Skip to content

D
Docs

XKZJ_WCL / Docs
与 Fork 源项目一致

Fork自 OpenHarmony / Docs

通知 1
Star 0
Fork 0
D
Docs

体验新版 GitCode,发现更多精彩内容 >>

提交 9d80dfd6 编写于 作者: A Annie_wang
浏览文件
操作

update docs 

Signed-off-by: NAnnie_wang <annie.wangli@huawei.com>
上级 9a9e637f
隐藏空白更改
内联 并排
Showing with 111 addition and 45 deletion
en/device-dev/subsystems/subsys-build-all.md
浏览文件 @ 9d80dfd6
......@@ -143,28 +143,28 @@ To ensure that chipset and product solutions are decoupled from OpenHarmony, you
```shell
/build # Directory for build
/build # Directory for build
├── __pycache__
├── build_scripts/ # Python scripts for build
├── build_scripts/ # Python scripts for build
├── common/
├── config/ # Build-related configuration
├── config/ # Build-related configuration
├── core
│ └── gn/ # BUILD.gn configuration
│ └── gn/ # BUILD.gn configuration
└── build_scripts/
├── docs
gn_helpers.py*
lite/ # hb and preloader entry
lite/ # hb and preloader entry
misc/
├── ohos # Configuration of OpenHarmony build and packaging
│ ├── kits # Kits build and packaging templates and processing
│ ├── ndk # NDK templates and processing
│ ├── notice # Notice templates and processing
│ ├── packages # Distribution packaging templates and processing
│ ├── sa_profile # SA profiles and processing
│ ├── sdk # SDK templates and processing, which contains the module configuration in the SDK
│ └── testfwk # Testing-related processing
├── ohos.gni* # Common .gni files (facilitating one-time import of each module)
├── ohos # Configuration of OpenHarmony build and packaging
│ ├── kits # Kits build and packaging templates and processing
│ ├── ndk # NDK templates and processing
│ ├── notice # Notice templates and processing
│ ├── packages # Distribution packaging templates and processing
│ ├── sa_profile # SA profiles and processing
│ ├── sdk # SDK templates and processing, which contains the module configuration in the SDK
│ └── testfwk # Testing-related processing
├── ohos.gni* # Common .gni files (facilitating one-time import of each module)
├── ohos_system.prop
├── ohos_var.gni*
├── prebuilts_download.sh*
......@@ -172,10 +172,10 @@ misc/
├── scripts/
├── subsystem_config.json
├── subsystem_config_example.json
├── templates/ # C/C++ build templates
├── templates/ # C/C++ build templates
├── test.gni*
├── toolchain # Build toolchain configuration
├── tools # Common tools
├── toolchain # Build toolchain configuration
├── tools # Common tools
├── version.gni
├── zip.py*
......@@ -222,25 +222,25 @@ Then, run the build commands in command line (CLI) mode or hb mode.
- The **./build.sh** command supports the following options:
```shell
-h, --help # Display help information and exit.
--source-root-dir=SOURCE_ROOT_DIR # Specify the path.
--product-name=PRODUCT_NAME # Specify the product name.
--device-name=DEVICE_NAME # Specify the device name.
--target-cpu=TARGET_CPU # Specify the CPU.
--target-os=TARGET_OS # Specify the operating system.
-T BUILD_TARGET, --build-target=BUILD_TARGET # Specify one or more targets to build.
--gn-args=GN_ARGS # Specify GN parameters.
--ninja-args=NINJA_ARGS # Specify Ninja parameters.
-v, --verbose # Display all commands used.
--keep-ninja-going # Keep Ninja going until 1,000,000 jobs fail.
-h, --help # Display help information and exit.
--source-root-dir=SOURCE_ROOT_DIR # Specify the path.
--product-name=PRODUCT_NAME # Specify the product name.
--device-name=DEVICE_NAME # Specify the device name.
--target-cpu=TARGET_CPU # Specify the CPU.
--target-os=TARGET_OS # Specify the operating system.
-T BUILD_TARGET, --build-target=BUILD_TARGET # Specify one or more targets to build.
--gn-args=GN_ARGS # Specify GN parameters.
--ninja-args=NINJA_ARGS # Specify Ninja parameters.
-v, --verbose # Display all commands used.
--keep-ninja-going # Keep Ninja going until 1,000,000 jobs fail.
--jobs=JOBS
--export-para=EXPORT_PARA
--build-only-gn # Perform GN parsing and do not run Ninja.
--ccache # (Optional) Use ccache for build. You need to install ccache locally.
--fast-rebuild # Specify whether to allow fast rebuild. The default value is False.
--log-level=LOG_LEVEL # Specify the log level used in the build process. The options are debug, info, and error. The default value is info.
--device-type=DEVICE_TYPE # Specify the device type. The default value is default.
--build-variant=BUILD_VARIANT # Specify the device operation mode. The default value is user.
--build-only-gn # Perform GN parsing and do not run Ninja.
--ccache # (Optional) Use ccache for build. You need to install ccache locally.
--fast-rebuild # Specify whether to allow fast rebuild. The default value is False.
--log-level=LOG_LEVEL # Specify the log level used in the build process. The options are debug, info, and error. The default value is info.
