!632 文档更新

Merge pull request !632 from duangavin123/master

en/device-dev/Readme-EN.md

-# Overview<a name="EN-US_TOPIC_0000001191785779"></a>
+# Overview<a name="EN-US_TOPIC_0000001152533331"></a>
 
 -   [System Types](#section767218232110)
 -   [Document Outline](#section19810171681218)
@@ -69,7 +69,7 @@ In addition, OpenHarmony provides a series of optional system components that ca
 </td>
 <td class="cellrowborder" valign="top" width="35.61356135613561%" headers="mcps1.2.4.1.2 "><p id="p857711379158"><a name="p857711379158"></a><a name="p857711379158"></a>Using basic capabilities of <span id="text8928941123820"><a name="text8928941123820"></a><a name="text8928941123820"></a>OpenHarmony</span></p>
 </td>
-<td class="cellrowborder" valign="top" width="35.91359135913591%" headers="mcps1.2.4.1.3 "><a name="ul1577103716159"></a><a name="ul1577103716159"></a><ul id="ul1577103716159"><li><a href="kernel/kernel-lite.md">Kernel</a></li><li><a href="driver/Readme-EN.md">HDF</a></li><li><a href="subsystems/Readme-EN.md">Subsystems</a></li><li><a href="security/security-guidelines-overall.md">Security Guidelines</a></li><li><a href="security/security-privacy-protection.md">Privacy Protection</a></li></ul>
+<td class="cellrowborder" valign="top" width="35.91359135913591%" headers="mcps1.2.4.1.3 "><a name="ul1577103716159"></a><a name="ul1577103716159"></a><ul id="ul1577103716159"><li><a href="kernel/kernel-lite-mini.md">HarmonyOS Kernel Development Guide (LiteOS-M)</a></li><li><a href="kernel/kernel-lite-small.md">HarmonyOS Kernel Development Guide (LiteOS-A)</a></li><li><a href="driver/Readme-EN.md">HDF</a></li><li><a href="subsystems/Readme-EN.md">Subsystems</a></li><li><a href="security/security-guidelines-overall.md">Security Guidelines</a></li><li><a href="security/security-privacy-protection.md">Privacy Protection</a></li></ul>
 </td>
 </tr>
 <tr id="row10602193719152"><td class="cellrowborder" valign="top" width="28.472847284728473%" headers="mcps1.2.4.1.1 "><p id="p857873713152"><a name="p857873713152"></a><a name="p857873713152"></a>Advanced development</p>
@@ -90,7 +90,7 @@ In addition, OpenHarmony provides a series of optional system components that ca
 </td>
 <td class="cellrowborder" valign="top" width="35.61356135613561%" headers="mcps1.2.4.1.2 "><p id="p45798376158"><a name="p45798376158"></a><a name="p45798376158"></a>Contributing components to <span id="text207913212498"><a name="text207913212498"></a><a name="text207913212498"></a>OpenHarmony</span></p>
 </td>
-<td class="cellrowborder" valign="top" width="35.91359135913591%" headers="mcps1.2.4.1.3 "><a name="ul957919379156"></a><a name="ul957919379156"></a><ul id="ul957919379156"><li><a href="bundles/bundles-standard-rules.md">Component Development Specifications</a></li><li><a href="bundles/bundles-guide.md">Component Development Guidelines</a></li><li><a href="bundles/bundles-demo.md">HPM User Guide</a></li></ul>
+<td class="cellrowborder" valign="top" width="35.91359135913591%" headers="mcps1.2.4.1.3 "><a name="ul957919379156"></a><a name="ul957919379156"></a><ul id="ul957919379156"><li><a href="bundles/bundles-standard-rules.md">Bundle Development Specifications</a></li><li><a href="bundles/bundles-guide.md">Bundle Development Guidelines</a></li><li><a href="bundles/bundles-demo.md">Bundle Development Example</a></li></ul>
 </td>
 </tr>
 <tr id="row260193701512"><td class="cellrowborder" valign="top" width="28.472847284728473%" headers="mcps1.2.4.1.1 "><p id="p95794372155"><a name="p95794372155"></a><a name="p95794372155"></a>Reference</p>
@@ -114,11 +114,11 @@ In addition, OpenHarmony provides a series of optional system components that ca
 </th>
 </tr>
 </thead>
-<tbody><tr id="row9662532514"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p066105317513"><a name="p066105317513"></a><a name="p066105317513"></a>About <span id="text1523091643"><a name="text1523091643"></a><a name="text1523091643"></a>OpenHarmony</span></p>
+<tbody><tr id="row9662532514"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p066105317513"><a name="p066105317513"></a><a name="p066105317513"></a>About <span id="text70243343"><a name="text70243343"></a><a name="text70243343"></a>OpenHarmony</span></p>
 </td>
-<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p16673531512"><a name="p16673531512"></a><a name="p16673531512"></a>Getting familiar with <span id="text280142300"><a name="text280142300"></a><a name="text280142300"></a>OpenHarmony</span></p>
+<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p16673531512"><a name="p16673531512"></a><a name="p16673531512"></a>Getting familiar with <span id="text897788591"><a name="text897788591"></a><a name="text897788591"></a>OpenHarmony</span></p>
 </td>
-<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul10673531517"></a><a name="ul10673531517"></a><ul id="ul10673531517"><li><a href="https://gitee.com/openharmony" target="_blank" rel="noopener noreferrer">About OpenHarmony</a></li><li><a href="glossary/glossary.md">Glossary</a></li></ul>
+<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul10673531517"></a><a name="ul10673531517"></a><ul id="ul10673531517"><li><a href="https://gitee.com/openharmony/docs/blob/master/en/OpenHarmony-Overview.md" target="_blank" rel="noopener noreferrer">About OpenHarmony</a></li><li><a href="glossary/glossary.md">Glossary</a></li></ul>
 </td>
 </tr>
 <tr id="row267155313513"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p13671853205113"><a name="p13671853205113"></a><a name="p13671853205113"></a>Development resources</p>
@@ -137,31 +137,23 @@ In addition, OpenHarmony provides a series of optional system components that ca
 </tr>
 <tr id="row1168155365119"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p96810536514"><a name="p96810536514"></a><a name="p96810536514"></a>Basic capabilities</p>
 </td>
-<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p136812535511"><a name="p136812535511"></a><a name="p136812535511"></a>Using basic capabilities of <span id="text2027331797"><a name="text2027331797"></a><a name="text2027331797"></a>OpenHarmony</span></p>
+<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p136812535511"><a name="p136812535511"></a><a name="p136812535511"></a>Using basic capabilities of <span id="text1468659507"><a name="text1468659507"></a><a name="text1468659507"></a>OpenHarmony</span></p>
 </td>
-<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul1954915235272"></a><a name="ul1954915235272"></a><ul id="ul1954915235272"><li><a href="kernel/kernel-standard.md">Kernel</a></li><li><a href="driver/Readme-EN.md">HDF</a></li><li><a href="subsystems/Readme-EN.md">Subsystems</a></li><li><a href="security/security-privacy-protection.md">Security Guidelines</a></li><li><a href="security/security-privacy-protection.md">Privacy Protection</a></li></ul>
-</td>
-</tr>
-<tr id="row1368195345111"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p16681853145115"><a name="p16681853145115"></a><a name="p16681853145115"></a>Advanced development</p>
-</td>
-<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p1568753135116"><a name="p1568753135116"></a><a name="p1568753135116"></a>Developing smart devices based on system capabilities</p>
-</td>
-<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul136895314518"></a><a name="ul136895314518"></a><ul id="ul136895314518"><li><a href="guide/device-clock-guide.md">Development Example for Clock Apps</a></li><li><a href="guide/device-driver-demo.md">Development Example for Platform Drivers</a></li><li><a href="guide/device-outerdriver-demo.md">Development Example for Peripheral Drivers</a></li></ul>
+<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul1954915235272"></a><a name="ul1954915235272"></a><ul id="ul1954915235272"><li><a href="kernel/kernel-standard.md">Kernel Development Guide</a></li><li><a href="driver/Readme-EN.md">HDF</a></li><li><a href="subsystems/Readme-EN.md">Subsystems</a></li><li><a href="security/security-guidelines-overall.md">Security Guidelines</a></li><li><a href="security/security-privacy-protection.md">Privacy Protection</a></li></ul>
 </td>
 </tr>
 <tr id="row66915375119"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p4696535512"><a name="p4696535512"></a><a name="p4696535512"></a>Porting and adaptation</p>
 </td>
 <td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p185185615284"><a name="p185185615284"></a><a name="p185185615284"></a>Porting and adapting the <span id="text1434016533511"><a name="text1434016533511"></a><a name="text1434016533511"></a>OpenHarmony</span> to a third-party library</p>
 </td>
-<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><p id="p10262183114555"><a name="p10262183114555"></a><a name="p10262183114555"></a><a href="porting/porting-thirdparty.md">Third-Party Library Porting Guide</a></p>
-<p id="p123471211096"><a name="p123471211096"></a><a name="p123471211096"></a><a href="porting/standard-system-porting-guide">Standard  System SoC Porting Guide</a></p>
+<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul14724164204819"></a><a name="ul14724164204819"></a><ul id="ul14724164204819"><li><a href="porting/standard-system-porting-guide.md">Standard System SoC Porting Guide</a></li></ul>
 </td>
 </tr>
 <tr id="row869853125119"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p3691530511"><a name="p3691530511"></a><a name="p3691530511"></a>Contributing components</p>
 </td>
-<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p1469115335113"><a name="p1469115335113"></a><a name="p1469115335113"></a>Contributing components to <span id="text262674084"><a name="text262674084"></a><a name="text262674084"></a>OpenHarmony</span></p>
+<td class="cellrowborder" valign="top" width="36.053605360536054%" headers="mcps1.2.4.1.2 "><p id="p1469115335113"><a name="p1469115335113"></a><a name="p1469115335113"></a>Contributing components to <span id="text1180831622"><a name="text1180831622"></a><a name="text1180831622"></a>OpenHarmony</span></p>
 </td>
-<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul87045395116"></a><a name="ul87045395116"></a><ul id="ul87045395116"><li><a href="bundles/bundles-standard-rules.md">Component Development Specifications</a></li><li><a href="bundles/bundles-guide.md">Component Development Guidelines</a></li><li><a href="bundles/bundles-demo.md">HPM User Guide</a></li></ul>
+<td class="cellrowborder" valign="top" width="36.07360736073608%" headers="mcps1.2.4.1.3 "><a name="ul44949625110"></a><a name="ul44949625110"></a><ul id="ul44949625110"><li><a href="bundles/bundles-standard-rules.md">Bundle Development Specifications</a></li><li><a href="bundles/bundles-guide.md">Bundle Development Guidelines</a></li><li><a href="bundles/bundles-demo.md">Bundle Development Example</a></li></ul>
 </td>
 </tr>
 <tr id="row1170153125110"><td class="cellrowborder" valign="top" width="27.872787278727873%" headers="mcps1.2.4.1.1 "><p id="p16701253195118"><a name="p16701253195118"></a><a name="p16701253195118"></a>Reference</p>

