libs/rt-thread-official
libs
/
rt-thread-official
mirror of https://github.com/RT-Thread/rt-thread.git
4
0
Fork 0
Code Issues Releases Wiki Activity

Merge remote-tracking branch 'upstream/master'

This commit is contained in:
Bernard Xiong 2015-08-10 08:14:20 +08:00
parent 358837bb89 3292353bc2
commit 4a66474329
11 changed files with 36 additions and 32 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

31
README.md
View File

@ -3,25 +3,28 @@
[![Build Status](https://travis-ci.org/RT-Thread/rt-thread.svg)](https://travis-ci.org/RT-Thread/rt-thread)
[![Gitter](https://badges.gitter.im/Join Chat.svg)](https://gitter.im/RT-Thread/rt-thread?utm_source=badge&utm_medium=badge&utm_campaign=pr-badge&utm_content=badge)
RT-Thread is an open source real-time operating system for embedded devices from China. RT-Thread RTOS is a scalable real-time operating system: a tiny kernel for ARM Cortex-M0, Cortex-M3/4, or a full feature system in ARM Cortex-A8, ARM Cortex-A9 DualCore etc.
RT-Thread is an open source real-time operating system for embedded devices from China. RT-Thread RTOS is a scalable real-time operating system: a tiny kernel for ARM Cortex-M0, Cortex-M3/4/7, or a rich feature system like ARM Cortex-A8, ARM Cortex-A9 DualCore etc.
## Overview ##
RT-Thread RTOS like a traditional real-time operating system. The kernel has real-time multi-task scheduling, semaphore, mutex, mail box, message queue etc. However, it has two different things:
* Device Driver;
* Component.
* Component;
* Application Module
The device driver is more like a driver framework, UART, SPI, USB device/host, EMAC, MTD NAND etc. The developer can easily add low level driver and board configuration, then he/she can use lots of features.
The device driver is more like a driver framework, UART, IIC, SPI, SDIO, USB device/host, EMAC, MTD NAND etc. The developer can easily add low level driver and board configuration, then he/she can use lots of features.
The Component is a software concept upon RT-Thread kernel, for example a shell (finsh shell), virtual file system (FAT, YAFFS, UFFS, ROM/RAM file system etc), TCP/IP protocol stack (lwIP), POSIX interface etc. One component must be a directory under RT-Thread/Components and one component can be descripted by a SConscript file (then be compiled and linked into the system).
The Component is a software concept upon RT-Thread kernel, for example a shell (finsh/msh shell), virtual file system (FAT, YAFFS, UFFS, ROM/RAM file system etc), TCP/IP protocol stack (lwIP), POSIX (thread) interface etc. One component must be a directory under RT-Thread/Components and one component can be descripted by a SConscript file (then be compiled and linked into the system).
The Appliation Module, or User Applicaion (UA) is a dyanmic loaded module, it can be compiled standalone without Kernel. Each UA has its own object container to manage thread/semaphore/kernel object which was created or initialized inside this UA. More information about UA, please visit another [git repo](https://github.com/RT-Thread/rtthread-apps).
## Board Support Package ##
RT-Thread RTOS can support many architectures:
* ARM Cortex-M0
* ARM Cortex-M3/M4
* ARM Cortex-M3/M4/7
* ARM Cortex-R4
* ARM Cortex-A8/A9
* ARM920T/ARM926 etc
@ -37,32 +40,30 @@ As a special exception, including RT-Thread RTOS header files in a file, instant
## Usage ##
RT-Thread RTOS uses [scons](http://www.scons.org) as its building system. Therefore, please install scons and Python 2.7 firstly.
RT-Thread RTOS uses [scons](http://www.scons.org) as building system. Therefore, please install scons and Python 2.7 firstly.
So far, the RT-Thread scons building system support the command line compiling or generate some IDE's project. There are some option varaibles in the scons building script:
In rtconfig.py file:
So far, the RT-Thread scons building system support the command line compile or generate some IDE's project. There are some option varaibles in the scons building script (rtconfig.py):
* ```CROSS_TOOL``` the compiler which you want to use, gcc/keil/iar.
* ```EXEC_PATH``` the path of compiler.
In SConstruct file:
```RTT_ROOT``` This variable is the root directory of RT-Thread RTOS. If you build the porting in the bsp directory, you can use the default value. Also, you can set the root directory in ```RTT_ROOT``` environment variable.
```RTT_ROOT``` This variable is the root directory of RT-Thread RTOS. If you build the porting in the bsp directory, you can use the default setting. Also, you can set the root directory in ```RTT_ROOT``` environment variable and not modify SConstruct files.
When you set these variables correctly, you can use command:
scons
under BSP directory to simplely compile RT-Thread RTOS.
If you want to generate the IDE's project file, firstly you should change the ```RTT_CC``` in the rtconfig.py file. Then use command:
under BSP directory to simplely compile RT-Thread RTOS.
scons --target=mdk/mdk4/iar/cb -s
If you want to generate the IDE's project file, you can use command:
s
scons --target=mdk/mdk4/mdk5/iar/cb -s
to generate the project file.
NOTE: RT-Thread scons building system will tailor the system according to your rtconfig.h configuration header file. For example, if you disable the lwIP in the rtconfig.h by commenting the ```#define RT_USING_LWIP```, the generated project file has no lwIP related files.
NOTE: RT-Thread scons building system will tailor the system according to your rtconfig.h configuration header file. For example, if you disable the lwIP in the rtconfig.h by commenting the ```#define RT_USING_LWIP```, the generated project file should have no lwIP related files.
## Contribution ##

