态图加速也可能没有价值。\n", "\n", "有关使用静态图来进行网络编译的示例,请参考[网络构建](https://www.mindspore.cn/tutorials/zh-CN/master/beginner/model.html)。\n", "\n", "## 静态图模式开启方式\n", "\n", "通常情况下,由于动态图的灵活性,我们会选择使用PyNative模式来进行自由的神经网络构建,以实现模型的创新和优化。但是当需要进行性能加速时,我们需要对神经网络部分或整体进行加速。MindSpore提供了两种切换为图模式的方式,分别是基于装饰器的开启方式以及基于全局context的开启方式。\n", "\n", "### 基于装饰器的开启方式\n", "\n", "MindSpore提供了jit装饰器,可以通过修饰Python函数或者Python类的成员函数使其被编译成计算图,通过图优化等技术提高运行速度。此时我们可以简单的对想要进行性能优化的模块进行图编译加速,而模型其他部分,仍旧使用解释执行方式,不丢失动态图的灵活性。无论全局context是设置成静态图模式还是动态图模式,被jit修饰的部分始终会以静态图模式进行运行。\n", "\n", "在需要对Tensor的某些运算进行编译加速时,可以在其定义的函数上使用jit修饰器,在调用该函数时,该模块自动被编译为静态图。需要注意的是,jit装饰器只能用来修饰函数,无法对类进行修饰。jit的使用示例如下:" ] }, { "cell_type": "code", "execution_count": 3, "id": "d97a2f69", "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " ...\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]\n", " [-0.12126954 0.06986676 -0.2230821 -0.07087803 -0.01003947 0.01063392\n", " 0.10143848 -0.0200909 -0.09724037 0.0114444 ]]\n" ] } ], "source": [ "import numpy as np\n", "import mindspore as ms\n", "from mindspore import nn, Tensor\n", "\n", "class Network(nn.Cell):\n", " def __init__(self):\n", " super().__init__()\n", " self.flatten = nn.Flatten()\n", " self.dense_relu_sequential = nn.SequentialCell(\n", " nn.Dense(28*28, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 10)\n", " )\n", "\n", " def construct(self, x):\n", " x = self.flatten(x)\n", " logits = self.dense_relu_sequential(x)\n", " return logits\n", "\n", "input = Tensor(np.ones([64, 1, 28, 28]).astype(np.float32))\n", "\n", "@ms.jit # 使用ms.jit装饰器,使被装饰的函数以静态图模式运行\n", "def run(x):\n", " model = Network()\n", " return model(x)\n", "\n", "output = run(input)\n", "print(output)" ] }, { "cell_type": "markdown", "id": "0c5adf4d", "metadata": {}, "source": [ "除使用修饰器外,也可使用函数变换方式调用jit方法,示例如下:" ] }, { "cell_type": "code", "execution_count": 4, "id": "7337a0bb", "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " ...\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]\n", " [ 0.11027216 -0.09628229 0.0457969 0.05396656 -0.06958974 0.0428197\n", " -0.1572069 -0.14151613 -0.04531277 0.07521383]]\n" ] } ], "source": [ "import numpy as np\n", "import mindspore as ms\n", "from mindspore import nn, Tensor\n", "\n", "class Network(nn.Cell):\n", " def __init__(self):\n", " super().__init__()\n", " self.flatten = nn.Flatten()\n", " self.dense_relu_sequential = nn.SequentialCell(\n", " nn.Dense(28*28, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 10)\n", " )\n", "\n", " def construct(self, x):\n", " x = self.flatten(x)\n", " logits = self.dense_relu_sequential(x)\n", " return logits\n", "\n", "input = Tensor(np.ones([64, 1, 28, 28]).astype(np.float32))\n", "\n", "def run(x):\n", " model = Network()\n", " return model(x)\n", "\n", "run_with_jit = ms.jit(run) # 通过调用jit将函数转换为以静态图方式执行\n", "output = run(input)\n", "print(output)" ] }, { "cell_type": "markdown", "id": "df543f53", "metadata": {}, "source": [ "当我们需要对神经网络的某部分进行加速时,可以直接在construct方法上使用jit修饰器,在调用实例化对象时,该模块自动被编译为静态图。示例如下:" ] }, { "cell_type": "code", "execution_count": 5, "id": "e51b32f5", "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " ...\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]\n", " [ 0.10522258 0.06597593 -0.09440921 -0.04883489 0.07194916 0.1343117\n", " -0.06813788 0.01986085 0.0216996 -0.05345828]]\n" ] } ], "source": [ "import numpy as np\n", "import mindspore as ms\n", "from mindspore import nn, Tensor\n", "\n", "class Network(nn.Cell):\n", " def __init__(self):\n", " super().__init__()\n", " self.flatten = nn.Flatten()\n", " self.dense_relu_sequential = nn.SequentialCell(\n", " nn.Dense(28*28, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 10)\n", " )\n", "\n", " @ms.jit # 使用ms.jit装饰器,使被装饰的函数以静态图模式运行\n", " def construct(self, x):\n", " x = self.flatten(x)\n", " logits = self.dense_relu_sequential(x)\n", " return logits\n", "\n", "input = Tensor(np.ones([64, 1, 28, 28]).astype(np.float32))\n", "model = Network()\n", "output = model(input)\n", "print(output)" ] }, { "cell_type": "markdown", "id": "d8aef1df", "metadata": {}, "source": [ "### 基于context的开启方式\n", "\n", "context模式是一种全局的设置模式。代码示例如下:" ] }, { "cell_type": "code", "execution_count": 6, "id": "bb1d7b61", "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " ...\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]\n", " [ 0.08501796 -0.04404321 -0.05165704 0.00357929 0.00051521 0.00946456\n", " 0.02748473 -0.19415936 -0.00278988 0.04024826]]\n" ] } ], "source": [ "import numpy as np\n", "import mindspore as ms\n", "from mindspore import nn, Tensor\n", "ms.set_context(mode=ms.GRAPH_MODE) # 使用set_context进行运行静态图模式的配置\n", "\n", "class Network(nn.Cell):\n", " def __init__(self):\n", " super().__init__()\n", " self.flatten = nn.Flatten()\n", " self.dense_relu_sequential = nn.SequentialCell(\n", " nn.Dense(28*28, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 512),\n", " nn.ReLU(),\n", " nn.Dense(512, 10)\n", " )\n", "\n", " def construct(self, x):\n", " x = self.flatten(x)\n", " logits = self.dense_relu_sequential(x)\n", " return logits\n", "\n", "model = Network()\n", "input = Tensor(np.ones([64, 1, 28, 28]).astype(np.float32))\n", "output = model(input)\n", "print(output)" ] }, { "cell_type": "markdown", "id": "b863f0f7", "metadata": {}, "source": [ "## 静态图的语法约束\n", "\n", "在Graph模式下,Python代码并不是由Python解释器去执行,而是将代码编译成静态计算图,然后执行静态计算图。因此,编译器无法支持全量的Python语法。MindSpore的静态图编译器维护了Python常用语法子集,以支持神经网络的构建及训练。详情可参考[静态图语法支持](https://www.mindspore.cn/docs/zh-CN/master/note/static_graph_syntax_support.html)。\n", "\n", "## JitConfig配置选项\n", "\n", "在图模式下,可以通过使用[JitConfig](https://www.mindspore.cn/docs/zh-CN/master/api_python/mindspore/mindspore.JitConfig.html#mindspore.JitConfig)配置选项来一定程度的自定义编译流程,目前JitConfig支持的配置参数如下:\n", "\n", "- jit_level: 用于控制优化等级。\n", "- exec_mode: 用于控制模型执行方式。\n", "- jit_syntax_level: 设置静态图语法支持级别,详细介绍请见[静态图语法支持](https://www.mindspore.cn/docs/zh-CN/master/note/static_graph_syntax_support.html#概述)。\n", "\n", "## 静态图高级编程技巧\n", "\n", "使用静态图高级编程技巧可以有效地提高编译效率以及执行效率,并可以使程序运行的更加稳定。详情可参考[静态图高级编程技巧](https://www.mindspore.cn/tutorials/zh-CN/master/advanced/static_graph_expert_programming.html)。" ] } ], "metadata": { "kernelspec": { "display_name": "MindSpore", "language": "python", "name": "mindspore" }, "language_info": { "codemirror_mode": { "name": "ipython", "version": 3 }, "file_extension": ".py", "mimetype": "text/x-python", "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", "version": "3.7.10" } }, "nbformat": 4, "nbformat_minor": 5 }