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# TencentOS tiny开发指南
目录
- [TencentOS tiny开发指南](#tencentos-tiny开发指南)
- [1. 概述](#1-概述)
- [1.1 基础内核组件](#11-基础内核组件)
- [2. 基础内核](#2-基础内核)
- [2.1 系统管理](#21-系统管理)
- [概述](#概述)
- [API讲解](#api讲解)
- [编程实例](#编程实例)
- [运行效果](#运行效果)
- [2.2 任务管理](#22-任务管理)
- [概述](#概述-1)
- [API讲解](#api讲解-1)
- [编程实例](#编程实例-1)
- [运行效果](#运行效果-1)
- [2.3 任务间通信](#23-任务间通信)
- [2.3.1 互斥量](#231-互斥量)
- [概述](#概述-2)
- [API讲解](#api讲解-2)
- [编程实例](#编程实例-2)
- [运行效果](#运行效果-2)
- [2.3.2 信号量](#232-信号量)
- [概述](#概述-3)
- [API讲解](#api讲解-3)
- [编程实例](#编程实例-3)
- [运行效果](#运行效果-3)
- [2.3.3 事件](#233-事件)
- [概述](#概述-4)
- [API讲解](#api讲解-4)
- [编程实例](#编程实例-4)
- [运行效果](#运行效果-4)
- [2.3.4 完成量](#234-完成量)
- [概述](#概述-5)
- [API讲解](#api讲解-5)
- [编程实例](#编程实例-5)
- [运行效果](#运行效果-5)
- [2.3.5 计数锁](#235-计数锁)
- [概述](#概述-6)
- [API讲解](#api讲解-6)
- [编程实例](#编程实例-6)
- [运行效果](#运行效果-6)
- [2.3.6 栅栏](#236-栅栏)
- [概述](#概述-7)
- [API讲解](#api讲解-7)
- [编程实例](#编程实例-7)
- [运行效果](#运行效果-7)
- [2.3.7 消息队列](#237-消息队列)
- [概述](#概述-8)
- [API讲解](#api讲解-8)
- [编程实例](#编程实例-8)
- [运行效果](#运行效果-8)
- [2.3.8 邮箱队列](#238-邮箱队列)
- [概述](#概述-9)
- [API讲解](#api讲解-9)
- [编程实例](#编程实例-9)
- [运行效果](#运行效果-9)
- [2.3.9 优先级消息队列](#239-优先级消息队列)
- [概述](#概述-10)
- [API讲解](#api讲解-10)
- [编程实例](#编程实例-10)
- [运行效果](#运行效果-10)
- [2.3.10 优先级邮箱队列](#2310-优先级邮箱队列)
- [概述](#概述-11)
- [API讲解](#api讲解-11)
- [编程实例](#编程实例-11)
- [运行效果](#运行效果-11)
- [2.4 内存管理](#24-内存管理)
- [2.4.1 动态内存](#241-动态内存)
- [概述](#概述-12)
- [API讲解](#api讲解-12)
- [编程实例](#编程实例-12)
- [运行效果](#运行效果-12)
- [2.4.2 静态内存](#242-静态内存)
- [概述](#概述-13)
- [API讲解](#api讲解-13)
- [编程实例](#编程实例-13)
- [运行效果](#运行效果-13)
- [2.5 时间管理](#25-时间管理)
- [概述](#概述-14)
- [API讲解](#api讲解-14)
- [编程实例](#编程实例-14)
- [运行效果](#运行效果-14)
- [2.6 软件定时器](#26-软件定时器)
- [概述](#概述-15)
- [API讲解](#api讲解-15)
- [编程实例](#编程实例-15)
- [运行效果](#运行效果-15)
- [2.7 时间片轮转机制](#27-时间片轮转机制)
- [概述](#概述-16)
- [API讲解](#api讲解-16)
- [编程实例](#编程实例-16)
- [运行效果](#运行效果-16)
- [2.8 内核基础组件](#28-内核基础组件)
- [2.8.1 环形队列](#281-环形队列)
- [概述](#概述-17)
- [API讲解](#api讲解-17)
- [编程实例](#编程实例-17)
- [运行效果](#运行效果-17)
- [2.8.2 字符流先入先出队列](#282-字符流先入先出队列)
- [概述](#概述-18)
- [API讲解](#api讲解-18)
- [编程实例](#编程实例-18)
- [运行效果](#运行效果-18)
- [2.8.3 二项堆](#283-二项堆)
- [概述](#概述-19)
- [2.8.4 优先级队列](#284-优先级队列)
- [概述](#概述-20)
- [API讲解](#api讲解-19)
- [编程实例](#编程实例-19)
- [运行效果](#运行效果-19)
- [2.9 功耗管理](#29-功耗管理)
- [2.9.1 低功耗](#291-低功耗)
- [概述](#概述-21)
- [API讲解](#api讲解-20)
- [编程实例](#编程实例-20)
- [运行效果](#运行效果-20)
- [2.9.2 tickless](#292-tickless)
- [概述](#概述-22)
- [API讲解](#api讲解-21)
- [编程实例](#编程实例-21)
- [运行效果](#运行效果-21)
## 1. 概述
TencentOS tiny是面向物联网IOT领域的操作系统由一个实现精简的实时操作系统RTOS内核以及丰富的物联网组件组成。
### 1.1 基础内核组件
- **系统管理**
系统管理模块,主要提供了内核的初始化、内核运行启动,中断进入/退出流程托管、系统调度锁定及解锁等功能。
- **任务管理**
提供了任务的创建、删除、睡眠、取消睡眠、挂起、恢复、优先级修改、主动放弃CPU等功能。
- **任务间通信**
提供互斥量、信号量、队列、事件等常用任务间通信机制。
- **内存管理**
提供了基于堆的动态内存管理,以及静态内存块管理机制。
- **时间管理**
提供了获取/设置系统时钟滴答数、系统时钟滴答数与墙上时钟时间转换、基于墙上时钟时间的任务睡眠等机制。
- **软件定时器**
提供了软件定时器的创建、删除、启动、停止等机制。
- **时间片轮转机制**
TencentOS tiny内核在提供可抢占式调度内核基础上还提供了按时间片轮转的robin机制。
- **内核基础组件**
提供了消息队列、字符流先入先出队列等机制。
- **功耗管理**
提供了CPU低功耗运行模式设置、低功耗设备注册、板级唤醒闹钟设置等机制。
## 2. 基础内核
### 2.1 系统管理
#### 概述
系统管理模块提供了几个接口,用以初始化/启动TencentOS tiny内核、锁定/解锁系统调度等。
#### API讲解
`k_err_t tos_knl_init(void);`
初始化内核。
`k_err_t tos_knl_start(void);`
启动运行内核,开始第一个任务调度。
`int tos_knl_is_running(void);`
判断内核是否已启动运行。
`void tos_knl_irq_enter(void);`
此函数应该在中断调用函数的最前端被调用。
`void tos_knl_irq_leave(void);`
此函数应该在中断调用函数的尾端被调用。
`k_err_t tos_knl_sched_lock(void);`
锁定系统调度此函数被调用并返回K_ERR_NONE时系统调度会被锁定系统调度器不再进行任务的切换。
`k_err_t tos_knl_sched_unlock(void);`
解锁系统调度,允许任务切换。