en/device-dev/get-code/gettools-acquire.md

@@ -69,7 +69,6 @@ OpenHarmony provides the following two types of Docker environments for you to q
 </tbody>
 </table>
 
-
 ## Preparations<a name="section7337134183512"></a>
 
 Before using the Docker environment, perform the following operations:
@@ -151,10 +150,8 @@ hb set
  .
 ```
 
-**Figure  1**  Setting page<a name="fig18712183616135"></a>  
-
-
-![](figure/en-us_image_0000001101413884.png)
+**Figure  1**  Setting page<a name="fig7947145854013"></a>  
+![](figure/setting-page.png "setting-page")
 
 >![](../public_sys-resources/icon-note.gif) **NOTE:** 
 >The mapping between the development board and the building GUI:

en/device-dev/get-code/gettools-ide.md

@@ -9,7 +9,7 @@ HUAWEI DevEco Device Tool is a one-stop integrated development environment \(IDE
 
 The roadmap of Huawei DevEco Device Tool for supporting OpenHarmony device development is shown in the figure below.
 
-![](figure/3-27.png)
+![](figure/evolution-roadmap.png)
 
 ## Acquiring the Application Development Tool \(HUAWEI DevEco Studio\)<a name="section0904101019258"></a>
 

en/device-dev/get-code/sourcecode-acquire.md

@@ -101,12 +101,12 @@ This document describes how to acquire OpenHarmony source code and provides its
     ```
     repo init -u https://gitee.com/openharmony/manifest.git -b OpenHarmony_1.0.1_release --no-repo-verify
     repo sync -c  
-    repo forall -c 'git lfs pull'
+    repo[Release-Notes](../../release-notes/Readme.md) forall -c 'git lfs pull'
     ```
 
 -   Obtaining the source code of other OpenHarmony releases
 
-    For details about how to obtain the source code of other OpenHarmony releases, see the  [Release Notes](../../release-notes/Readme.md).
+    For details about how to obtain the source code of other OpenHarmony releases, see the  [Release-Notes](../../release-notes/Readme.md).
 
 
 ## Method 2: Acquiring Source Code from HPM<a name="section463013147412"></a>
@@ -154,10 +154,8 @@ You must install  **Node.js**  and HPM on your local PC. The installation proced
     3.  Specify filter criteria, such as the bundle type \(for example:  **Board support**  and  **Kernel support**\), to further filter the distributions.
     4.  Locate your desired distribution and click it to view details.
 
-        **Figure  1**  HPM page<a name="fig838103114320"></a>  
-        
-
-        ![](figure/en-us_image_0000001119915556.png)
+        **Figure  1**  HPM page<a name="fig414435103619"></a>  
+        ![](figure/hpm-page.png "hpm-page")
 
 2.  Learn more about the distribution.
 
@@ -165,10 +163,8 @@ You must install  **Node.js**  and HPM on your local PC. The installation proced
     2.  Click  **Download**  to download the distribution to your local PC.
     3.  Click  **Custom**  to add or delete bundles of the distribution.
 
-    **Figure  2**  Example distribution<a name="fig1329851510414"></a>  
-    
-
-    ![](figure/en-us_image_0000001119755646.png)
+    **Figure  2**  Example distribution<a name="fig950763112375"></a>  
+    ![](figure/example-distribution.png "example-distribution")
 
 3.  Customize bundles.
     1.  Access the  **Custom solution**  page, as shown in the following figure.
@@ -176,10 +172,8 @@ You must install  **Node.js**  and HPM on your local PC. The installation proced
     3.  Enter the basic information about your project, including the bundle name, version, and description, on the right pane.
     4.  Click  **Download**. The system then generates the OpenHarmony code structure file \(for example,  **my\_cust\_dist.zip**\) and saves it to your local PC.
 
-        **Figure  3**  Customizing bundles<a name="fig05036599014"></a>  
-        
-
-        ![](figure/en-us_image_0000001166715379.png)
+        **Figure  3**  Customizing bundles<a name="fig13979182053817"></a>  
+        ![](figure/customizing-bundles.png "customizing-bundles")
 
 4.  Download and install bundles.
     1.  Decompress the downloaded file using the CLI tool CMD \(shell in Linux\).
@@ -192,7 +186,7 @@ You must install  **Node.js**  and HPM on your local PC. The installation proced
 To ensure the download performance, you are advised to download the source code or the corresponding solution from the image library of the respective site listed in the table below.
 
 >![](../public_sys-resources/icon-note.gif) **NOTE:** 
->-   The table below provides only the sites for downloading the latest OpenHarmony master and LTS code. For details about how to obtain the source code of earlier versions, see the  [Release Notes](../../release-notes/Readme.md).
+>-   The table below provides only the sites for downloading the latest OpenHarmony master and LTS code. For details about how to obtain the source code of earlier versions, see the  [Release-Notes](../../release-notes/Readme.md).
 >-   The Master 1.0 version is no longer maintained.
 
 **Table  1**  Sites for acquiring source code from image sites
@@ -256,9 +250,9 @@ To ensure the download performance, you are advised to download the source code
 </td>
 <td class="cellrowborder" valign="top" width="25%"><p id="p194141849163919"><a name="p194141849163919"></a><a name="p194141849163919"></a><strong id="b1094411391670"><a name="b1094411391670"></a><a name="b1094411391670"></a>Version Information</strong></p>
 </td>
-<td class="cellrowborder" valign="top" width="25%"><p id="p8414649193919"><a name="p8414649193919"></a><a name="p8414649193919"></a><strong id="b172399013"><a name="b172399013"></a><a name="b172399013"></a>Site</strong></p>
+<td class="cellrowborder" valign="top" width="25%"><p id="p8414649193919"><a name="p8414649193919"></a><a name="p8414649193919"></a><strong id="b311804727"><a name="b311804727"></a><a name="b311804727"></a>Site</strong></p>
 </td>
-<td class="cellrowborder" valign="top" width="25%"><p id="p13415149133914"><a name="p13415149133914"></a><a name="p13415149133914"></a><strong id="b294086750"><a name="b294086750"></a><a name="b294086750"></a>SHA-256 Verification Code</strong></p>
+<td class="cellrowborder" valign="top" width="25%"><p id="p13415149133914"><a name="p13415149133914"></a><a name="p13415149133914"></a><strong id="b197076505"><a name="b197076505"></a><a name="b197076505"></a>SHA-256 Verification Code</strong></p>
 </td>
 </tr>
 <tr id="row4769431134919"><td class="cellrowborder" valign="top" width="25%"><p id="p97691031124913"><a name="p97691031124913"></a><a name="p97691031124913"></a>Full code (for standard systems)</p>
@@ -319,7 +313,7 @@ To ensure the download performance, you are advised to download the source code
 </td>
