Driver Subsystem

• Overview
• Architecture
• Directory Structure
• Use
• Installation
• Repositories Involved

Overview

The OpenHarmony driver subsystem is constructed using the C object-oriented programming (OOP). It provides a unified driver platform through platform decoupling, kernel decoupling, and compatible kernels. This unified driver architecture platform is designed to provide a more precise and efficient development environment, where you develop a driver that can be deployed on different systems supporting HDF.

The OpenHarmony driver subsystem provides the following key features and capabilities to shorten the driver development period and make third-party device driver integration much easier:

• Flexible framework capabilities

  Based on the traditional driver framework, the OpenHarmony driver subsystem builds flexible framework capabilities to deploy terminal products with the capacity ranging from hundreds KB to hundreds MB of memory.

• Standardized driver APIs

  The OpenHarmony driver subsystem provides you with abundant and stable driver APIs, which are compatible with those of future-proof smartphones, tablets, smart TVs.

• Component-based driver models

  The OpenHarmony driver subsystem supports component-based driver models. It provides more refined driver management to dismantle components, enabling you to focus on the interaction between the hardware and driver.

  The subsystem also presets some template-based driver model components, such as the network device models.

• Normalized configuration GUIs

  The OpenHarmony driver subsystem provides a unified configuration GUI and a cross-platform tool for configuration conversion and generation to implement seamless switchover across platforms.

You can use DevEco to manage driver projects, generate driver templates, and manage settings to make the development of OpenHarmony drivers easier.

Architecture

The OpenHarmony driver framework adopts the primary/secondary mode and is developed based on the framework, model, competence library, and tool.

Figure 1 Driver subsystem architecture

• Driver framework stored in the framework/core directory

  • Loads and starts drivers.
  • Deploys and expands the driver framework flexibly through the object manager.

• Driver model stored in the framework/model directory

  • Provides model-based driving capabilities, such as network device models.

• Driver capability library stored in the framework/ability directory

  • Provides basic driver models, such as the I/O communication model.

• Driver tools stored in the framework/tools directory

  • Provides tools for HDI API conversion, and driver configuration and driver compilation.

• Driver APIs stored in the lite/hdi directory

  • Provides standardized driver APIs.

• Support stored in the framework/support directory

  • Provides platform driver APIs and system APIs with normalized abstraction capabilities.

Directory Structure

drivers
├── adapter               # Adaptation code for differentiated platforms
├── framework             # Core code of the HDF
└── peripheral            # Peripheral driver code 

Use

Figure 2 Interaction between the driver and framework

Driver loading is mostly done by the driver framework, and you only need to register and configure required APIs. The driver framework will load and initialize the driver based on the parsing content.

Driver development based on the HDF consists of the following three parts:

1. Driver: Develop the functions.

2. Information configuration: Present the loading information of the driver.

3. Resource configuration: Configure the hardware information of the driver.

The driver mainly aims to develop the functions.

The first part that catches your eyes is the driver entry, which is described through DriverEntry.

Three APIs are available, namely bind, init, and release.

struct HdfDriverEntry g_deviceSample = {
    .moduleVersion = 1,
    .moduleName = "sample_driver", 
    .Bind = SampleDriverBind,
    .Init = SampleDriverInit,
    .Release = SampleDriverRelease,
};

Bind: This API is used to bind driver devices and its functions.

int32_t SampleDriverBind(struct HdfDeviceObject *deviceObject)
{
    // TODO: Bind device service to device object.
    // And you can also initialize device resources here.
    return HDF_SUCCESS;
}

Init: When devices are successfully bound, the framework calls Init to initialize the driver. After initialization is complete, the driver framework will determine whether to create external service interfaces based on the configuration file. If the driver fails to be initialized, the driver framework will automatically release the created device interface.

int32_t SampleDriverInit(struct HdfDeviceObject *deviceObject)
{
    // TODO: Init hardware or other resources here.
    return HDF_SUCCESS;
}

Release: When you need to uninstall a driver, the driver framework calls this function to release the driver resources. Then, other internal resources will be released.

void SampleDriverRelease(struct HdfDeviceObject *deviceObject)
{
    // Release all resources.
    return;
}

Installation

The OpenHarmony driver is mainly deployed in the kernel space using the static link mode. It is compiled and packed with the kernel subsystem and system image.

Figure 3 Driver installation

Repositories Involved

Driver subsystem

drivers_framework

drivers_adapter

drivers_adapter_khdf_linux

drivers_peripheral