#### 编程实例
#### 运行效果
### 2.2 任务管理
#### 概述
TencentOS tiny内核是单地址空间的可抢占式实时内核TencentOS tiny内核不提供进程模型任务对应线程的概念是最小的调度运行体也是最小的资源持有单位。
任务的本质是一个拥有独立栈空间的可调度运行实体,用户可以在任务的入口函数中编写自己的业务逻辑;多个任务之间可以通过系统提供的任务间通信机制进行同步或者信息传递等操作;每个任务都有优先级,高优先级任务可以抢占低优先级任务的运行。
#### API讲解
创建任务的系统api接口为tos_task_create接口原型如下
```c
k_err_t tos_task_create(k_task_t *task,
char *name,
k_task_entry_t entry,
void *arg,
k_prio_t prio,
k_stack_t *stk_base,
size_t stk_size,
k_timeslice_t timeslice);
```
这里详细讲解此api参数意义
- task
这是一个k_task_t类型的指针k_task_t是内核的任务结构体类型。注意task指针应该指向生命周期大于待创建任务体生命周期的k_task_t类型变量如果该指针指向的变量生命周期比待创建的任务体生命周期短譬如可能是一个生命周期极端的函数栈上变量可能会出现任务体还在运行而k_task_t变量已被销毁会导致系统调度出现不可预知问题。
- name
指向任务名字符串的指针。注意同task该指针指向的字符串生命周期应该大于待创建的任务体生命周期一般来说传入字符串常量指针即可。
- entry
任务体运行的函数入口。当任务创建完毕进入运行状态后entry是任务执行的入口用户可以在此函数中编写业务逻辑。
- arg
传递给任务入口函数的参数。
- prio
任务优先级。prio的数值越小优先级越高。用户可以在tos_config.h中通过TOS_CFG_TASK_PRIO_MAX来配置任务优先级的最大数值在内核的实现中idle任务的优先级会被分配为TOS_CFG_TASK_PRIO_MAX - 1,此优先级只能被idle任务使用。因此对于一个用户创建的任务来说合理的优先级范围应该为[0, TOS_CFG_TASK_PRIO_MAX - 2]。另外TOS_CFG_TASK_PRIO_MAX的配置值必需大于等于8。
- stk_base
任务在运行时使用的栈空间的起始地址。注意同task该指针指向的内存空间的生命周期应该大于待创建的任务体生命周期。stk_base是k_stack_t类型的数组起始地址。
- stk_size
任务的栈空间大小。注意因为stk_base是k_stack_t类型的数组指针因此实际栈空间所占内存大小为stk_size * sizeof(k_stack_t)。
- timeslice
时间片轮转机制下当前任务的时间片大小。当timeslice为0时任务调度时间片会被设置为默认大小TOS_CFG_CPU_TICK_PER_SECOND / 10系统时钟滴答systick数 / 10。
#### 编程实例
1、在tos_config.h中配置最大任务优先级TOS_CFG_TASK_PRIO_MAX
`#define TOS_CFG_TASK_PRIO_MAX 10u`
2、配置每秒钟的系统滴答数TOS_CFG_CPU_TICK_PER_SECOND
`#define TOS_CFG_CPU_TICK_PER_SECOND 1000u`
3、编写main.c示例代码
```c
#include "tos_k.h" // 添加TencentOS tiny内核接口头文件
#include "mcu_init.h" // 包含mcu初始化头文件里面有board_init等板级启动代码函数原型声明
#define STK_SIZE_TASK_PRIO4 512 // 优先级为4的任务栈大小为512
#define STK_SIZE_TASK_PRIO5 1024 // 优先级为5的任务栈大小为1024
k_stack_t stack_task_prio4[STK_SIZE_TASK_PRIO4]; // 优先级为4的任务栈空间
k_stack_t stack_task_prio5[STK_SIZE_TASK_PRIO5]; // 优先级为5的任务栈空间
k_task_t task_prio4; // 优先级为4的任务体
k_task_t task_prio5; // 优先级为5的任务体
extern void entry_task_prio4(void *arg); // 优先级为4的任务体入口函数
extern void entry_task_prio5(void *arg); // 优先级为5的任务体入口函数
uint32_t arg_task_prio4_array[3] = { // 优先级为4的任务体入口函数入参
1, 2, 3,
};
char *arg_task_prio5_string = "arg for task_prio5"; // 优先级为5的任务体入口函数入参
static void dump_uint32_array(uint32_t *array, size_t len)
{
size_t i = 0;
for (i = 0; i < len; ++i) {
printf("%d\t", array[i]);
}
printf("\n\n");
}
void entry_task_prio4(void *arg)
{
uint32_t *array_from_main = (uint32_t *)arg; // 捕获调用者传入的参数
printf("array from main:\n");
dump_uint32_array(array_from_main, 3); // dump传入的参数数组
while (K_TRUE) {
printf("task_prio4 body\n"); // 任务运行体,不断打印这条信息
tos_task_delay(1000); // 睡眠1000个系统时钟滴答以下记作systick因为TOS_CFG_CPU_TICK_PER_SECOND为1000也就是一秒钟会有1000个systick因此睡眠1000个systick就是睡眠了1秒。
}
}
void entry_task_prio5(void *arg)
{
int i = 0;
char *string_from_main = (char *)arg;
printf("string from main:\n");
printf("%s\n\n", string_from_main); // 打印出调用者传入的字符串参数
while (K_TRUE) {
if (i == 2) {
printf("i = %d\n", i); // i为2时挂起task_prio4task_prio4停止运行
tos_task_suspend(&task_prio4);
} else if (i == 4) {
printf("i = %d\n", i); // i为4时恢复task_prio4的运行
tos_task_resume(&task_prio4);
} else if (i == 6) {
printf("i = %d\n", i); // i为6时删除task_prio4task_prio4不再运行
tos_task_destroy(&task_prio4);
}
printf("task_prio5 body\n");
tos_task_delay(1000);
++i;
}
}
int main(void)
{
board_init(); // 执行板级初始化代码,初始化串口等外设。
tos_knl_init(); // 初始化TencentOS tiny内核
// 创建一个优先级为4的任务
(void)tos_task_create(&task_prio4, "task_prio4", entry_task_prio4,
(void *)(&arg_task_prio4_array[0]), 4,
