Go to file

vcbchang e7c4b1963a test: 修复mqueue_unittest全量用例ItPosixQueue075与ItPosixQueue097,冒烟用例 ItPosixQueue053用例存在偶尔无法通过的问题【背景】mqueue_unittest用例ItPosixQueue075、ItPosixQueue053 与ItPosixQueue097用例存在偶尔无法通过的问题，现在将其修复【修改方案】ItPosixQueue075中原来是通过延时来实现线程同步，现在更改为静态全局变量实现； ItPosixQueue097中的关于g_testCount利用延时来置标志位，实现线程同步。这里通过延时来期望线程调度，写的不合理，这里更改为等待标志位来实现线程同步。 re #I3Z9H9 Signed-off-by: vcbchang <vcbchang@qq.com> Change-Id: Ib1bb945a5393cb03f4d92e4332e20acd82eb1845		2021-07-13 11:56:50 +08:00
.gitee	add issue and pr template	2021-04-07 14:49:32 +08:00
apps	chore: make liteos_a can be built alone	2021-06-30 18:44:46 +08:00
arch	feat: add blackbox for liteos_a	2021-07-06 07:49:59 +08:00
bsd	fix: remove redundant headfile	2021-06-19 17:32:47 +08:00
compat/posix	refactor: 对LiteOS_a内核中menuconfig开关的宏使用#ifdef/#ifndef做预编译处理	2021-07-01 09:08:18 +08:00
drivers	fix: 设置qemu默认userfs大小/修改qemu驱动目录	2021-06-26 15:38:19 +08:00
figures	update openharmony 1.0.1	2021-03-11 18:43:57 +08:00
fs	!384 对内核中menuconfig开关的宏使用#ifdef/#ifndef来做预编译判断	2021-07-01 07:11:13 +00:00
kernel	feat: add blackbox for liteos_a	2021-07-06 07:49:59 +08:00
lib	fix: 修复内核c库的makefile中被优化函数替换的高频函数依然参与了编译的问题	2021-06-28 17:34:08 +08:00
net	!384 对内核中menuconfig开关的宏使用#ifdef/#ifndef来做预编译判断	2021-07-01 07:11:13 +00:00
platform	refactor: 对LiteOS_a内核中menuconfig开关的宏使用#ifdef/#ifndef做预编译处理	2021-07-01 09:08:18 +08:00
security	remove __cplusplus guards in .c files	2021-04-19 18:28:25 +08:00
shell	refactor: Refactored the kernel boot process and added a init framework	2021-05-20 16:45:43 +08:00
syscall	refactor: 对LiteOS_a内核中menuconfig开关的宏使用#ifdef/#ifndef做预编译处理	2021-07-01 09:08:18 +08:00
testsuites	test: 修复mqueue_unittest全量用例ItPosixQueue075与ItPosixQueue097,冒烟用例 ItPosixQueue053用例存在偶尔无法通过的问题	2021-07-13 11:56:50 +08:00
tools	!401 【DFX子系统】【BBoxDetector】LiteOS_A死机重启维测框架	2021-07-06 08:15:48 +00:00
.gitignore	fix: Show conflicting files for git apply or patch -p command	2021-04-22 16:44:46 +08:00
BUILD.gn	chore: pass sysroot and arch related cflags by BUILD.gn	2021-06-28 16:31:02 +08:00
Kconfig	feat: add blackbox for liteos_a	2021-07-06 07:49:59 +08:00
LICENSE	update openharmony 1.0.1	2021-03-11 18:43:57 +08:00
Makefile	chore: make liteos_a can be built alone	2021-06-30 18:44:46 +08:00
README.md	TicketNo:DTS2021012805GXU8P0H00	2021-03-16 16:54:09 +08:00
README_zh-HK.md	fix(doc): 修复README_zh-HK.md的链接错误	2021-06-25 14:13:32 +08:00
README_zh.md	README_zh.md: update the correct links	2021-06-03 09:24:50 +08:00
TODOList.md	update TODOList.md.	2021-05-21 15:01:20 +08:00
build.sh	chore: pass sysroot and arch related cflags by BUILD.gn	2021-06-28 16:31:02 +08:00
config.mk	remove __cplusplus guards in .c files	2021-04-19 18:28:25 +08:00
kernel_test.sources	remove __cplusplus guards in .c files	2021-04-19 18:28:25 +08:00