 <td class="cellrowborder" valign="top" width="25%"><p id="p1093810218417"><a name="p1093810218417"></a><a name="p1093810218417"></a><strong id="b1124015405556"><a name="b1124015405556"></a><a name="b1124015405556"></a>Version Information</strong></p>
 </td>
-<td class="cellrowborder" valign="top" width="25%"><p id="p9938132648"><a name="p9938132648"></a><a name="p9938132648"></a><strong id="b1331994007"><a name="b1331994007"></a><a name="b1331994007"></a>Site</strong></p>
+<td class="cellrowborder" valign="top" width="25%"><p id="p9938132648"><a name="p9938132648"></a><a name="p9938132648"></a><strong id="b1902250690"><a name="b1902250690"></a><a name="b1902250690"></a>Site</strong></p>
 </td>
 <td class="cellrowborder" valign="top" width="25%"><p id="p12520113711011"><a name="p12520113711011"></a><a name="p12520113711011"></a><strong id="b19256751175516"><a name="b19256751175516"></a><a name="b19256751175516"></a>SHA-256 Verification Code</strong></p>
 </td>

en/device-dev/guide/device-driver-demo.md

@@ -34,7 +34,7 @@ In this example, an I2C driver is used.  [Figure 1](#fig148041484161)  shows the
 
 ## Preparations<a name="section6926133918422"></a>
 
-Follow the instructions in  [Environment Setup for Standard System](../quick-start/quickstart-standard-description.md).
+Follow the instructions in  [Environment Setup for Standard System](../quick-start/quickstart-standard-overview.md).
 
 >![](../public_sys-resources/icon-notice.gif) **NOTICE:** 
 >This development example applies to standard, small, and mini OpenHarmony systems. The following sections use the standard system as an example. You can refer to the specific guide for your system to set up the environment.

en/device-dev/kernel/kernel-small-start-user.md

@@ -48,8 +48,8 @@ During system startup,  **OsUserInitProcess**  is called to start the  **init**
 
 Common compilation modes of user-space programs include:
 
-1.  [Compilation using the framework](../quick-start/quickstart-lite-steps-board3516-running.md)
-2.  Manual compilation
+1. [Compilation using the framework](../quick-start/quickstart-lite-steps-hi3516-running.md)
+2. Manual compilation
 
     Example:
 
@@ -57,7 +57,7 @@ Common compilation modes of user-space programs include:
     clang --target=arm-liteos --sysroot=prebuilts/lite/sysroot -o helloworld helloworld.c
     ```
 
-    Before running the  **clang**  command, install the LLVM compiler. For details, see  [Installing LLVM](../quick-start/quickstart-lite-env-setup-lin.md).
+    Before running the  **clang**  command, install the LLVM compiler. For details, see  [Installing LLVM](../quick-start/quickstart-lite-env-setup-linux.md).
 
     **--target=arm-liteos**: specifies that the compilation platform is arm-liteos.
 

en/device-dev/porting/Readme-EN.md

@@ -23,7 +23,7 @@ The download steps for other resources are the same as those in the mainline ver
 
 - [Mini System SoC Porting Guide](porting-minichip.md)
   - [Porting Preparations](porting-chip-prepare.md)
-    - [Before You Start](porting-chip-prepare-knows.md)
+    - [Before You Start](oem_transplant_chip_prepare_knows.md)
     - [Building Adaptation Process](porting-chip-prepare-process.md)
   - [Kernel Porting](porting-chip-kernel.md)
     - [Overview](porting-chip-kernel-overview.md)

en/device-dev/porting/porting-chip-prepare-knows.md → en/device-dev/porting/oem_transplant_chip_prepare_knows.md

-# Before You Start<a name="EN-US_TOPIC_0000001064030766"></a>
+# Before You Start<a name="EN-US_TOPIC_0000001199722625"></a>
 
 -   [Porting Directory](#section284217487490)
 -   [Porting Process](#section639315306506)

en/device-dev/porting/porting-chip-board-bundle.md

-# Third-party Module Adaptation<a name="EN-US_TOPIC_0000001117478960"></a>
+# Third-party Module Adaptation<a name="EN-US_TOPIC_0000001153842842"></a>
 
 To use third-party modules in the  **third\_party**  directory, you may need to adapt the modules. This section uses mbedTLS as an example to describe how to integrate the adaptation code with the OpenHarmony compilation framework. For the principles of mbedTLS and the specific logic of the adaptation code, see the adaptation guide on the mbedTLS official website.
 

en/device-dev/porting/porting-chip-board-component.md

-# System Modules<a name="EN-US_TOPIC_0000001063871490"></a>
+# System Modules<a name="EN-US_TOPIC_0000001199722621"></a>
 
 -   [SAMGR](#section105874301910)
 -   [DFX](#section20064420420)

en/device-dev/porting/porting-chip-board-driver.md

-# Board-Level Driver Adaptation<a name="EN-US_TOPIC_0000001063265278"></a>
+# Board-Level Driver Adaptation<a name="EN-US_TOPIC_0000001153683028"></a>
 
 To implement board-level driver adaptation, perform the following steps:
 

en/device-dev/porting/porting-chip-board-hal.md

-# Implementation of APIs at the HAL<a name="EN-US_TOPIC_0000001062862633"></a>
+# Implementation of APIs at the HAL<a name="EN-US_TOPIC_0000001199722623"></a>
 
 -   [Utils](#section1394788286)
 -   [IoT Peripheral Subsystem](#section958113200811)

en/device-dev/porting/porting-chip-board-overview.md

-# Overview<a name="EN-US_TOPIC_0000001064031492"></a>
+# Overview<a name="EN-US_TOPIC_0000001153683022"></a>
 
 -   [Porting Process](#section1283115812294)
 -   [Board-Level Directory Specifications](#section6204129143013)

en/device-dev/porting/porting-chip-board-xts.md

-# XTS<a name="EN-US_TOPIC_0000001063110883"></a>
+# XTS<a name="EN-US_TOPIC_0000001199722627"></a>
 
 -   [Introduction](#section6725155811454)
     -   [Adding the XTS Subsystem to the Building Component](#section46981118105417)

en/device-dev/porting/porting-chip-board.md

-# Board-Level OS Porting<a name="EN-US_TOPIC_0000001062604739"></a>
+# Board-Level OS Porting<a name="EN-US_TOPIC_0000001199842515"></a>
 
 -   **[Overview](porting-chip-board-overview.md)**  
 

en/device-dev/porting/porting-chip-faqs.md

-# FAQ<a name="EN-US_TOPIC_0000001063192853"></a>
+# FAQ<a name="EN-US_TOPIC_0000001153683024"></a>
 
 -   [How Do I Mount the Heap Memory to the Kernel?](#section965418378552)
 

en/device-dev/porting/porting-chip-kernel-adjustment.md

-# Basic Kernel Adaptation<a name="EN-US_TOPIC_0000001063432950"></a>
+# Basic Kernel Adaptation<a name="EN-US_TOPIC_0000001199842517"></a>
 
 -   [Adaptation Process](#section14523241594)
 -   [Feature Configuration](#section112994366592)
@@ -15,7 +15,7 @@ Basic adaptation consists of the following steps:
 **Figure  1**  Startup process<a name="fig10838105524917"></a>  
 
 
-![](figure/en-us_image_0000001073943511.png)
+![](figure/startup-process.png)
 