stack_task_prio4, STK_SIZE_TASK_PRIO4, 0);
// 创建一个优先级为5的任务
(void)tos_task_create(&task_prio5, "task_prio5", entry_task_prio5,
(void *)arg_task_prio5_string, 5,
stack_task_prio5, STK_SIZE_TASK_PRIO5, 0);
// 开始内核调度
tos_knl_start();
}
```
#### 运行效果
> array from main:
> 1 2 3
>
> task_prio4 body
> string from main:
> arg for task_prio5
>
> task_prio5 body
> task_prio4 body
> task_prio5 body
> task_prio4 body
> i = 2
> task_prio5 body
> task_prio5 body
> i = 4
> task_prio4 body
> task_prio5 body
> task_prio4 body
> task_prio5 body
> task_prio4 body
> i = 6
> task_prio5 body
> task_prio5 body
> task_prio5 body
> task_prio5 body
> task_prio5 body
> task_prio5 body
> task_prio5 body
[实例代码](code/2.2%20task%20manager/main.c)
### 2.3 任务间通信
#### 2.3.1 互斥量
##### 概述
互斥量又称互斥锁,一般用于共享资源的互斥排他性访问保护。
互斥量在任意时刻处于且仅会处于解锁或锁定状态,当一个任务获取到一把锁后(互斥量锁定),其他任务再尝试获得这把锁时会失败或进入阻塞状态,当该任务释放持有的锁时(互斥量解锁),会唤醒一个正阻塞等待此互斥量的任务,被唤醒的任务将会获取这把锁。
在多任务运行环境中,有些共享资源不具有多线程可重入性,对于这类不希望被多任务同时访问的资源(临界资源),可以采用互斥量来进行保护,后面的编程实例章节会演示这一编程范式。
##### API讲解
##### 编程实例
1、在tos_config.h中配置互斥量组件开关TOS_CFG_MUTEX_EN
`#define TOS_CFG_MUTEX_EN 1u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_WRITER 512
#define STK_SIZE_TASK_READER 512
k_stack_t stack_task_writer[STK_SIZE_TASK_WRITER];
k_stack_t stack_task_reader[STK_SIZE_TASK_READER];
k_task_t task_writer;
k_task_t task_reader;
extern void entry_task_writer(void *arg);
extern void entry_task_reader(void *arg);
k_mutex_t critical_resource_locker;
// 一片临界区内存
static uint32_t critical_resource[3];
static void write_critical_resource(int salt)
{
size_t i = 0;
// 此函数每次向共享内存中按递增顺序写入三个无符号整数
printf("writting critical resource:\n");
for (i = 0; i < 3; ++i) {
printf("%d\t", salt + i);
critical_resource[i] = salt + i;
}
printf("\n");
}
void entry_task_writer(void *arg)
{
size_t salt = 0;
k_err_t err;
while (K_TRUE) {
// 在向临界区写入数据之前,先尝试获取临界区保护锁
err = tos_mutex_pend(&critical_resource_locker);
if (err == K_ERR_NONE) {
// 成功获取锁之后,向临界区写入数据
write_critical_resource(salt);
// 写完数据后,释放互斥锁
tos_mutex_post(&critical_resource_locker);
}
tos_task_delay(1000);
++salt;
}
}
static void read_critical_resource(void)
{
size_t i = 0;
// 从临界区读取数据
printf("reading critical resource:\n");
for (i = 0; i < 3; ++i) {
printf("%d\t", critical_resource[i]);
}
printf("\n");
}
void entry_task_reader(void *arg)
{
k_err_t err;
while (K_TRUE) {
// 读取临界区数据之前,先尝试获取临界区保护锁
err = tos_mutex_pend(&critical_resource_locker);
if (err == K_ERR_NONE) {
// 成功获取锁之后,从临界区读取数据
read_critical_resource();
// 读取数据完毕后,释放互斥锁
tos_mutex_post(&critical_resource_locker);
}
tos_task_delay(1000);
}
}
int main(void)
{
board_init();
tos_knl_init();
// 创建临界区保护互斥锁
tos_mutex_create(&critical_resource_locker);
(void)tos_task_create(&task_writer, "writer", entry_task_writer, NULL,
4, stack_task_writer, STK_SIZE_TASK_WRITER, 0);
(void)tos_task_create(&task_reader, "reader", entry_task_reader, NULL,
4, stack_task_reader, STK_SIZE_TASK_READER, 0);
tos_knl_start();
}
```
##### 运行效果
> writting critical resource:
> 0 1 2
> reading critical resource:
> 0 1 2
> writting critical resource:
> 1 2 3
> reading critical resource:
> 1 2 3
> writting critical resource:
> 2 3 4
> reading critical resource:
> 2 3 4
> writting critical resource:
> 3 4 5
> reading critical resource:
> 3 4 5
> writting critical resource:
> 4 5 6
> reading critical resource:
> 4 5 6
> writting critical resource:
> 5 6 7
> reading critical resource:
> 5 6 7
> writting critical resource:
> 6 7 8
> reading critical resource:
> 6 7 8
> writting critical resource:
> 7 8 9
> reading critical resource:
> 7 8 9
[实例代码](code/2.3.1%20mutex/main.c)
#### 2.3.2 信号量
##### 概述
信号量是一种实现任务间同步的机制,一般用于多个任务间有限资源竞争访问。
通常来说一个信号量中持有一个整形数值用以表示可用资源的数量。当一个信号量的可用资源数量大于0时任务尝试获取该信号量成功信号量的可用资源数减一当一个信号量的可用资源数等于0时任务尝试获取该信号量失败或进入阻塞状态。信号量的这一模式当可用资源数为1时可将其用于资源的互斥访问或者解决生产者-消费者问题中的资源生产-消费问题。编程实例章节会演示生产者-消费者问题的解决范式。
##### API讲解
##### 编程实例
1、在tos_config.h中配置信号量组件开关TOS_CFG_SEM_EN
`#define TOS_CFG_SEM_EN 1u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_PRODUCER 512
#define STK_SIZE_TASK_CONSUMER 512
k_stack_t stack_task_producer[STK_SIZE_TASK_PRODUCER];
k_stack_t stack_task_consumer[STK_SIZE_TASK_CONSUMER];
k_task_t task_producer;
k_task_t task_consumer;
extern void entry_task_producer(void *arg);
extern void entry_task_consumer(void *arg);
k_mutex_t buffer_locker;
k_sem_t full;
k_sem_t empty;
#define RESOURCE_COUNT_MAX 3
struct resource_st {
int cursor;
uint32_t buffer[RESOURCE_COUNT_MAX];
} resource = { 0, {0} };
static void produce_item(int salt)
{
printf("produce item:\n");
printf("%d", salt);
resource.buffer[resource.cursor++] = salt;
printf("\n");
}
void entry_task_producer(void *arg)
{
size_t salt = 0;
k_err_t err;
while (K_TRUE) {
err = tos_sem_pend(&empty, TOS_TIME_FOREVER);
if (err != K_ERR_NONE) {
continue;
}
err = tos_mutex_pend(&buffer_locker);
if (err != K_ERR_NONE) {
continue;
}
produce_item(salt);
tos_mutex_post(&buffer_locker);
tos_sem_post(&full);
tos_task_delay(1000);
++salt;
}
}
static void consume_item(void)
{
printf("cosume item:\n");
printf("%d\t", resource.buffer[--resource.cursor]);
printf("\n");
}
void entry_task_consumer(void *arg)
{
k_err_t err;
while (K_TRUE) {
err = tos_sem_pend(&full, TOS_TIME_FOREVER);
if (err != K_ERR_NONE) {
continue;
}
tos_mutex_pend(&buffer_locker);
if (err != K_ERR_NONE) {
continue;
}
consume_item();
tos_mutex_post(&buffer_locker);
tos_sem_post(&empty);
tos_task_delay(2000);
}
}
int main(void)
{
board_init();
tos_knl_init();
tos_mutex_create(&buffer_locker);
tos_sem_create(&full, 0);
tos_sem_create(&empty, RESOURCE_COUNT_MAX);
(void)tos_task_create(&task_producer, "producer", entry_task_producer, NULL,
4, stack_task_producer, STK_SIZE_TASK_PRODUCER, 0);
(void)tos_task_create(&task_consumer, "consumer", entry_task_consumer, NULL,
4, stack_task_consumer, STK_SIZE_TASK_CONSUMER, 0);
tos_knl_start();
}
```
##### 运行效果
> produce iterm:
> 0
> cosume iterm:
> 0
> produce iterm:
> 1
> produce iterm:
> 2
> cosume iterm:
> 2
> produce iterm:
> 3
> produce iterm:
> 4
> cosume iterm:
> 4
> produce iterm:
> 5
> cosume iterm:
> 5
> produce iterm:
> 6
> cosume iterm:
> 6
> produce iterm:
> 7
> cosume iterm:
> 7
> produce iterm:
> 8
> cosume iterm:
> 8
> produce iterm:
> 9
> cosume iterm:
> 9
> produce iterm:
> 10
[实例代码](code/2.3.2%20semaphore/main.c)
#### 2.3.3 事件
##### 概述
事件提供了一种任务间实现同步和信息传递的机制。一般来说,一个事件中包含了一个旗标,这个旗标的每一位表示一个“事件”。
一个任务可以等待一个或者多个“事件”的发生,其他任务在一定的业务条件下可以通过写入特定“事件”唤醒等待此“事件”的任务,实现一种类似信号的编程范式。
##### API讲解
##### 编程实例
1、在tos_config.h中配置事件组件开关TOS_CFG_EVENT_EN
`#define TOS_CFG_EVENT_EN 1u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_LISTENER 512
#define STK_SIZE_TASK_TRIGGER 512
k_stack_t stack_task_listener1[STK_SIZE_TASK_LISTENER];
k_stack_t stack_task_listener2[STK_SIZE_TASK_LISTENER];
k_stack_t stack_task_trigger[STK_SIZE_TASK_TRIGGER];
k_task_t task_listener1;
k_task_t task_listener2;
k_task_t task_trigger;
extern void entry_task_listener1(void *arg);
extern void entry_task_listener2(void *arg);
extern void entry_task_trigger(void *arg);
const k_event_flag_t event_eeny = (k_event_flag_t)(1 << 0);