README.md

LiteOS Cortex-A

Introduction
Directory Structure
Constraints
Usage
Repositories Involved

Introduction

The OpenHarmony LiteOS Cortex-A is a new-generation kernel developed based on the Huawei LiteOS kernel. Huawei LiteOS is a lightweight operating system OS built for the Internet of Things IoT field. With the rapid development of the IoT industry, OpenHarmony LiteOS Cortex-A brings small-sized, low-power, and high-performance experience and builds a unified and open ecosystem for developers. In addition, it provides rich kernel mechanisms, more comprehensive Portable Operating System Interface POSIX, and a unified driver framework, Hardware Driver Foundation HDF, which offers unified access for device developers and friendly development experience for application developers. Figure 1 shows the architecture of the OpenHarmony LiteOS Cortex-A kernel.

Figure 1 Architecture of the OpenHarmony LiteOS Cortex-A kernel

Directory Structure

/kernel/liteos_a
├── apps                   # User-space init and shell application programs
├── arch                   # System architecture, such as ARM
│   └── arm                # Code for ARM architecture
├── bsd                    # Code of the driver and adaptation layer module related to the FreeBSD, such as the USB module
├── compat                 # Kernel API compatibility
│   └── posix              # POSIX APIs
├── drivers                # Kernel drivers
│   └── char               # Character device
│       ├── mem            # Driver for accessing physical input/output (I/O) devices
│       ├── quickstart     # APIs for quick start of the system
│       ├── random         # Driver for random number generators
│       └── video          # Framework of the framebuffer driver
├── fs                     # File system module, which mainly derives from the NuttX open-source project
│   ├── fat                # FAT file system
│   ├── jffs2              # JFFS2 file system
│   ├── include            # Header files exposed externally
│   ├── nfs                # NFS file system
│   ├── proc               # proc file system
│   ├── ramfs              # RAMFS file system
│   └── vfs                # VFS layer
├── kernel                 # Kernel modules including the process, memory, and IPC modules
│   ├── base               # Basic kernel modules including the scheduling and memory modules
│   ├── common             # Common components used by the kernel
│   ├── extended           # Extended kernel modules including the dynamic loading, vDSO, and LiteIPC modules
│   ├── include            # Header files exposed externally
│   └── user               # Init process loading
├── lib                    # Kernel library
├── net                    # Network module, which mainly derives from the lwIP open-source project
├── platform               # Code for supporting different systems on a chip (SOCs), such as Hi3516D V300
│   ├── hw                 # Logic code related to clocks and interrupts
│   ├── include            # Header files exposed externally
│   └── uart               # Logic code related to the serial port
├── platform               # Code for supporting different systems on a chip (SOCs), such as Hi3516D V300
├── security               # Code related to security features, including process permission management and virtual ID mapping management
├── syscall                # System calling
└── tools                  # Building tools as well as related configuration and code

Constraints

Programming languages: C and C++
Applicable development boards: Hi3518E V300 and Hi3516D V300
Hi3518E V300 uses the JFFS2 file system by default, and Hi3516D V300 uses the FAT file system by default.

Usage

OpenHarmony LiteOS Cortex-A supports the Hi3518E V300 and Hi3516D V300. You can develop and run your applications based on both development boards.

Preparations

You need to set up the compilation environment on Linux.

For Hi3518E V300, see Setting Up the Hi3518 Development Environment.
For Hi3516D V300, see Setting Up the Hi3516 Development Environment.

Source Code Acquisition

Download and decompress a set of source code on a Linux server to acquire the source code. For more acquisition methods, see Source Code Acquisition.

Compilation and Building

For details about how to develop the first application, see:

Repositories Involved

Kernel subsystem

drivers_liteos

kernel_liteos_a