--device-type=DEVICE_TYPE # Specify the device type. The default value is default.
--build-variant=BUILD_VARIANT #Specify the device operation mode. The default value is user.
```
2. Using the hb tool
......@@ -381,4 +381,4 @@ You can add and build a product, component, chipset solution, and module. For de
- [Information Collected by the Open Source Software Notice](subsys-build-reference.md#information-collected-by-the-open-source-software-notice)
- [Parameters for Accelerating Local Build](subsys-build-reference.md#parameters-for-accelerating-local-build)
- [Viewing Ninja Build Information](subsys-build-reference.md#viewing-ninja-build-information)
- [Customizing the chip_prod Image](subsys-build-reference.md#customizing-the-chip_prod-image)
en/device-dev/subsystems/subsys-build-reference.md
浏览文件 @ 9d80dfd6
......@@ -55,8 +55,8 @@ The dependency between modules can be classified into **deps** (left in the figu
external_deps = [
"part1:module1",
...
] # Inter-component dependency. The dependent module must be declared in inner_kits by the dependent component.
part_name = "part2" # (Mandatory) Name of the component to which the module belongs.
] # Inter-component dependency. The dependent module must be declared in inner_kits by the dependent component.
part_name = "part2" # (Mandatory) Name of the component to which the module belongs.
}
```
......@@ -71,14 +71,14 @@ Sanitizer configuration example:
``` shell
ohos_shared_library("example") {
sanitize = {
cfi = true # Enable the CFI check.
cfi_cross_dso = true # Enable the cross-DSO CFI check.
integer_overflow = true # Enable the integer overflow check.
boundary_sanitize = true # Enable the bounds check.
ubsan = true # Enable some UBSAN options.
all_ubsan = true # Enable all UBSAN options.
debug = true # Enable the debug mode, which is disabled by default.
blocklist = "./blocklist.txt" # Path of the blocklist.
cfi = true # Enable the CFI check.
cfi_cross_dso = true # Enable the cross-DSO CFI check.
integer_overflow = true # Enable the integer overflow check.
boundary_sanitize = true # Enable the bounds check.
ubsan = true # Enable some UBSAN options.
all_ubsan = true # Enable all UBSAN options.
debug = true # Enable the debug mode, which is disabled by default.
blocklist = "./blocklist.txt" # Path of the blocklist.
}
...
}
......@@ -198,3 +198,69 @@ You can graphically display the build time as follows:
1. Click **Success** under **Static Check**.
2. Click **Output** in the **Output** column. The **build.trace.html** file is displayed in the **build_trace** column on the left. Click the file to open it.
## Customizing the chip_prod Image
### When to Use
The different capabilities for the products in the same chip solution are placed in the **chip_prod** partition. You need to generate the **chip_prod.img** specific to the product.
### Procedure
1. Configure the **config.json** file.
In the **config.json** file, add **chipprod_config_path**, which specifies the path of the product definition file.
The file is named **chip_product_list.gni**, and in the **chip_product_list = ["productA", "productB", ...]** format.
Example:
To customize **chip_prod.img** for **MyProduct**, modify the **//vendor/Product vendor/MyProduct/config.json** as follows:
```shell
{
"product_name": "MyProduct", # Product name.
"version": "3.0", # config.json version, which is 3.0.
"chipprod_config_path": "", # (Optional) Path of the chipprod configuration file.
"subsystems": [
{
"subsystem": "arkui", # Subsystem of the product.
"components": [
{
"component": "ace_engine",
"features":[ "ace_engine_feature_enable_web = true",
"ace_engine_feature_enable_accessibility = true" ] }
]
},
{
...
}
...
More subsystems and components.
}
}
```
2. Configure the module.
If the configuration file has different product configurations, for example, to generate **chip_prod.img** for product A, you need to configure **install_images** and **module_install_dir** for module compilation.
The following uses **ohos_prebuilt_executable** as an example:
```shell
ohos_prebuilt_executable("moduleXXX"){
install_images = [ "chip_prod" ]
module_install_dir = "productA/etc/***" # The path must start with productA.
}
```
3. Run the build command.
```shell
./build.sh --product-name {product_name} --build-target chip_prod_image
```
4. Generate the images.
If products A and B are defined (**chip_product_list = ["productA", "productB"]**) and a module is installed in the products, the following images are generated:
```
images/productA/chip_prod.img
images/productB/chip_prod.img
```
Markdown is supported
0% .
You are about to add 0 people to the discussion. Proceed with caution.
先完成此消息的编辑!
想要评论请 注册