const k_event_flag_t event_meeny = (k_event_flag_t)(1 << 1);
const k_event_flag_t event_miny = (k_event_flag_t)(1 << 2);
const k_event_flag_t event_moe = (k_event_flag_t)(1 << 3);
k_event_t event;
void entry_task_listener1(void *arg)
{
k_event_flag_t flag_match;
k_err_t err;
while (K_TRUE) {
// 此任务监听四个事件因为使用了TOS_OPT_EVENT_PEND_ALL选项因此必须是四个事件同时到达此任务才会被唤醒
err = tos_event_pend(&event, event_eeny | event_meeny | event_miny | event_moe,
&flag_match, TOS_TIME_FOREVER, TOS_OPT_EVENT_PEND_ALL | TOS_OPT_EVENT_PEND_CLR);
if (err == K_ERR_NONE) {
printf("entry_task_listener1:\n");
printf("eeny, meeny, miny, moe, they all come\n");
}
}
}
void entry_task_listener2(void *arg)
{
k_event_flag_t flag_match;
k_err_t err;
while (K_TRUE) {
// 此任务监听四个事件因为使用了TOS_OPT_EVENT_PEND_ANY选项因此四个事件任意一个到达包括四个事件同时到达任务就会被唤醒
err = tos_event_pend(&event, event_eeny | event_meeny | event_miny | event_moe,
&flag_match, TOS_TIME_FOREVER, TOS_OPT_EVENT_PEND_ANY | TOS_OPT_EVENT_PEND_CLR);
if (err == K_ERR_NONE) {
printf("entry_task_listener2:\n");
// 有事件到达,判断具体是哪个事件
if (flag_match == event_eeny) {
printf("eeny comes\n");
}
if (flag_match == event_meeny) {
printf("meeny comes\n");
}
if (flag_match == event_miny) {
printf("miny comes\n");
}
if (flag_match == event_moe) {
printf("moe comes\n");
}
if (flag_match == (event_eeny | event_meeny | event_miny | event_moe)) {
printf("all come\n");
}
}
}
}
void entry_task_trigger(void *arg)
{
int i = 1;
while (K_TRUE) {
if (i == 2) {
printf("entry_task_trigger:\n");
printf("eeny will come\n");
// 发送eeny事件task_listener2会被唤醒
tos_event_post(&event, event_eeny);
}
if (i == 3) {
printf("entry_task_trigger:\n");
printf("meeny will come\n");
// 发送eeny事件task_listener2会被唤醒
tos_event_post(&event, event_meeny);
}
if (i == 4) {
printf("entry_task_trigger:\n");
printf("miny will come\n");
// 发送eeny事件task_listener2会被唤醒
tos_event_post(&event, event_miny);
}
if (i == 5) {
printf("entry_task_trigger:\n");
printf("moe will come\n");
// 发送eeny事件task_listener2会被唤醒
tos_event_post(&event, event_moe);
}
if (i == 6) {
printf("entry_task_trigger:\n");
printf("all will come\n");
// 同时发送四个事件因为task_listener1的优先级高于task_listener2因此这里task_listener1会被唤醒
tos_event_post(&event, event_eeny | event_meeny | event_miny | event_moe);
}
tos_task_delay(1000);
++i;
}
}
int main(void)
{
board_init();
tos_knl_init();
tos_event_create(&event, (k_event_flag_t)0u);
// 这里task_listener1的优先级比task_listener2高因此在task_trigger发送所有事件时task_listener1会被唤醒
// 读者可以尝试将task_listener1优先级修改为5比task_listener2低此设置下在task_trigger发送所有事件时task_listener2将会被唤醒。
(void)tos_task_create(&task_listener1, "listener1", entry_task_listener1, NULL,
3, stack_task_listener1, STK_SIZE_TASK_LISTENER, 0);
(void)tos_task_create(&task_listener2, "listener2", entry_task_listener2, NULL,
4, stack_task_listener2, STK_SIZE_TASK_LISTENER, 0);
(void)tos_task_create(&task_trigger, "trigger", entry_task_trigger, NULL,
4, stack_task_trigger, STK_SIZE_TASK_TRIGGER, 0);
tos_knl_start();
}
```
##### 运行效果
> entry_task_trigger:
> eeny will come
> entry_task_listener2:
> eeny comes
> entry_task_trigger:
> meeny will come
> entry_task_listener2:
> meeny comes
> entry_task_trigger:
> miny will come
> entry_task_listener2:
> miny comes
> entry_task_trigger:
> moe will come
> entry_task_listener2:
> moe comes
> entry_task_trigger:
> all will come
> entry_task_listener1:
> eeny, meeny, miny, moe, they all come
[实例代码](code/2.3.3%20event/main.c)
#### 2.3.4 完成量
##### 概述
完成量是一种简单的任务间通信机制,用以在任务间同步某一事件是否已“完成”的信息。
##### API讲解
##### 编程实例
1、编写main.c示例代码
