# Driver Development - [Driver Model](#section157425168112) - [How to Develop](#section1969312275533) ## Driver Model The HDF is designed based on the component-based driver model. This model allows refined driver management and normalizes driver development and deployment. Device drivers of the same type are placed in the same host. You can develop and deploy the drivers separately. One driver can have multiple nodes. [Figure 1](#fig3580184214210) shows the HDF driver model. **Figure 1** HDF driver model ![](figures/hdf-driver-model.png "hdf-driver-model") ## How to Develop Driver development based on the HDF involves driver implementation and driver configuration. The development procedure is as follows: 1. Implement a driver. To implement a driver, compile driver service code and register a driver entry. - Driver service code ``` #include "hdf_device_desc.h" // Header file that describes the APIs provided by the HDF to the driver. #include "hdf_log.h" // Header file that describes the log APIs provided by the HDF. #define HDF_LOG_TAG "sample_driver" // Tag contained in logs. If no tag is not specified, the default HDF_TAG is used. // The driver service interface must be bound to the HDF for you to use the service capability. int32_t HdfSampleDriverBind(struct HdfDeviceObject *deviceObject) { HDF_LOGD("Sample driver bind success"); return 0; } // Initialize the driver service. int32_t HdfSampleDriverInit(struct HdfDeviceObject *deviceObject) { HDF_LOGD("Sample driver Init success"); return 0; } // Release the driver resources. void HdfSampleDriverRelease(struct HdfDeviceObject *deviceObject) { HDF_LOGD("Sample driver release success"); return; } ``` - Registering the driver entry with the HDF ``` // Define the object of the driver entry. The object must be a global variable of the HdfDriverEntry type (defined in hdf_device_desc.h). struct HdfDriverEntry g_sampleDriverEntry = { .moduleVersion = 1, .moduleName = "sample_driver", .Bind = HdfSampleDriverBind, .Init = HdfSampleDriverInit, .Release = HdfSampleDriverRelease, }; // Call HDF_INIT to register the driver entry with the HDF framework. When loading the driver, call the Bind function and then the Init function. If the Init function fails to be called, the HDF will call Release to release the driver resource and exit. HDF_INIT(g_sampleDriverEntry); ``` 2. Build the driver. - LiteOS Modify **makefile** and **BUILD.gn**: * makefile: Use the **makefile** template provided by the HDF to compile the driver code. ``` include $(LITEOSTOPDIR)/../../drivers/adapter/khdf/liteos/lite.mk # Import the content predefined by the HDF. This operation is mandatory. MODULE_NAME := # File to be generated. LOCAL_INCLUDE: = # Header file directory of the driver. LOCAL_SRCS : = # Source code file of the driver. LOCAL_CFLAGS : = # Custom compilation options. include $(HDF_DRIVER) # Import the makefile template to complete the compilation. ``` Add the path of the generated file to **hdf_lite.mk** in the **drivers/adapter/khdf/liteos** directory to link the file to the kernel image. The following is an example: ``` LITEOS_BASELIB += -lxxx # Static library generated by the link. LIB_SUBDIRS += # Directory in which the driver code makefile is located. ``` * BUILD.gn: Add **BUILD.gn**. The content of **BUILD.gn** is as follows: ``` import("//build/lite/config/component/lite_component.gni") import("//drivers/adapter/khdf/liteos/hdf.gni") module_switch = defined(LOSCFG_DRIVERS_HDF_xxx) module_name = "xxx" hdf_driver(module_name) { sources = [ "xxx/xxx/xxx.c", # Source code file of the driver ] public_configs = [ ":public" ] # Configuration applied to dependencies } config("public") {# Configuration of the dependencies include_dirs = [ "xxx/xxx/xxx", # Directory of the dependency header file. ] } ``` Add the directory where the **BUILD.gn** file of the driver is located to **/drivers/adapter/khdf/liteos/BUILD.gn**. ``` group("liteos") { public_deps = [ ":$module_name" ] deps = [ "xxx/xxx", # Directory where the BUILD.gn of the driver is located. It is a relative path to /drivers/adapter/khdf/liteos. ] } ``` - Linux To define the driver control macro, add the **Kconfig** file to the driver directory **xxx** and add the path of the **Kconfig** file to **drivers/adapter/khdf/linux/Kconfig**. ``` source "drivers/hdf/khdf/xxx/Kconfig" # Kernel directory to which the HDF module is soft linked. ``` Add the driver directory to **drivers/adapter/khdf/linux/Makefile**. ``` obj-$(CONFIG_DRIVERS_HDF) += xxx/ ``` Add a **Makefile** to the driver directory **xxx** and add code compiling rules of the driver to the **Makefile** file. ``` obj-y += xxx.o ``` 3. Configure the driver. HDF Configuration Source (HCS) is the source code that describes the configuration of the HDF. For details about the HCS, see [Driver Configuration Management](driver-hdf-manage.md). The