# MindSpore Lite 端侧目标检测demo( )
本示例程序演示了如何在端侧利用MindSpore Lite C++ API( ) , ,
## 运行依赖
- Android Studio >= 3.2 (推荐4.0以上版本)
## 构建与运行
1. 在Android Studio中加载本示例源码。
启动Android Studio后, ,
> Android SDK Tools为默认安装项,
>
> 使用过程中若出现问题,
2. 连接Android设备,
通过USB连接Android手机。待成功识别到设备后,
> 编译过程中Android Studio会自动下载MindSpore Lite、模型文件等相关依赖项,
>
> Android Studio连接设备调试操作,
>
> 手机需开启“USB调试模式”,
3. 在Android设备上, ,
如下图所示,识别出的概率最高的物体是植物。
4. Demo部署问题解决方案。
4.1 NDK、CMake、JDK等工具问题:
如果Android Studio内安装的工具出现无法识别等问题, ,
- NDK >= 21.3 [NDK ](https://developer.android.google.cn/ndk/downloads?hl=zh-cn )
- CMake >= 3.10.2 [CMake ](https://cmake.org/download )
- Android SDK >= 26 [SDK ](https://developer.microsoft.com/zh-cn/windows/downloads/windows-10-sdk/ )
- JDK >= 1.8 [JDK ](https://www.oracle.com/cn/java/technologies/javase/javase-jdk8-downloads.html )
4.2 NDK版本不匹配问题:
打开`Android SDK`,点击`Show Package Details`,
4.3 Android Studio版本问题:
在`工具栏-help-Checkout for Updates`中更新Android Studio版本。
4.4 Gradle下依赖项安装过慢问题:
如图所示, 打开Demo根目录下`build.gradle`文件,加入华为镜像源地址:`maven {url 'https://developer.huawei.com/repo/'}`, , ,
## 示例程序详细说明
本端侧目标检测Android示例程序分为JAVA层和JNI层, , , ( ) ;
> 此处详细说明示例程序的JNI层实现, ,
### 示例程序结构
```text
app
|
├── libs # 存放demo jni层编译出的库文件
│ └── arm64-v8a
│ │── libmlkit-label-MS.so #
|
├── src/main
│ ├── assets # 资源文件
| | └── ssd.ms # 存放模型文件
│ |
│ ├── cpp # 模型加载和预测主要逻辑封装类
| | ├── mindspore-lite-x.x.x-mindata-arm64-cpu # minspore源码编译出的调用包,包含demo jni层依赖的库文件及相关的头文件
| | | └── ...
│ | |
| | ├── MindSporeNetnative.cpp # MindSpore调用相关的JNI方法
│ ├── java # java层应用代码
│ │ └── com.huawei.himindsporedemo
│ │ ├── help # 图像处理及MindSpore JNI调用相关实现
│ │ │ └── ...
│ │ └── obejctdetect # 开启摄像头及绘制相关实现
│ │ └── ...
│ │
│ ├── res # 存放Android相关的资源文件
│ └── AndroidManifest.xml # Android配置文件
│
├── CMakeList.txt # cmake编译入口文件
│
├── build.gradle # 其他Android配置文件
├── download.gradle # APP构建时由gradle自动从HuaWei Server下载依赖的库文件及模型文件
└── ...
```
### 配置MindSpore Lite依赖项
Android JNI层调用MindSpore C++ API时,
> version: ,
>
> device: ( ) ( )
>
> os:
本示例中,
> 若自动下载失败,请手动下载相关库文件,解压并放在对应位置:
mindspore-lite-1.0.1-runtime-arm64-cpu.tar.gz [下载链接 ](https://ms-release.obs.cn-north-4.myhuaweicloud.com/1.0.1/lite/android_aarch64/mindspore-lite-1.0.1-runtime-arm64-cpu.tar.gz )
在app的`build.gradle`文件中配置CMake编译支持,
```text
android{
defaultConfig{
externalNativeBuild{
cmake{
arguments "-DANDROID_STL=c++_shared"
}
}
ndk{
abiFilters 'arm64-v8a'
}
}
}
```
在`app/CMakeLists.txt`文件中建立`.so`库文件链接,如下所示。
```text
# Set MindSpore Lite Dependencies.
set(MINDSPORELITE_VERSION mindspore-lite-1.0.1-runtime-arm64-cpu)
include_directories(${CMAKE_SOURCE_DIR}/src/main/cpp/${MINDSPORELITE_VERSION})
add_library(mindspore-lite SHARED IMPORTED )
add_library(minddata-lite SHARED IMPORTED )
set_target_properties(mindspore-lite PROPERTIES IMPORTED_LOCATION
${CMAKE_SOURCE_DIR}/src/main/cpp/${MINDSPORELITE_VERSION}/lib/libmindspore-lite.so)
set_target_properties(minddata-lite PROPERTIES IMPORTED_LOCATION
${CMAKE_SOURCE_DIR}/src/main/cpp/${MINDSPORELITE_VERSION}/lib/libminddata-lite.so)
# Link target library.
target_link_libraries(
...
mindspore-lite
minddata-lite
...