```c
/*
这个例子里创建了两个任务一个任务task_wait等待完成量完成另一个任务负责触发完成量让完成量完成
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_WAIT 512
#define STK_SIZE_TASK_TRIGGER 512
k_stack_t stack_task_wait[STK_SIZE_TASK_WAIT];
k_stack_t stack_task_trigger[STK_SIZE_TASK_TRIGGER];
k_task_t task_wait;
k_task_t task_trigger;
k_completion_t completion;
void entry_task_wait(void *arg)
{
printf("wait: I won't go further until someone do the trigger(make it 'complete')\n");
tos_completion_pend(&completion);
printf("wait: someone has made it complete, so I'm here\n");
}
void entry_task_trigger(void *arg)
{
printf("trigger: I'm the one who make complete, anyone waitting for the complete won't go further until I do the trigger\n");
tos_completion_post(&completion);
printf("trigger: I have done the completion\n");
}
int main(void)
{
board_init();
tos_knl_init();
tos_completion_create(&completion);
(void)tos_task_create(&task_wait, "wait", entry_task_wait, NULL,
3, stack_task_wait, STK_SIZE_TASK_WAIT, 0);
(void)tos_task_create(&task_trigger, "trigger", entry_task_trigger, NULL,
4, stack_task_trigger, STK_SIZE_TASK_TRIGGER, 0);
tos_knl_start();
}
```
##### 运行效果
> wait: I won't go further until someone do the trigger(make it 'complete')
> trigger: I'm the one who make complete, anyone waitting for the complete won't go further until I do the trigger
> wait: someone make it complete, so I'm here
> trigger: I have done the completion
[实例代码](code/2.3.4%20completion/main.c)
#### 2.3.5 计数锁
##### 概述
计数锁提供了一种“计数信息”同步的概念计数锁创建的时候会指定一个计数值每当有任务执行tos_countdownlatch_post时该计数锁的计数值减一直到计数锁的计数值为零时等待此计数锁的任务才会被唤醒。
##### API讲解
##### 编程实例
1、编写main.c示例代码
```c
/*
假设有这样的业务场景,共有三个勇士,此三个勇士分头去寻找三个武器的碎片,只有这三个勇士都找到碎片后,法师才能将三个碎片合成为武器。用代码看具体如何使用计数锁来完成这个模型。
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_WIZARD 512
#define STK_SIZE_TASK_WARRIOR 512
k_stack_t stack_task_wizard[STK_SIZE_TASK_WIZARD];
k_stack_t stack_task_warrior_0[STK_SIZE_TASK_WARRIOR];
k_stack_t stack_task_warrior_1[STK_SIZE_TASK_WARRIOR];
k_stack_t stack_task_warrior_2[STK_SIZE_TASK_WARRIOR];
k_task_t task_wizard;
k_task_t task_warrior_0;
k_task_t task_warrior_1;
k_task_t task_warrior_2;
k_countdownlatch_t countdownlatch;
void entry_task_warrior_0(void *arg)
{
printf("warrior 0: I have done my job\n");
tos_countdownlatch_post(&countdownlatch);
}
void entry_task_warrior_1(void *arg)
{
printf("warrior 1: I have done my job\n");
tos_countdownlatch_post(&countdownlatch);
}
void entry_task_warrior_2(void *arg)
{
printf("warrior 2: I have done my job\n");
tos_countdownlatch_post(&countdownlatch);
}
void entry_task_wizard(void *arg)
{
printf("wizard: I will set 3 warriors to find the fragments\n");
tos_countdownlatch_create(&countdownlatch, 3);
(void)tos_task_create(&task_warrior_0, "warrior_0", entry_task_warrior_0, NULL,
4, stack_task_warrior_0, STK_SIZE_TASK_WARRIOR, 0);
(void)tos_task_create(&task_warrior_1, "warrior_1", entry_task_warrior_1, NULL,
4, stack_task_warrior_1, STK_SIZE_TASK_WARRIOR, 0);
(void)tos_task_create(&task_warrior_2, "warrior_2", entry_task_warrior_2, NULL,
4, stack_task_warrior_2, STK_SIZE_TASK_WARRIOR, 0);
printf("wizard: now warriors are on their way, I will wait here until they all done the job\n");
tos_countdownlatch_pend(&countdownlatch);
printf("wizard: the warriors all have done their jobs, let's make the weapon\n");
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_wizard, "wizard", entry_task_wizard, NULL,
3, stack_task_wizard, STK_SIZE_TASK_WIZARD, 0);
tos_knl_start();
}
```