 In the  **startup.S**  file, you must ensure that the entry function \(for example,  **reset\_vector**\) of the interrupt vector table is stored in the RAM start address specified by the link configuration files. The link configuration files of IAR, Keil, and GCC projects are  **xxx.icf**,  **xxx.sct**, and  **xxx.ld**, respectively. The startup file provided by the vendor does not need to be modified if the  **startup.S**  file has initialized the system clock and returned to the  **main**  function. Otherwise, the preceding functions need to be implemented.
 
@@ -63,6 +63,11 @@ The following table shows some typical configuration items:
 <td class="cellrowborder" valign="top" width="65.19%" headers="mcps1.2.3.1.2 "><p id="p1644094201917"><a name="p1644094201917"></a><a name="p1644094201917"></a>Switch of the queue feature. The values <strong id="b1514814454405"><a name="b1514814454405"></a><a name="b1514814454405"></a>1</strong> and <strong id="b114824504011"><a name="b114824504011"></a><a name="b114824504011"></a>0</strong> indicate that the switch is turned on and turned off, respectively.</p>
 </td>
 </tr>
+<tr id="row14294143784110"><td class="cellrowborder" valign="top" width="34.81%" headers="mcps1.2.3.1.1 "><p id="p529573794111"><a name="p529573794111"></a><a name="p529573794111"></a>LOSCFG_BASE_CORE_TSK_LIMIT</p>
+</td>
+<td class="cellrowborder" valign="top" width="65.19%" headers="mcps1.2.3.1.2 "><p id="p529503704116"><a name="p529503704116"></a><a name="p529503704116"></a>Maximum number of available tasks, excluding idle tasks. You can set this item based on your actual service requirements, or you can initially set it to a large value and adjust the value at a later time.</p>
+</td>
+</tr>
 <tr id="row16440124216198"><td class="cellrowborder" valign="top" width="34.81%" headers="mcps1.2.3.1.1 "><p id="p9440184271915"><a name="p9440184271915"></a><a name="p9440184271915"></a>LOSCFG_BASE_IPC_SEM</p>
 </td>
 <td class="cellrowborder" valign="top" width="65.19%" headers="mcps1.2.3.1.2 "><p id="p1044024261912"><a name="p1044024261912"></a><a name="p1044024261912"></a>Switch of the semaphore feature. The values <strong id="b0766102114312"><a name="b0766102114312"></a><a name="b0766102114312"></a>1</strong> and <strong id="b1876612254312"><a name="b1876612254312"></a><a name="b1876612254312"></a>0</strong> indicate that the switch is turned on and turned off, respectively.</p>

en/device-dev/porting/porting-chip-kernel-overview.md

-# Overview<a name="EN-US_TOPIC_0000001063870592"></a>
+# Overview<a name="EN-US_TOPIC_0000001153842840"></a>
 
 -   [Porting Scenario](#section93781277367)
 -   [Directory Specifications](#section18127744153119)
@@ -21,7 +21,7 @@ The kernel used by module chips is LiteOS Cortex-M, which consists of four modul
 **Figure  1**  Architecture of the LiteOS Cortex-M kernel<a name="fig10838105524917"></a>  
 
 
-![](figure/en-us_image_0000001072304191.png)
+![](figure/architecture-of-the-liteos-cortex-m-kernel.png)
 
 The directory structure of the kernel is described as follows:
 

en/device-dev/porting/porting-chip-kernel-verify.md

-# Kernel Porting Verification<a name="EN-US_TOPIC_0000001062953117"></a>
+# Kernel Porting Verification<a name="EN-US_TOPIC_0000001153842844"></a>
 
 Add the sample program file  **main.c**  to the  **device**  directory of the project and compile the file. After LOS\_KernelInit is complete, this sample program will create two tasks that loop the  **LOS\_TaskDelay**  function and print the log information cyclically. In this way, you can check whether system scheduling and the clock work properly.
 

en/device-dev/porting/porting-chip-kernel.md

-# Kernel Porting<a name="EN-US_TOPIC_0000001063110705"></a>
+# Kernel Porting<a name="EN-US_TOPIC_0000001153842846"></a>
 
 -   **[Overview](porting-chip-kernel-overview.md)**  
 

en/device-dev/porting/porting-chip-prepare-process.md

-# Building Adaptation Process<a name="EN-US_TOPIC_0000001063302771"></a>
+# Building Adaptation Process<a name="EN-US_TOPIC_0000001153683026"></a>
 
 -   [Building Adaptation Process](#section2159183845319)
 

en/device-dev/porting/porting-chip-prepare.md

-# Porting Preparations<a name="EN-US_TOPIC_0000001063252862"></a>
+# Porting Preparations<a name="EN-US_TOPIC_0000001199842513"></a>
 
--   **[Before You Start](porting-chip-prepare-knows.md)**  
+-   **[Before You Start](oem_transplant_chip_prepare_knows.md)**  
 
 -   **[Building Adaptation Process](porting-chip-prepare-process.md)**  
 

en/device-dev/porting/porting-smallchip-driver-oom.md

-# Device Driver Porting<a name="EN-US_TOPIC_0000001124154504"></a>
+# Device Driver Porting<a name="EN-US_TOPIC_0000001200252097"></a>
 
 -   [LCD Driver Porting](#section1574513454119)
 -   [Touchscreen Driver Porting](#section20284142116422)

en/device-dev/porting/porting-smallchip-driver-overview.md

-# Overview<a name="EN-US_TOPIC_0000001172160289"></a>
+# Overview<a name="EN-US_TOPIC_0000001154372312"></a>
 
 Drivers can be classified as platform drivers or device drivers. The platform drivers are generally in the SoC, such as the GPIO, I2C, and SPI drivers. The device drivers are typically outside of the SoC, such as the LCD, TP, and WLAN drivers.
 
-**Figure  1**  OpenHarmony driver classification<a name="fig11697182018375"></a>  
-
-
-![](figure/分类.png)
+**Figure  1**  OpenHarmony driver classification<a name="fig08631434121"></a>  
+![](figure/openharmony-driver-classification.png "openharmony-driver-classification")
 
 The Hardware Driver Foundation \(HDF\) is designed to work across OSs. The HDF driver framework provides strong support for drivers to achieve this goal. During HDF driver development, you are advised to use only the APIs provided by the HDF driver framework. Otherwise, the driver cannot be used across OSs. Before driver development, familiarize yourself with the  [HDF](../driver/driver-hdf-overview.md).
 

en/device-dev/porting/porting-smallchip-driver-plat.md

-# Platform Driver Porting<a name="EN-US_TOPIC_0000001170794079"></a>
+# Platform Driver Porting<a name="EN-US_TOPIC_0000001154372314"></a>
 
 Create a platform driver in the source code directory  **//device/vendor\_name/soc\_name/drivers**. If there is no repository for the vendor of your SoC, contact the  [device SIG](https://gitee.com/openharmony/community/blob/master/sig/sig-devboard/sig_devboard.md)  to create one.
 

en/device-dev/porting/porting-smallchip-driver.md

-# Driver Porting<a name="EN-US_TOPIC_0000001123149616"></a>
+# Driver Porting<a name="EN-US_TOPIC_0000001200252099"></a>
 
 -   **[Overview](porting-smallchip-driver-overview.md)**  
 

en/device-dev/porting/porting-smallchip-kernel-a.md