)
```
### 下载及部署模型文件
从MindSpore Model Hub中下载模型文件, ,
> 若下载失败请手动下载模型文件,
### 编写端侧推理代码
在JNI层调用MindSpore Lite C++ API实现端测推理。
推理代码流程如下,完整代码请参见`src/cpp/MindSporeNetnative.cpp`。
1. 加载MindSpore Lite模型文件,
- 加载模型文件:创建并配置用于模型推理的上下文
```cpp
// Buffer is the model data passed in by the Java layer
jlong bufferLen = env->GetDirectBufferCapacity(buffer);
char *modelBuffer = CreateLocalModelBuffer(env, buffer);
```
- 创建会话
```cpp
void **labelEnv = new void *;
MSNetWork *labelNet = new MSNetWork;
*labelEnv = labelNet;
// Create context.
lite::Context *context = new lite::Context;
context->cpu_bind_mode_ = lite::NO_BIND;
context->device_ctx_.type = lite::DT_CPU;
context->thread_num_ = numThread; //Specify the number of threads to run inference
// Create the mindspore session.
labelNet->CreateSessionMS(modelBuffer, bufferLen, "device label", context);
delete context;
```
- 加载模型文件并构建用于推理的计算图
```cpp
void MSNetWork::CreateSessionMS(char* modelBuffer, size_t bufferLen, std::string name, mindspore::lite::Context* ctx)
{
CreateSession(modelBuffer, bufferLen, ctx);
session = mindspore::session::LiteSession::CreateSession(ctx);
auto model = mindspore::lite::Model::Import(modelBuffer, bufferLen);
int ret = session->CompileGraph(model); // Compile Graph
}
```
2. 将输入图片转换为传入MindSpore模型的Tensor格式。
将待检测图片数据转换为输入MindSpore模型的Tensor。
```cpp
// Convert the Bitmap image passed in from the JAVA layer to Mat for OpenCV processing
LiteMat lite_mat_bgr,lite_norm_mat_cut;
if (!BitmapToLiteMat(env, srcBitmap, lite_mat_bgr)){
MS_PRINT("BitmapToLiteMat error");
return NULL;
}
int srcImageWidth = lite_mat_bgr.width_;
int srcImageHeight = lite_mat_bgr.height_;
if(!PreProcessImageData(lite_mat_bgr, lite_norm_mat_cut)){
MS_PRINT("PreProcessImageData error");
return NULL;
}
ImgDims inputDims;
inputDims.channel =lite_norm_mat_cut.channel_;
inputDims.width = lite_norm_mat_cut.width_;
inputDims.height = lite_norm_mat_cut.height_;
// Get the mindsore inference environment which created in loadModel().
void **labelEnv = reinterpret_cast<void ** >(netEnv);
if (labelEnv == nullptr) {
MS_PRINT("MindSpore error, labelEnv is a nullptr.");
return NULL;
}
MSNetWork *labelNet = static_cast<MSNetWork * >(*labelEnv);
auto mSession = labelNet->session;
if (mSession == nullptr) {
MS_PRINT("MindSpore error, Session is a nullptr.");
return NULL;
}
MS_PRINT("MindSpore get session.");
auto msInputs = mSession->GetInputs();
auto inTensor = msInputs.front();
float *dataHWC = reinterpret_cast<float * >(lite_norm_mat_cut.data_ptr_);
// copy input Tensor
memcpy(inTensor->MutableData(), dataHWC,
inputDims.channel * inputDims.width * inputDims.height * sizeof(float));
delete[] (dataHWC);
```
3. 进行模型推理前, , ,
```cpp
bool PreProcessImageData(LiteMat & lite_mat_bgr,LiteMat & lite_norm_mat_cut) {
bool ret=false;
LiteMat lite_mat_resize;
ret = ResizeBilinear(lite_mat_bgr, lite_mat_resize, 300, 300);
if (!ret) {
MS_PRINT("ResizeBilinear error");
return false;
}
LiteMat lite_mat_convert_float;
ret = ConvertTo(lite_mat_resize, lite_mat_convert_float, 1.0 / 255.0);
if (!ret) {
MS_PRINT("ConvertTo error");
return false;
}
float means[3] = {0.485, 0.456, 0.406};
float vars[3] = {1.0 / 0.229, 1.0 / 0.224, 1.0 / 0.225};
SubStractMeanNormalize(lite_mat_convert_float, lite_norm_mat_cut, means, vars);
return true;
}
```
4. 对输入Tensor按照模型进行推理, ,
- 图执行,端测推理。
```cpp
// After the model and image tensor data is loaded, run inference.