##### 运行效果
> wizard: I will set 3 warriors to find the fragments
> wizard: now warriors are on their way, I will wait here until they all done the job
> warrior 0: I have done my job
> warrior 1: I have done my job
> warrior 2: I have done my job
> wizard: the warriors all have done their jobs, let's make the weapon
[实例代码](code/2.3.5%20countdownlatch/main.c)
#### 2.3.6 栅栏
##### 概述
栅栏提供了一种设置任务阻塞屏障的机制栅栏创建的时候会指定一个计数值每当有任务执行tos_barrier_pend时该计数锁的计数值减一直到计数锁的计数值为零时所有阻塞在tos_barrier_pend点上的任务才可以往下运行。
##### API讲解
##### 编程实例
1、编写main.c示例代码
```c
/*
假设有这样的业务场景,共有三个勇士,此三个勇士分头去寻找三个武器的碎片,任意勇士找到自己的那块武器碎片时,都在原地等待,直到所有的小伙伴都找到了自己的武器碎片后,才各自采取下一步行动。用代码看具体如何使用栅栏来完成这个模型。
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_WARRIOR 512
k_stack_t stack_task_warrior_0[STK_SIZE_TASK_WARRIOR];
k_stack_t stack_task_warrior_1[STK_SIZE_TASK_WARRIOR];
k_stack_t stack_task_warrior_2[STK_SIZE_TASK_WARRIOR];
k_task_t task_warrior_0;
k_task_t task_warrior_1;
k_task_t task_warrior_2;
k_barrier_t barrier;
void entry_task_warrior_0(void *arg)
{
printf("warrior 0: I'm searching the fragment\n");
tos_task_delay(1000);
printf("warrior 0: I have done my job, waitting other buddies done their job\n");
tos_barrier_pend(&barrier);
printf("warrior 0: all buddies find their fragment, do my next job\n");
}
void entry_task_warrior_1(void *arg)
{
printf("warrior 1: I'm searching the fragment\n");
tos_task_delay(1500);
printf("warrior 1: I have done my job, waitting other buddies done their job\n");
tos_barrier_pend(&barrier);
printf("warrior 1: all buddies find their fragment, do my next job\n");
}
void entry_task_warrior_2(void *arg)
{
printf("warrior 2: I'm searching the fragment\n");
tos_task_delay(2000);
printf("warrior 2: I have done my job, waitting other buddies done their job\n");
tos_barrier_pend(&barrier);
printf("warrior 2: all buddies find their fragment, do my next job\n");
}
int main(void)
{
board_init();
tos_knl_init();
tos_barrier_create(&barrier, 3);
(void)tos_task_create(&task_warrior_0, "warrior_0", entry_task_warrior_0, NULL,
4, stack_task_warrior_0, STK_SIZE_TASK_WARRIOR, 0);
(void)tos_task_create(&task_warrior_1, "warrior_1", entry_task_warrior_1, NULL,
4, stack_task_warrior_1, STK_SIZE_TASK_WARRIOR, 0);
(void)tos_task_create(&task_warrior_2, "warrior_2", entry_task_warrior_2, NULL,
4, stack_task_warrior_2, STK_SIZE_TASK_WARRIOR, 0);
tos_knl_start();
}
```
##### 运行效果
> warrior 0: I'm searching the fragment
> warrior 1: I'm searching the fragment
> warrior 2: I'm searching the fragment
> warrior 0: I have done my job, waitting other buddies done their job
> warrior 1: I have done my job, waitting other buddies done their job
> warrior 2: I have done my job, waitting other buddies done their job
> warrior 2: all buddies find their fragment, do my next job
> warrior 0: all buddies find their fragment, do my next job
> warrior 1: all buddies find their fragment, do my next job
[实例代码](code/2.3.6%20barrier/main.c)
#### 2.3.7 消息队列
##### 概述
消息队列提供了任务间传递指针数据的机制,所谓的“消息“就是指针。消息本身如何解析使用,由传递消息的两个任务自行规定,消息队列不对消息本身做任何规定和限制,消息队列仅承担指针数据的传递义务。
##### API讲解
##### 编程实例
1、在tos_config.h中配置消息队列组件开关TOS_CFG_MESSAGE_QUEUE_EN
`#define TOS_CFG_MESSAGE_QUEUE_EN 1u`
2、编写main.c示例代码
```c
/*
这里演示如何使用消息队列在sender和receiver任务之间传递消息一个指针此案例中这个指针信息指向的是一个字符串
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_RECEIVER 512
#define STK_SIZE_TASK_SENDER 512
#define PRIO_TASK_RECEIVER_HIGHER_PRIO 4
#define PRIO_TASK_RECEIVER_LOWER_PRIO (PRIO_TASK_RECEIVER_HIGHER_PRIO + 1)
#define MESSAGE_MAX 10
k_stack_t stack_task_receiver_higher_prio[STK_SIZE_TASK_RECEIVER];
