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zhushengle 230a2f348f fixed `9b5739a` from https://gitee.com/zhushengle/kernel_liteos_m/pulls/298 feat: 低功耗支持冻结线程等需求 1.支持低功耗时冻结线程 2.支持延时锁 3.低功耗与idle分离 4.支持对接电源管组件的低功耗接口 LOS_PmReadLock --- 常阻塞，低功耗线程阻塞于该接口，当系统无任何模块持锁时会唤醒低功耗线程, 触发低功耗流程 LOS_PmSuspend --- 进入低功耗流程 Close #I49FJF Signed-off-by: zhushengle <zhushengle@huawei.com> Change-Id: I009255cfa1852b109dd8bfaf9c779e976660d621		2021-09-14 12:31:10 +00:00
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README.md

LiteOS Cortex-M

Introduction
Directory Structure
Constraints
Usage
Repositories Involved

Introduction

The OpenHarmony LiteOS Cortex-M is the kernel designed for the lightweight operating system OS for the Internet of Things IoT field. It features small size, low power consumption, and high performance. In addition, it has a simple code structure, including the minimum kernel function set, kernel abstraction layer, optional components, and project directory, and is divided into the hardware-related and hardware-irrelevant layers. The hardware-related layers provide unified hardware abstraction layer HAL interfaces to improve hardware adaptability. The combination and classification of different compilation toolchains and chip architectures meet the requirements of the Artificial Intelligence of Things AIoT field for rich hardware and compilation toolchains. Figure1 shows the architecture of the OpenHarmony LiteOS Cortex-M kernel.

Figure 1 Architecture of OpenHarmony the LiteOS Cortex-M kernel

Directory Structure

The directory structure is listed as below, for the detailed directories, please refer to arch_spec.md.

/kernel/liteos_m
├── components           # Optional components
│   ├── backtrace        # Backtrace support
│   ├── cppsupport       # C++ support
│   ├── cpup             # CPU possession (CPUP)
│   ├── dynlink          # Dynamic loader & linker
│   ├── exchook          # Exception hook
│   ├── fs               # File system
│   └── net              # Network support
├── kal                  # Kernel abstraction layer
│   ├── cmsis            # CMSIS-compliant API support
│   └── posix            # POSIX API support
├── kernel               # Minimum function set support
│   ├── arch             # Code of the kernel instruction architecture layer
│   │   ├── arm          # Code of the ARM32 architecture
│   │   └── include      # APIs exposed externally
│   ├── include          # APIs exposed externally
│   └── src              # Source code of the minimum function set of the kernel
├── targets              # Board-level projects
├── utils                # Common code

Constraints

Programming languages: C and C++

Currently applicable architectures: Cortex-M3, Cortex-M4, Cortex-M7, and RISC-V

Usage

LiteOS Cortex-M provides projects for three chip architectures, which are located in the targets directory. The methods of compiling and using these projects are as follows:

Cortex-M3:

The kernel/liteos_m/targets/cortex-m3_stm32f103_simulator_keil directory is the Keil project directory created based on the STM32F103 chip architecture. You can download and install Keil development tools from the Internet. To compile the Cortex-M3 project, go to the cortex-m3_stm32f103_simulator_keil/project directory and double-click the los_demo.uvproj file to open the desired project. After the compilation is successful, burn the file to the corresponding board using JLINK or STM32 ST-LINK Utility.

Cortex-M4:

The kernel/liteos_m/targets/cortex-m4_stm32f429ig_fire-challenger_iar directory is the IAR project directory created based on the STM32F429IG chip architecture. You can download and install IAR development tools from the Internet. To compile the Cortex-M4 project, go to the cortex-m4_stm32f429ig_fire-challenger_iar/project directory and double-click the los_demo.eww file to open the desired project. After the compilation is successful, burn the file to the corresponding board using JLINK or STM32 ST-LINK Utility.

Cortex-M7:

The kernel/liteos_m/targets/cortex-m7_nucleo_f767zi_gcc directory is the Makefile project directory created based on the STM32F767ZI chip architecture. The compilation commands are as follows:

cd kernel/liteos_m/targets/cortex-m7_nucleo_f767zi_gcc
make clean; make

After the compilation is successful, the executable file NUCLEO-F767.hex is generated in the cortex-m7_nucleo_f767zi_gcc/build directory. Burn the file to the corresponding board using STM32 ST-LINK Utility.

Repositories Involved

Kernel subsystem

kernel_liteos_m