|
/*
* 程序清单:信号量实现生产者消费者间的互斥
*
* 在这个程序中,会创建两个线程,一个是生成者线程worker一个是消费者线程thread
*
* 在数据信息生产、消费的过程中, worker负责把数据将写入到环形buffer中,而thread
* 则从环形buffer中读出。
*/
#include <rtthread.h>
//#include "tc_comm.h"
#define THREAD_STACK_SIZE 512
#define THREAD_PRIORITY 20
#define THREAD_TIMESLICE 20
/* 一个环形buffer的实现 */
struct rb
{
rt_uint16_t read_index, write_index;
rt_uint8_t *buffer_ptr; /*缓冲区数据指针*/
rt_uint16_t buffer_size; /*缓冲区大小*/
};
/* 指向信号量控制块的指针 */
static rt_sem_t sem = RT_NULL;
/* 指向线程控制块的指针 */
static rt_thread_t tid = RT_NULL, worker = RT_NULL;
/* 环形buffer的内存块(用数组体现出来) */
#define BUFFER_SIZE 256
#define BUFFER_ITEM 32
static rt_uint8_t working_buffer[BUFFER_SIZE]; /*使用的缓冲区*/
struct rb working_rb;
/* 初始化环形buffer, size指的是buffer的大小。注:这里并没对数据地址对齐做处理 */
static void rb_init( struct rb* rb, rt_uint8_t *pool, rt_uint16_t size )
{
RT_ASSERT( rb != RT_NULL );
/* 对读写指针清零*/
rb->read_index = rb->write_index = 0;
/* 设置环形buffer的内存数据块 */
rb->buffer_ptr = pool;
rb->buffer_size = size;
}
/* 向环形buffer中写入数据 */
static rt_bool_t rb_put( struct rb* rb, const rt_uint8_t *ptr, rt_uint16_t length )
{
rt_size_t size;
/* 判断是否有足够的剩余空间 */
if ( rb->read_index > rb->write_index )
size = rb->read_index - rb->write_index;
else
size = rb->buffer_size - rb->write_index + rb->read_index;
/* 没有多余的空间 */
if ( size < length ) return RT_FALSE;
if ( rb->read_index > rb->write_index )
{
/* read index - write index 即为总的空余空间 */
memcpy( &rb->buffer_ptr[rb->write_index], ptr, length );
rb->write_index += length;
}
else
{
if ( rb->buffer_size - rb->write_index > length )
{
/* write index 后面剩余的空间有足够的长度 */
memcpy( &rb->buffer_ptr[rb->write_index], ptr, length );
rb->write_index += length;
}
else
{
/*
* write index 后面剩余的空间不存在足够的长度,需要把部分数据复制到
* 前面的剩余空间中
*/
memcpy( &rb->buffer_ptr[rb->write_index], ptr,
rb->buffer_size - rb->write_index );
memcpy( &rb->buffer_ptr[0], &ptr[rb->buffer_size - rb->write_index],
length - ( rb->buffer_size - rb->write_index ) );
rb->write_index = length - ( rb->buffer_size - rb->write_index );
}
}
return RT_TRUE;
}
/* 从环形buffer中读出数据 */
static rt_bool_t rb_get( struct rb* rb, rt_uint8_t *ptr, rt_uint16_t length )
{
rt_size_t size;
/* 判断是否有足够的数据 */
if ( rb->read_index > rb->write_index )
size = rb->buffer_size - rb->read_index + rb->write_index;
else
size = rb->write_index - rb->read_index;
/* 没有足够的数据 */
if ( size < length ) return RT_FALSE;
if ( rb->read_index > rb->write_index )
{
if ( rb->buffer_size - rb->read_index > length )
{
/* read index的数据足够多,直接复制 */
memcpy( ptr, &rb->buffer_ptr[rb->read_index], length );
rb->read_index += length;
}
else
{
/* read index的数据不够,需要分段复制 */
memcpy( ptr, &rb->buffer_ptr[rb->read_index],
rb->buffer_size - rb->read_index );
memcpy( &ptr[rb->buffer_size - rb->read_index], &rb->buffer_ptr[0],
length - rb->buffer_size + rb->read_index );
rb->read_index = length - rb->buffer_size + rb->read_index;
}
}
else
{
/*
* read index要比write index小,总的数据量够(前面已经有总数据量的判