-# LiteOS Cortex-A<a name="EN-US_TOPIC_0000001113392962"></a>
+# LiteOS Cortex-A<a name="EN-US_TOPIC_0000001200171989"></a>
 
 -   [Overview](#section14876256185510)
     -   [Porting Scenario](#section1986014410569)
@@ -23,20 +23,20 @@ For details about the LiteOS Cortex-A directory specifications, see  [LiteOS Cor
 
 LiteOS Cortex-A provides the system initialization process and custom configuration options required for system running. During porting, pay attention to the functions related to hardware configuration in the initialization process.
 
-The LiteOS Cortex-A initialization process consists of five steps:
+The LiteOS Cortex-A initialization process consists of seven steps:
 
 1.  Add the  **target\_config.h**  file and compile the macros  **DDR\_MEM\_ADDR**  and  **DDR\_MEM\_SIZE**, which indicate the start address and length of the board memory, respectively. The prelinker script  **board.ld.S**  creates the linker script  **board.ld**  based on the two macros.
-2.  The kernel creates a kernel image based on the linker script  **board.ld**.
-3.  Operations such as initialization of the interrupt vector table and MMU page table are performed in the assembly files:  **reset\_vector\_up.S**  and  **reset\_vector\_mp.S**, from which a single-core CPU and a multi-core CPU start, respectively.
-4.  The assembly code in  **reset\_vector.S**  jumps to the  **main**  function of the C programming language to initialize the hardware clock, software timer, memory, and tasks. This process depends on the feature macro configuration in  **target\_config.h**  . The  **SystemInit**  task to be implemented in the board code is then created, and  **OsSchedStart\(\)**  is enabled for task scheduling.
-5.  The  **DeviceManagerStart**  function is called to initialize the HDF driver. This process is implemented by calling the driver configuration file  **hdf.hcs**  and driver source code in the board code.
+2.  Define  **g\_archMmuInitMapping**, the global array of MMU mappings, to specify the memory segment attributes and the virtual-to-physical address mappings. The memory mapping will be established based on this array during kernel startup.
+3.  If there are multiple cores, define  **struct SmpOps**, the handle to the slave core operation function. The  **SmpOps-\>SmpCpuOn**  function needs to implement the feature of waking up a slave core. Then, define the  **SmpRegFunc**  function and call the  **LOS\_SmpOpsSet**  interface to register the handle. The registration process is completed by starting the framework using  **LOS\_MODULE\_INIT\(SmpRegFunc, LOS\_INIT\_LEVEL\_EARLIEST\)**.
+4.  Create a kernel image based on the linker script  **board.ld**.
+5.  Perform operations such as initialization of the interrupt vector table and MMU page table are performed in the assembly files:  **reset\_vector\_up.S**  and  **reset\_vector\_mp.S**, from which a single-core CPU and a multi-core CPU start, respectively.
+6.  Enable the assembly code in  **reset\_vector.S**  to jump to the  **main**  function of the C programming language to initialize the hardware clock, software timer, memory, and tasks. This process depends on the feature macro configuration in  **target\_config.h**. Then, create the  **SystemInit**  task to be implemented in the board code, with  **OsSchedStart\(\)**  enabled for task scheduling.
+7.  Call the  **DeviceManagerStart**  function to initialize the HDF driver. This process is implemented by calling the driver configuration file  **hdf.hcs**  and drivers source code in the board code.
 
-Below is the overall initialization process.
+The figure below shows the overall initialization process.
 
-**Figure  1**  Overall initialization process<a name="fig10838105524917"></a>  
-
-
-![](figure/en-us_image_0000001126358814.png)
+**Figure  1**  Overall initialization process<a name="fig68283211926"></a>  
+![](figure/overall-initialization-process.png "overall-initialization-process")
 
 As can be seen from preceding figure, kernel basic adaptation involves the following parts:
 
@@ -114,25 +114,23 @@ As can be seen from preceding figure, kernel basic adaptation involves the follo
     </tbody>
     </table>
 
--   Implementing the  **SystemInit**  function to initialize services in the user space. Figure 2 shows a typical initialization scenario.
-
-    **Figure  1**  Service startup process<a name="fig15798236163510"></a>  
-    
+-   Implementing the  **SystemInit**  function to initialize services in the user space.  [\#EN-US\_TOPIC\_0000001200171989/fig15798236163510](#fig15798236163510)  shows a typical initialization scenario.
 
-    ![](figure/en-us_image_0000001126198996.png)
+    **Figure  2**  Service startup process<a name="fig1919217914418"></a>  
+    ![](figure/service-startup-process.png "service-startup-process")
 
--   Implementing the  **main**  function for basic kernel initialization and initialization of services in the board kernel space. Figure 3 shows the initialization process, where the kernel startup framework takes the lead in the initialization process. The light blue part in the figure indicates the phase in which external modules can be registered and started in the startup framework.
+-   Implementing the  **main**  function for basic kernel initialization and initialization of services in the board kernel space.  [Figure 3](#fig32611728133919)  shows the initialization process, where the kernel startup framework takes the lead in the initialization process. The light blue part in the figure indicates the phase in which external modules can be registered and started in the startup framework.
 
     >![](../public_sys-resources/icon-caution.gif) **CAUTION:** 
     >Modules at the same layer cannot depend on each other.
 
-    **Figure  2**  Kernel startup framework<a name="fig32611728133919"></a>  
+    **Figure  3**  Kernel startup framework<a name="fig32611728133919"></a>  
     ![](figure/kernel-startup-framework.jpg "kernel-startup-framework")
 
     **Table  2**  Startup framework layers
 
     <a name="table38544719428"></a>
-    <table><thead align="left"><tr id="row286134714423"><th class="cellrowborder" valign="top" width="34.089999999999996%" id="mcps1.2.3.1.1"><p id="p886164717423"><a name="p886164717423"></a><a name="p886164717423"></a>Level</p>
+    <table><thead align="left"><tr id="row286134714423"><th class="cellrowborder" valign="top" width="34.089999999999996%" id="mcps1.2.3.1.1"><p id="p886164717423"><a name="p886164717423"></a><a name="p886164717423"></a>Layer</p>
     </th>
     <th class="cellrowborder" valign="top" width="65.91%" id="mcps1.2.3.1.2"><p id="p586194716421"><a name="p586194716421"></a><a name="p586194716421"></a>Description</p>