driver configuration consists of the driver device description defined by the HDF and private driver configuration information. - (Mandatory) Driver device description The information required for the HDF to load drivers comes from the driver device description defined by the HDF. Therefore, the device description must be added to the configuration file **device_info.hcs** defined by the HDF for drivers developed based on the HDF.The following is an example: ``` root { device_info { match_attr = "hdf_manager"; template host { // Host template. If the node (for example, sample_host) that inherits the template uses default values in the template, the values of the node fields can be omitted. hostName = ""; priority = 100; template device { template deviceNode { policy = 0; priority = 100; preload = 0; permission = 0664; moduleName = ""; serviceName = ""; deviceMatchAttr = ""; } } } sample_host :: host{ hostName = "host0"; // Host name. The host node is used to store a certain type of drivers. priority = 100; // Host startup priority (0-200). A larger value indicates a lower priority. The default value 100 is recommended. If the priorities are the same, the host loading sequence is random. device_sample :: device { // Device node of sample device0 :: deviceNode { // DeviceNode of the sample driver policy = 1; // Driver service release policy. For details, see section Driver Service Management. priority = 100; // Driver startup priority (0-200). A larger value indicates a lower priority. The default value 100 is recommended. If the priorities are the same, the device loading sequence is random. preload = 0; // On-demand loading of the driver. For details, see "NOTE" at the end of this section. permission = 0664; // Permission for the driver to create device nodes. moduleName = "sample_driver"; // Driver name. The value of this field must be the same as the value of moduleName in the driver entry structure. serviceName = "sample_service"; // Name of the service released by the driver. The name must be unique. deviceMatchAttr = "sample_config"; // Keyword matching the private data of the driver. The value must be the same as that of match_attr in the private data configuration table of the driver. } } } } } ``` - \(Optional\) Private configuration information of the driver If the driver has private configurations, you can add a driver configuration file to fill in the default configuration information of the driver. When loading the driver, the HDF obtains the information and saves it in the **property** of **HdfDeviceObject**, and transfers it to the driver using **Bind** and **Init** \(see [1](#li35182436435)\). The following is an example of the driver configuration information: ``` root { SampleDriverConfig { sample_version = 1; sample_bus = "I2C_0"; match_attr = "sample_config"; // The value of this field must be the same as that of deviceMatchAttr in device_info.hcs. } } ``` After the configuration information is defined, you need to add the configuration file to the board-level configuration entry file **hdf.hcs**. \(You can use the DevEco to perform on-click configuration. For details, see the description about the driver development suite.\) The following is an example: ``` #include "device_info/device_info.hcs" #include "sample/sample_config.hcs" ``` >![](../public_sys-resources/icon-note.gif) **NOTE:** >On-demand loading and sequential loading are supported. The detailed usage is as follows: >- On-demand loading > ``` > typedef enum { > DEVICE_PRELOAD_ENABLE = 0, > DEVICE_PRELOAD_ENABLE_STEP2, > DEVICE_PRELOAD_DISABLE, > DEVICE_PRELOAD_INVALID > } DevicePreload; > ``` > If the **preload** field in the configuration file is set to **0** (DEVICE\_PRELOAD\_ENABLE), the driver is loaded by default during the system boot process. If **preload** is set to **1** (DEVICE\_PRELOAD\_ENABLE\_STEP2), the driver is loaded after a quick start is complete if the system supports quick start. If the system does not support quick start, the value **1** has the same meaning as DEVICE\_PRELOAD\_ENABLE. If **preload** is set to **2** (DEVICE\_PRELOAD\_DISABLE), the driver is dynamically loaded instead of being loaded during the system boot process. When a user-mode process requests the driver service (for details, see [Driver Message Mechanism Management](driver-hdf-news.md)), the HDF attempts to dynamically load the driver if the driver service does not exist. >- Sequential loading \(drivers must be loaded by default\) > In the configuration file, the **priority** field \(the value is an integer ranging from 0 to 200\) indicates the priority of the host and driver. For drivers in different hosts, a smaller host priority value indicates a higher driver loading priority; for drivers in the same host, a smaller driver priority value indicates a higher driver loading priority.