auto status = mSession->RunGraph();
```
- 获取输出数据。
```cpp
auto names = mSession->GetOutputTensorNames();
typedef std::unordered_map< std::string ,
std::vector< mindspore::tensor::MSTensor * > > Msout;
std::unordered_map< std::string ,
mindspore::tensor::MSTensor *> msOutputs;
for (const auto & name : names) {
auto temp_dat =mSession->GetOutputByTensorName(name);
msOutputs.insert(std::pair< std::string , mindspore::tensor::MSTensor * > {name, temp_dat});
}
std::string retStr = ProcessRunnetResult(msOutputs, ret);
```
- 模型有2个输出, , : ; ,
```cpp
void SSDModelUtil::getDefaultBoxes() {
float fk[6] = {0.0, 0.0, 0.0, 0.0, 0.0, 0.0};
std::vector< struct WHBox > all_sizes;
struct Product mProductData[19 * 19] = {0};
for (int i = 0; i < 6 ; i + + ) {
fk[i] = config.model_input_height / config.steps[i];
}
float scale_rate =
(config.max_scale - config.min_scale) / (sizeof(config.num_default) / sizeof(int) - 1);
float scales[7] = {0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 1.0};
for (int i = 0; i < sizeof ( config . num_default ) / sizeof ( int ) ; i + + ) {
scales[i] = config.min_scale + scale_rate * i;
}
for (int idex = 0; idex < sizeof ( config . feature_size ) / sizeof ( int ) ; idex + + ) {
float sk1 = scales[idex];
float sk2 = scales[idex + 1];
float sk3 = sqrt(sk1 * sk2);
struct WHBox tempWHBox;
all_sizes.clear();
if (idex == 0) {
float w = sk1 * sqrt(2);
float h = sk1 / sqrt(2);
tempWHBox.boxw = 0.1;
tempWHBox.boxh = 0.1;
all_sizes.push_back(tempWHBox);
tempWHBox.boxw = w;
tempWHBox.boxh = h;
all_sizes.push_back(tempWHBox);
tempWHBox.boxw = h;
tempWHBox.boxh = w;
all_sizes.push_back(tempWHBox);
} else {
tempWHBox.boxw = sk1;
tempWHBox.boxh = sk1;
all_sizes.push_back(tempWHBox);
for (int j = 0; j < sizeof ( config . aspect_ratios [ idex ] ) / sizeof ( int ) ; j + + ) {
float w = sk1 * sqrt(config.aspect_ratios[idex][j]);
float h = sk1 / sqrt(config.aspect_ratios[idex][j]);
tempWHBox.boxw = w;
tempWHBox.boxh = h;
all_sizes.push_back(tempWHBox);
tempWHBox.boxw = h;
tempWHBox.boxh = w;
all_sizes.push_back(tempWHBox);
}
tempWHBox.boxw = sk3;
tempWHBox.boxh = sk3;
all_sizes.push_back(tempWHBox);
}
for (int i = 0; i < config.feature_size [ idex ] ; i + + ) {
for (int j = 0; j < config.feature_size [ idex ] ; j + + ) {
mProductData[i * config.feature_size[idex] + j].x = i;
mProductData[i * config.feature_size[idex] + j].y = j;
}
}
int productLen = config.feature_size[idex] * config.feature_size[idex];
for (int i = 0; i < productLen ; i + + ) {
for (int j = 0; j < all_sizes.size ( ) ; j + + ) {
struct NormalBox tempBox;
float cx = (mProductData[i].y + 0.5) / fk[idex];
float cy = (mProductData[i].x + 0.5) / fk[idex];
tempBox.y = cy;
tempBox.x = cx;
tempBox.h = all_sizes[j].boxh;
tempBox.w = all_sizes[j].boxw;
mDefaultBoxes.push_back(tempBox);
}
}
}
}
```
- 通过最大值抑制将目标类型置信度较高的输出筛选出来。
```cpp
void SSDModelUtil::nonMaximumSuppression(const YXBoxes *const decoded_boxes,
const float *const scores,
const std::vector< int > & in_indexes,
std::vector< int > & out_indexes, const float nmsThreshold,
const int count, const int max_results) {
int nR = 0; //number of results
std::vector< bool > del(count, false);
for (size_t i = 0; i < in_indexes.size ( ) ; i + + ) {
if (!del[in_indexes[i]]) {
out_indexes.push_back(in_indexes[i]);
if (++nR == max_results) {
break;
}
for (size_t j = i + 1; j < in_indexes.size ( ) ; j + + ) {
const auto boxi = decoded_boxes[in_indexes[i]], boxj = decoded_boxes[in_indexes[j]];
float a[4] = {boxi.xmin, boxi.ymin, boxi.xmax, boxi.ymax};
float b[4] = {boxj.xmin, boxj.ymin, boxj.xmax, boxj.ymax};
if (IOU(a, b) > nmsThreshold) {
del[in_indexes[j]] = true;
}
}
}
}
}
```
- 对每类的概率大于阈值, ,
```cpp
std::string SSDModelUtil::getDecodeResult(float *branchScores, float *branchBoxData) {
std::string result = "";
NormalBox tmpBox[1917] = {0};
float mScores[1917][81] = {0};
float outBuff[1917][7] = {0};
float scoreWithOneClass[1917] = {0};
int outBoxNum = 0;
YXBoxes decodedBoxes[1917] = {0};
// Copy branch outputs box data to tmpBox.