     </th>
@@ -199,9 +197,9 @@ As can be seen from preceding figure, kernel basic adaptation involves the follo
     </tr>
     <tr id="row357517134414"><td class="cellrowborder" valign="top" width="34.089999999999996%" headers="mcps1.2.3.1.1 "><p id="p12575676449"><a name="p12575676449"></a><a name="p12575676449"></a>LOS_INIT_LEVEL_KMOD_TASK</p>
     </td>
-    <td class="cellrowborder" valign="top" width="65.91%" headers="mcps1.2.3.1.2 "><p id="p7128122619143"><a name="p7128122619143"></a><a name="p7128122619143"></a>Kernel task creation</p>
+    <td class="cellrowborder" valign="top" width="65.91%" headers="mcps1.2.3.1.2 "><p id="p7128122619143"><a name="p7128122619143"></a><a name="p7128122619143"></a>Kernel task creation.</p>
     <p id="p1657587184419"><a name="p1657587184419"></a><a name="p1657587184419"></a>This layer can be used to create kernel tasks (kernel thread and software timer tasks).</p>
-    <p id="p55485297219"><a name="p55485297219"></a><a name="p55485297219"></a>Example: creation of the resident resource reclaiming task, SystemInit task, and CPU usage statistics task.</p>
+    <p id="p55485297219"><a name="p55485297219"></a><a name="p55485297219"></a>Example: creation of the resident resource reclaiming task, SystemInit task, and CPU usage statistics task</p>
     </td>
     </tr>
     </tbody>

en/device-dev/porting/porting-smallchip-kernel-linux.md

-# Linux Kernel<a name="EN-US_TOPIC_0000001159912785"></a>
+# Linux Kernel<a name="EN-US_TOPIC_0000001200171987"></a>
 
 -   [Overview](#section6282121355111)
     -   [Basic Information](#section19589322515)
@@ -58,18 +58,16 @@ You can use the Bootloader provided by the chipset vendor or open-source U-Boot
 
 ## Verification<a name="section17318153325311"></a>
 
-Debug the  **init**  process, start shell, and run a simple program in the user space to check whether the kernel porting is successful. Below is the OS image structure of the OpenHarmony  [small system](https://device.harmonyos.com/en/docs/start/introduce/oem_minitinier_des-0000001105598722)  and the Linux user-space program startup process.
+Debug the  **init**  process, start shell, and run a simple program in the user space to check whether the kernel porting is successful. Below is the OS image structure of the OpenHarmony  [small system](../quick-start/quickstart-lite-overview.md)  and the Linux user-space program startup process.
 
-**Figure  1**  OS image structure and user-space program startup process based on the Linux kernel<a name="fig1296918391004"></a>  
-
-
-![](figure/en-us_image_0000001126354076.png)
+**Figure  1**  OS image structure and user-space program startup process based on the Linux kernel<a name="fig91631652715"></a>  
+![](figure/os-image-structure-and-user-space-program-startup-process-based-on-the-linux-kernel.png "os-image-structure-and-user-space-program-startup-process-based-on-the-linux-kernel")
 
 Based on the preceding process, the recommended verification procedure is as follows:
 
 1.  Create a root file system image.
 
-    Create a root file system image  **rootfs.img**  by following instructions in  [Adding a Chipset Solution and a Product Solution](https://device.harmonyos.com/en/docs/develop/subsystems/oem_subsys_build_guide-0000001060378721). As shown in the preceding figure, the startup process is closely related to the product configuration. You need to complete the following configuration when creating  **rootfs.img**:
+    Create a root file system image  **rootfs.img**  by following instructions in  [Adding a Chipset Solution and a Product Solution](../subsystems/subsys-build-mini-lite.md). As shown in the preceding figure, the startup process is closely related to the product configuration. You need to complete the following configuration when creating  **rootfs.img**:
 
     -   Component configuration
 
@@ -99,17 +97,13 @@ Based on the preceding process, the recommended verification procedure is as fol
 
     If the init startup log contains the version number, the init program is started properly:
 
-    **Figure  2**  Log indicating that the init process is started properly<a name="fig13510844174415"></a>  
-    
-
-    ![](figure/en-us_image_0000001172273945.jpg)
+    **Figure  2**  Log indicating that the init process is started properly<a name="fig1111661083719"></a>  
+    ![](figure/log-indicating-that-the-init-process-is-started-properly.png "log-indicating-that-the-init-process-is-started-properly")
 
     After entering the shell, run the  **ls**  command. The following figure shows the information printed over the serial port.
 
-    **Figure  3**  Information printed after the ls command is executed in the shell<a name="fig584415944917"></a>  
-    
-
-    ![](figure/en-us_image_0000001172393865.jpg)
+    **Figure  3**  Information printed after the ls command is executed in the shell<a name="fig64571257103717"></a>  
+    ![](figure/information-printed-after-the-ls-command-is-executed-in-the-shell.png "information-printed-after-the-ls-command-is-executed-in-the-shell")
 
 3.  Configure the NFS.
 

en/device-dev/porting/porting-smallchip-kernel.md

-# Kernel Porting<a name="EN-US_TOPIC_0000001105566322"></a>
+# Kernel Porting<a name="EN-US_TOPIC_0000001200171985"></a>
 
 -   **[LiteOS Cortex-A](porting-smallchip-kernel-a.md)**  
 

en/device-dev/porting/porting-smallchip-prepare-building.md

-# Compilation and Building<a name="EN-US_TOPIC_0000001105406466"></a>
+# Compilation and Building<a name="EN-US_TOPIC_0000001154212512"></a>
 
 -   [Compilation Environment Setup](#section3336103410314)
 -   [Introduction to the Compilation and Building Subsystem](#section354343816319)
@@ -6,7 +6,7 @@
 
 ## Compilation Environment Setup<a name="section3336103410314"></a>
 
-Set up the basic environment by following instructions in  [Ubuntu Build Environment](../quick-start/quickstart-lite-env-setup-lin.md). Both the user space and LiteOS Cortex-A kernel space are compiled using the LLVM compiler. If you choose to port the Linux kernel, run the following command to install the gcc-arm-linux-gnueabi cross compiler for compiling the Linux kernel-space image:
+Set up the basic environment by following instructions in  [Ubuntu Build Environment](../quick-start/quickstart-lite-env-setup-linux.md). Both the user space and LiteOS Cortex-A kernel space are compiled using the LLVM compiler. If you choose to port the Linux kernel, run the following command to install the gcc-arm-linux-gnueabi cross compiler for compiling the Linux kernel-space image:
 