4
bsp/lm3s8962/applications/startup.c
View File

@ -142,10 +142,8 @@ void rtthread_startup(void)
int main(void)
{
rt_uint32_t level UNUSED;
/* disable interrupt first */
level = rt_hw_interrupt_disable();
rt_hw_interrupt_disable();
rtthread_startup();
return 0;

2
bsp/lpc2148/drivers/serial.c
View File

@ -66,7 +66,7 @@ void rt_hw_serial_init(void);
void rt_hw_uart_isr(struct rt_lpcserial* lpc_serial)
{
UNUSED rt_uint32_t iir;
RT_UNUSED rt_uint32_t iir;
RT_ASSERT(lpc_serial != RT_NULL)

2
bsp/lpc2478/drivers/serial.c
View File

@ -66,7 +66,7 @@ void rt_hw_serial_init(void);
void rt_hw_uart_isr(int irqno, void *param)
{
UNUSED rt_uint32_t iir;
RT_UNUSED rt_uint32_t iir;
struct rt_lpcserial* lpc_serial = (struct rt_lpcserial*)param;
RT_ASSERT(lpc_serial != RT_NULL)

4
bsp/mb9bf500r/startup.c
View File

@ -90,10 +90,8 @@ void rtthread_startup(void)
int main(void)
{
rt_uint32_t UNUSED level;
/* disable interrupt first */
level = rt_hw_interrupt_disable();
rt_hw_interrupt_disable();
/* init system setting */
SystemInit();

2
bsp/mini4020/drivers/board.c
View File

@ -51,7 +51,7 @@ void rt_serial_handler(int vector, void *param)
{
//rt_kprintf("in rt_serial_handler\n");
rt_int32_t stat = *(RP)UART0_IIR ;
UNUSED char c;
RT_UNUSED char c;
/*Received data*/
if (((stat & 0x0E) >> 1) == 0x02)

2
bsp/mini4020/drivers/sdcard.c
View File

@ -271,7 +271,7 @@ static rt_err_t sd_readblock(rt_uint32_t address, rt_uint8_t* buf)
U32 complete,i;
rt_uint8_t temp;
rt_err_t err;
UNUSED rt_uint32_t discard;
RT_UNUSED rt_uint32_t discard;
#ifdef USE_TIMEOUT
rt_uint32_t to = 10;
#endif

4
bsp/nios_ii/startup.c
View File

@ -85,10 +85,8 @@ void rtthread_startup(void)
int main(void)
{
rt_uint32_t UNUSED level;
/* disable interrupt first */
level = rt_hw_interrupt_disable();
rt_hw_interrupt_disable();
/* startup RT-Thread RTOS */
rtthread_startup();

8
bsp/stm32f0x/rtconfig.h
View File

@ -83,11 +83,13 @@
#define FINSH_THREAD_STACK_SIZE 1024
#define FINSH_HISTORY_LINES 1
/* Using symbol table */
#define FINSH_USING_SYMTAB
#define FINSH_USING_DESCRIPTION
//#define FINSH_USING_SYMTAB
//#define FINSH_USING_DESCRIPTION
#define FINSH_USING_MSH
#define FINSH_USING_MSH_ONLY
/* SECTION: libc management */
#define RT_USING_LIBC
// #define RT_USING_LIBC
/* SECTION: device filesystem */
/* #define RT_USING_DFS */

6
components/drivers/include/drivers/sdio.h
View File

@ -181,6 +181,12 @@ rt_int32_t sdio_io_rw_extended(struct rt_mmcsd_card *card,
rt_uint8_t *buf,
rt_uint32_t blocks,
rt_uint32_t blksize);
rt_int32_t sdio_io_rw_extended_block(struct rt_sdio_function *func,
rt_int32_t rw,
rt_uint32_t addr,
rt_int32_t op_code,
rt_uint8_t *buf,
rt_uint32_t len);
rt_uint8_t sdio_io_readb(struct rt_sdio_function *func,
rt_uint32_t reg,
rt_int32_t *err);

3
components/drivers/sdio/sdio.c
View File

@ -244,7 +244,7 @@ rt_inline rt_uint32_t sdio_max_block_size(struct rt_sdio_function *func)
return MIN(size, 512u); /* maximum size for byte mode */
}
static rt_int32_t sdio_io_rw_extended_block(struct rt_sdio_function *func,
rt_int32_t sdio_io_rw_extended_block(struct rt_sdio_function *func,
rt_int32_t rw,
rt_uint32_t addr,
rt_int32_t op_code,
@ -1325,6 +1325,7 @@ rt_int32_t sdio_register_driver(struct rt_sdio_driver *driver)
return -RT_ENOMEM;
}
sd->drv = driver;
rt_list_insert_after(&sdio_drivers, &sd->list);
if (!rt_list_isempty(&sdio_cards))