for (int i = 0; i < 1917 ; + + i ) {
tmpBox[i].y = branchBoxData[i * 4 + 0];
tmpBox[i].x = branchBoxData[i * 4 + 1];
tmpBox[i].h = branchBoxData[i * 4 + 2];
tmpBox[i].w = branchBoxData[i * 4 + 3];
}
// Copy branch outputs score to mScores.
for (int i = 0; i < 1917 ; + + i ) {
for (int j = 0; j < 81 ; + + j ) {
mScores[i][j] = branchScores[i * 81 + j];
}
}
ssd_boxes_decode(tmpBox, decodedBoxes);
const float nms_threshold = 0.3;
for (int i = 1; i < 81 ; i + + ) {
std::vector< int > in_indexes;
for (int j = 0; j < 1917 ; j + + ) {
scoreWithOneClass[j] = mScores[j][i];
// if (mScores[j][i] > 0.1) {
if (mScores[j][i] > g_thres_map[i]) {
in_indexes.push_back(j);
}
}
if (in_indexes.size() == 0) {
continue;
}
sort(in_indexes.begin(), in_indexes.end(),
[& ](int a, int b ) { return scoreWithOneClass[a] > scoreWithOneClass[b]; });
std::vector< int > out_indexes;
nonMaximumSuppression(decodedBoxes, scoreWithOneClass, in_indexes, out_indexes,
nms_threshold);
for (int k = 0; k < out_indexes.size ( ) ; k + + ) {
outBuff[outBoxNum][0] = out_indexes[k]; //image id
outBuff[outBoxNum][1] = i; //labelid
outBuff[outBoxNum][2] = scoreWithOneClass[out_indexes[k]]; //scores
outBuff[outBoxNum][3] =
decodedBoxes[out_indexes[k]].xmin * inputImageWidth / 300;
outBuff[outBoxNum][4] =
decodedBoxes[out_indexes[k]].ymin * inputImageHeight / 300;
outBuff[outBoxNum][5] =
decodedBoxes[out_indexes[k]].xmax * inputImageWidth / 300;
outBuff[outBoxNum][6] =
decodedBoxes[out_indexes[k]].ymax * inputImageHeight / 300;
outBoxNum++;
}
}
MS_PRINT("outBoxNum %d", outBoxNum);
for (int i = 0; i < outBoxNum ; + + i ) {
std::string tmpid_str = std::to_string(outBuff[i][0]);
result += tmpid_str; // image ID
result += "_";
// tmpid_str = std::to_string(outBuff[i][1]);
MS_PRINT("label_classes i %d, outBuff %d",i, (int) outBuff[i][1]);
tmpid_str = label_classes[(int) outBuff[i][1]];
result += tmpid_str; // label id
result += "_";
tmpid_str = std::to_string(outBuff[i][2]);
result += tmpid_str; // scores
result += "_";
tmpid_str = std::to_string(outBuff[i][3]);
result += tmpid_str; // xmin
result += "_";
tmpid_str = std::to_string(outBuff[i][4]);
result += tmpid_str; // ymin
result += "_";
tmpid_str = std::to_string(outBuff[i][5]);
result += tmpid_str; // xmax
result += "_";
tmpid_str = std::to_string(outBuff[i][6]);
result += tmpid_str; // ymax
result += ";";
}
return result;
}
```