 ```
 sudo apt-get install gcc-arm-linux-gnueabi
@@ -121,12 +121,12 @@ After learning the compilation framework and setting up the compilation environm
 
 3.  Edit the build script of the development board.
 
-    In the  **BUILD.gn**  file described in 1, build code related to the development board, such as code for the on-device driver, on-device interface adaptation \(media and graphics\), and SDK on the development board.
+    In the  **BUILD.gn**  file described in step  [1](#li20894101862), build code related to the development board, such as code for the on-device driver, on-device interface adaptation \(media and graphics\), and SDK on the development board.
 
     For example, edit the  **device/hisilicon/hispark\_taurus/BUILD.gn**  file as follows:
 
     ```
-    # It is recommended that the group name be the same as the developer board name.
+    # It is recommended that the group name be the same as the development board name.
     group("hispark_taurus") {   
       deps = [ "//kernel/linux/patches:linux_kernel" ] # Start kernel compilation.
       deps += [

en/device-dev/porting/porting-smallchip-prepare-needs.md

-# Before You Start<a name="EN-US_TOPIC_0000001152006279"></a>
+# Before You Start<a name="EN-US_TOPIC_0000001154212510"></a>
 
 This document provides guidance on how to port the Linux and LiteOS Cortex-A kernels on the OpenHarmony  [small system](../quick-start/quickstart-lite-overview.md)  to a development board. It is intended for developers with experience in developing embedded systems. Before following instructions in this document, it is recommended that you familiarize yourself with  [OpenHarmony](../../OpenHarmony-Overview.md), including its technical architecture, directory structure, kernel subsystem, and driver subsystem. The following table lists the development boards that have been adapted to the small system.
 

en/device-dev/porting/porting-smallchip-prepare.md

-# Porting Preparations<a name="EN-US_TOPIC_0000001105401594"></a>
+# Porting Preparations<a name="EN-US_TOPIC_0000001154212514"></a>
 
 -   **[Before You Start](porting-smallchip-prepare-needs.md)**  
 

en/device-dev/porting/porting-thirdparty-cmake.md

-# Porting a Library Built Using CMake<a name="EN-US_TOPIC_0000001063033549"></a>
+# Porting a Library Built Using CMake<a name="EN-US_TOPIC_0000001200172241"></a>
 
 -   [Source Code Acquisition](#section1771132116245)
 -   [Porting Guidelines](#section9737174410328)
@@ -136,10 +136,10 @@ The following steps show how to configure and modify the toolchains for cross-co
     set(CMAKE_LINKER clang)
     set(CMAKE_CXX_LINKER clang++)
     set(CMAKE_C_LINKER clang)
-    set(CMAKE_C_LINK_EXECUTABLE "${CMAKE_C_LINKER}
-    ${MY_LINK_FLAGS} <FLAGS> <LINK_FLAGS> <OBJECTS> -o <TARGET> <LINK_LIBRARIES>")
-    set(CMAKE_CXX_LINK_EXECUTABLE "${CMAKE_CXX_LINKER}
-    ${MY_LINK_FLAGS} <FLAGS> <LINK_FLAGS> <OBJECTS> -o <TARGET> <LINK_LIBRARIES>")
+    set(CMAKE_C_LINK_EXECUTABLE
+        "${CMAKE_C_LINKER} ${MY_LINK_FLAGS} <FLAGS> <LINK_FLAGS> <OBJECTS> -o <TARGET> <LINK_LIBRARIES>")
+    set(CMAKE_CXX_LINK_EXECUTABLE
+        "${CMAKE_CXX_LINKER} ${MY_LINK_FLAGS} <FLAGS> <LINK_FLAGS> <OBJECTS> -o <TARGET> <LINK_LIBRARIES>")
     # Specify the path for searching chained libraries.
     set(CMAKE_SYSROOT ${OHOS_SYSROOT_PATH})
     ```
@@ -154,7 +154,7 @@ The following steps show how to configure and modify the toolchains for cross-co
     make -j
     ```
 
-    **OHOS\_SYSROOT\_PATH**  specifies the absolute path where  **sysroot**  is located. Taking OpenHarmony for example, set  **OHOS\_SYSROOT\_PATH**  to the absolute path of  **openHarmony/prebuilts/lite/sysroot**.
+    **OHOS\_SYSROOT\_PATH**  specifies the absolute path where  **sysroot**  is located. For OpenHarmony, set  **OHOS\_SYSROOT\_PATH**  to the absolute path of the  **out/hispark\__xxx_/ipcamera\_hispark\__xxx_/sysroot**  directory. This directory is generated after full compilation is complete. Therefore, complete full compilation before porting.
 
 3.  <a name="li15717101715249"></a>View the result.
 
@@ -227,7 +227,7 @@ The following steps show how to configure and modify the toolchains for cross-co
 
 1.  Set up the OpenHarmony environment.
 
-    Using Hi3518EV300 as an example, compile the OpenHarmony image and burn it to the development board. For details, see  [Developing the First Example Program Running on Hi3518](../quick-start/quickstart-lite-steps-board3518-running.md).
+    Using Hi3518EV300 as an example, compile the OpenHarmony image and burn it to the development board. For details, see  [Developing the First Example Program Running on Hi3518](../quick-start/quickstart-lite-steps-hi3518-running.md).
 