* 断),直接复制出数据。
*/
memcpy( ptr, &rb->buffer_ptr[rb->read_index], length );
rb->read_index += length;
}
return RT_TRUE;
}
/* 生产者线程入口 */
static void thread_entry( void* parameter )
{
rt_bool_t result;
rt_uint8_t data_buffer[BUFFER_ITEM];
while ( 1 )
{
/* 持有信号量 */
rt_kprintf( "生产者线程,持有信号量\r\n");
rt_sem_take( sem, RT_WAITING_FOREVER );
/* 从环buffer中获得数据 */
result = rb_get( &working_rb, &data_buffer[0], BUFFER_ITEM/5 );
/* 释放信号量 */
rt_kprintf( "生产者线程,释放信号量\r\n");
rt_sem_release( sem );
if ( result == RT_TRUE )
{
/* 获取数据成功,打印数据 */
rt_kprintf( "获取数据成功,打印数据\r\n");
rt_kprintf( "%s\r\n", data_buffer );
}
/* 做一个5 OS Tick的休眠 */
rt_thread_delay( 100 );
}
}
/*消费者线程入口 */
static void worker_entry( void* parameter )
{
rt_bool_t result;
rt_uint32_t index, setchar;
rt_uint8_t data_buffer[BUFFER_ITEM];
setchar = 0x21;
while ( 1 )
{
/* 构造数据 */
for( index = 0; index < BUFFER_ITEM; index++ )
{
data_buffer[index] = setchar;
if ( ++setchar == 0x7f )
setchar = 0x21;
}
/* 持有信号量 */
rt_kprintf( "消费者线程 持有信号量\r\n");
rt_sem_take( sem, RT_WAITING_FOREVER );
/* 把数据放到环形buffer中 */
rt_kprintf( "把数据放到环形buffer中\r\n");
result = rb_put( &working_rb, &data_buffer[0], BUFFER_ITEM );
/* 释放信号量 */
rt_kprintf( "消费者线程 释放信号量\r\n");
rt_sem_release( sem );
/* 放入成功,做一个10 OS Tick的休眠 */
rt_thread_delay( 1000 );
}
}
int semaphore_buffer_worker_init()
{
/* 初始化ring buffer 缓冲区 */
rb_init( &working_rb, working_buffer, BUFFER_SIZE );
/* 创建信号量 */
sem = rt_sem_create( "sem", 1, RT_IPC_FLAG_FIFO );
if ( sem == RT_NULL )
{
//tc_stat(TC_STAT_END | TC_STAT_FAILED);
return 0;
}
/* 创建线程1 */
tid = rt_thread_create( "thread",
thread_entry, RT_NULL, /* 线程入口是thread entry, 入口参数是RT NULL */
THREAD_STACK_SIZE, THREAD_PRIORITY, THREAD_TIMESLICE );
if ( tid != RT_NULL )
rt_thread_startup( tid );
//else
//tc_stat(TC_STAT_END | TC_STAT_FAILED);
/* 创建线程2 */
worker = rt_thread_create( "worker",
worker_entry, RT_NULL, /* 线程入口是worker entry, 入口参数是RT NULL */
THREAD_STACK_SIZE, THREAD_PRIORITY, THREAD_TIMESLICE );
if ( worker != RT_NULL )
rt_thread_startup( worker );
//else
//tc_stat(TC_STAT_END | TC_STAT_FAILED);
return 0;
}
#ifdef RT_USING_TC
static void tc_cleanup()
{
/* 调度器上锁,上锁后,将不再切换到其他线程,仅响应中断 */
rt_enter_critical();
/* 删除信号量 */
if ( sem != RT_NULL )
rt_sem delete( sem );
/* 删除线程 */
if ( tid != RT NULL && tid->stat != RT THREAD CLOSE )
rt_thread_delete( tid );
if ( worker != RT NULL && worker->stat != RT THREAD CLOSE )
rt_thread_delete( worker );
/* 调度器解锁 */
rt exit critical();
/* 设置TestCase状态 */
tc done( TC STAT PASSED );
}
int tc semaphore buffer worker()
{
/* 设置TestCase清理回调函数 */
tc_cleanup( tc_cleanup );
semaphore_buffer_worker_init();
/* 返回TestCase运行的最长时间 */
return 100;
}
/* 输出函数命令到finsh shell中 */
FINSH FUNCTION EXPORT( tc semaphore buffer worker, a buffer worker with semaphore example );
#else
/* 用户应用入口 */
int rt_application_init()
{
semaphore_buffer_worker_init();
return 0;
}
#endif
|
|