     The following screen is displayed after a successful login to the OS.
 

en/device-dev/porting/porting-thirdparty-makefile.md

-# Porting a Library Built Using Makefile<a name="EN-US_TOPIC_0000001064218672"></a>
+# Porting a Library Built Using Makefile<a name="EN-US_TOPIC_0000001154372572"></a>
 
 -   [Source Code Acquisition](#section114115321416)
 -   [Cross-Compilation Settings](#section81263255384)
@@ -98,7 +98,7 @@ The following steps show how to configure and modify the toolchains for cross-co
     CC:=clang
     AR:=llvm-ar
     # The --target and --sysroot flags must be specified.
-    CFLAGS:=-Wall -Wextra -Wno-unused-parameter -O2 -g --target=arm-liteos -march=armv7-a --sysroot=$(OHOS_ROOT_PATH)prebuilts/lite/sysroot
+    CFLAGS:=-Wall -Wextra -Wno-unused-parameter -O2 -g --target=arm-liteos -march=armv7-a --sysroot=$(OHOS_SYSROOT_PATH)
     ```
 
     Original configuration:
@@ -117,7 +117,7 @@ The following steps show how to configure and modify the toolchains for cross-co
     make test OHOS_SYSROOT_PATH=...
     ```
 
-    **OHOS\_SYSROOT\_PATH**  specifies the absolute path of the directory where  **sysroot**  is located. Taking OpenHarmony for example, set  **OHOS\_SYSROOT\_PATH**  to the absolute path of  **prebuilts/lite/sysroot/**.
+    **OHOS\_SYSROOT\_PATH**  specifies the absolute path of the directory where  **sysroot**  is located. For OpenHarmony, set  **OHOS\_SYSROOT\_PATH**  to the absolute path of the  **out/hispark\__xxx_/ipcamera\_hispark\__xxx_/sysroot**  directory. This directory is generated after full compilation is complete. Therefore, complete full compilation before porting.
 
 3.  View the result.
 

en/device-dev/porting/porting-thirdparty-overview.md

-# Overview<a name="EN-US_TOPIC_0000001064570046"></a>
+# Overview<a name="EN-US_TOPIC_0000001154212772"></a>
 
 This document provides guidance for OpenHarmony developers to port third-party libraries that use common compiler organization modes, such as CMakeLists and Makefile. It describes how to set a toolchain in different compiler organization modes and how to add the compiling configuration of a library to the OpenHarmony project. Currently, this guide applies only to Hi3516DV300 and Hi3518EV300.
 

en/device-dev/porting/porting.md

@@ -6,4 +6,6 @@
 
 -   **[Small System SoC Porting Guide](porting-smallchip.md)**  
 
+-   **[Standard System Porting Guide](standard-system-porting-guide.md)**  
+
 

en/device-dev/quick-start/Readme-EN.md

 #  Getting Started
 
--   [Mini and Small Systems](quickstart-lite.md)
-    -   [Overview](quickstart-lite-overview.md)
-    -   [Introduction to the Development Boards](quickstart-lite-introduction.md)
-        -   [Hi3861 Development Board](quickstart-lite-introduction-hi3861.md)
-        -   [Hi3516 Development Board](quickstart-lite-introduction-hi3516.md)
-        -   [Hi3518 Development Board](quickstart-lite-introduction-hi3518.md)
-
-    -   [Environment Setup](quickstart-lite-env-setup.md)
-        -   [Overview](quickstart-lite-env-setup-des.md)
-        -   [Windows Development Environment](quickstart-lite-env-setup-win.md)
-        -   [Ubuntu Build Environment](quickstart-lite-env-setup-lin.md)
-        -   [FAQ](quickstart-lite-env-setup-faqs.md)
-
-    -   [How to Develop](quickstart-lite-steps.md)
-        -   [Hi3861](quickstart-lite-steps-board3861.md)
-            -   [Setting Up the Environment](quickstart-lite-steps-board3861-setting.md)
-            -   [WLAN Connection](quickstart-lite-steps-board3861-connection.md)
-            -   [Running a Hello World Program](quickstart-lite-steps-board3861-running.md)
-            -   [FAQs](quickstart-lite-steps-board3861-faqs.md)
-
-        -   [Hi3516](quickstart-lite-steps-board3516.md)
-            -   [Setting Up the Environment](quickstart-lite-steps-board3516-setting.md)
-            -   [Running a Hello OHOS Program](quickstart-lite-steps-board3516-running.md)
-            -   [Developing a Driver](quickstart-lite-steps-board3516-program.md)
-            -   [FAQs](quickstart-lite-steps-board3516-faqs.md)
-
-        -   [Hi3518](quickstart-lite-steps-board3518.md)
-            -   [Setting Up the Environment](quickstart-lite-steps-board3518-setting.md)
-            -   [Running a Hello OHOS Program](quickstart-lite-steps-board3518-running.md)
-            -   [FAQs](quickstart-lite-steps-board3518-faqs.md)
-
--   [Standard System](quickstart-standard.md)
-    -   [Introduction](quickstart-standard-description.md)
-    -   [Setting Up Windows Development Environment](quickstart-standard-windows-environment.md)
-    -   [Setting Up Ubuntu Development Environment in Docker Mode and Building Source Code](quickstart-standard-docker-environment.md)
-    -   [Setting Up Ubuntu Development Environment with Installation Package and Building Source Code](quickstart-standard-package-environment.md)
-    -   [Burning Images](quickstart-standard-burn.md)
-    -   [FAQs](quickstart-standard-faq.md)
\ No newline at end of file
+- [Mini and Small Systems](quickstart-lite.md)
+  - [Overview](quickstart-lite-overview.md)
+  - [Introduction](quickstart-lite-introduction.md)
+    - [Hi3861 Development Board](oem_minitinier_des_3861.md)
+    - [Hi3516 Development Board](oem_minitinier_des_3516.md)
+    - [Hi3518 Development Board](oem_minitinier_des_3518.md)
+  - [Environment Setup](quickstart-lite-env-setup.md)
+    - [Overview](quickstart-lite-env-setup-overview.md)
+    - [Setting Up Windows Development Environment](quickstart-lite-env-setup-windows.md)
+    - [Setting Up Ubuntu Development Environment](quickstart-lite-env-setup-linux.md)
+    - [FAQs](quickstart-lite-env-setup-faqs.md)
+  - [How to Develop](quickstart-lite-steps.md)
+    - [Hi3861](quickstart-lite-steps-hi3861.md)
+      - [Setting Up the Environment](quickstart-lite-steps-hi3861-setting.md)
+      - [Setting Up WLAN Connection](quickstart-lite-steps-hi3861-connection.md)
+      - [Running a Hello World Program](quickstart-lite-steps-hi3861-running.md)
+      - [FAQs](quickstart-lite-steps-hi3861-faqs.md)
+    - [Hi3516](quickstart-lite-steps-hi3516.md)
+      - [Setting Up the Environment](quickstart-lite-steps-hi3516-setting.md)
+      - [Running a Hello OHOS Program](quickstart-lite-steps-hi3516-running.md)
+      - [Developing a Driver](quickstart-lite-steps-hi3516-program.md)
+      - [FAQs](quickstart-lite-steps-hi3516-faqs.md)
+    - [Hi3518](quickstart-lite-steps-hi3518.md)
+      - [Setting Up the Environment](quickstart-lite-steps-hi3518-setting.md)
+      - [Running a Hello OHOS Program](quickstart-lite-steps-hi3518-running.md)
+      - [FAQs](quickstart-lite-steps-hi3518-faqs.md)
+- [Standard System](quickstart-standard.md)
+  - [Introduction](quickstart-standard-overview.md)
+  - [Setting Up Windows Development Environment](quickstart-standard-windows-environment.md)
+  - [Setting Up Ubuntu Development Environment in Docker Mode](quickstart-standard-docker-environment.md)
+  - [Setting Up Ubuntu Development Environment with Installation Package](quickstart-standard-package-environment.md)
+  - [Burning Images](quickstart-standard-burn.md)
+  - [Running an Image](quickstart-standard-running.md)
+  - [FAQs](quickstart-standard-faqs.md)
\ No newline at end of file