k_stack_t stack_task_receiver_lower_prio[STK_SIZE_TASK_RECEIVER];
k_stack_t stack_task_sender[STK_SIZE_TASK_SENDER];
uint8_t msg_pool[MESSAGE_MAX * sizeof(void *)];
k_task_t task_receiver_higher_prio;
k_task_t task_receiver_lower_prio;
k_task_t task_sender;
k_msg_q_t msg_q;
extern void entry_task_receiver_higher_prio(void *arg);
extern void entry_task_receiver_lower_prio(void *arg);
extern void entry_task_sender(void *arg);
void entry_task_receiver_higher_prio(void *arg)
{
k_err_t err;
void *msg_received;
while (K_TRUE) {
err = tos_msg_q_pend(&msg_q, &msg_received, TOS_TIME_FOREVER);
if (err == K_ERR_NONE) {
printf("higher: msg incoming[%s]\n", (char *)msg_received);
}
}
}
void entry_task_receiver_lower_prio(void *arg)
{
k_err_t err;
void *msg_received;
while (K_TRUE) {
err = tos_msg_q_pend(&msg_q, &msg_received, TOS_TIME_FOREVER);
if (err == K_ERR_NONE) {
printf("lower: msg incoming[%s]\n", (char *)msg_received);
}
}
}
void entry_task_sender(void *arg)
{
int i = 1;
char *msg_to_one_receiver = "message for one receiver(with highest priority)";
char *msg_to_all_receiver = "message for all receivers";
while (K_TRUE) {
if (i == 2) {
printf("sender: send a message to one receiver, and shoud be the highest priority one\n");
tos_msg_q_post(&msg_q, msg_to_one_receiver);
}
if (i == 3) {
printf("sender: send a message to all recevier\n");
tos_msg_q_post_all(&msg_q, msg_to_all_receiver);
}
if (i == 4) {
printf("sender: send a message to one receiver, and shoud be the highest priority one\n");
tos_msg_q_post(&msg_q, msg_to_one_receiver);
}
if (i == 5) {
printf("sender: send a message to all recevier\n");
tos_msg_q_post_all(&msg_q, msg_to_all_receiver);
}
tos_task_delay(1000);
++i;
}
}
int main(void)
{
board_init();
tos_knl_init();
tos_msg_q_create(&msg_q, msg_pool, MESSAGE_MAX);
(void)tos_task_create(&task_receiver_higher_prio, "receiver_higher_prio",
entry_task_receiver_higher_prio, NULL, PRIO_TASK_RECEIVER_HIGHER_PRIO,
stack_task_receiver_higher_prio, STK_SIZE_TASK_RECEIVER, 0);
(void)tos_task_create(&task_receiver_lower_prio, "receiver_lower_prio",
entry_task_receiver_lower_prio, NULL, PRIO_TASK_RECEIVER_LOWER_PRIO,
stack_task_receiver_lower_prio, STK_SIZE_TASK_RECEIVER, 0);
(void)tos_task_create(&task_sender, "sender", entry_task_sender, NULL,
4, stack_task_sender, STK_SIZE_TASK_SENDER, 0);
tos_knl_start();
}
```
##### 运行效果
> sender: send a message to one receiver, and shoud be the highest priority one
> higher: msg incoming[message for one receiver(with highest priority)]
> sender: send a message to all recevier
> higher: msg incoming[message for all receivers]
> lower: msg incoming[message for all receivers]
> sender: send a message to one receiver, and shoud be the highest priority one
> higher: msg incoming[message for one receiver(with highest priority)]
> sender: send a message to all recevier
> higher: msg incoming[message for all receivers]
> lower: msg incoming[message for all receivers]
[实例代码](code/2.3.7%20message%20queue/main.c)
#### 2.3.8 邮箱队列
##### 概述
消息队列传递的是指针,邮箱队列传递的是大片的内存数据。
##### API讲解
##### 编程实例
1、在tos_config.h中配置邮箱队列组件开关TOS_CFG_MAIL_QUEUE_EN
`#define TOS_CFG_MAIL_QUEUE_EN 1u`
2、编写main.c示例代码
```c
/*
这里演示如何使用邮箱队列在sender和receiver任务之间传递邮箱此案例中邮件也就是邮箱要传递的内存数据为一个mail_t类型的结构体从此案例中可以看出来邮箱队列相对消息队列来说可以传递更为复杂的内存块数据
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_RECEIVER 512
#define STK_SIZE_TASK_SENDER 512
#define PRIO_TASK_RECEIVER_HIGHER_PRIO 4
#define PRIO_TASK_RECEIVER_LOWER_PRIO (PRIO_TASK_RECEIVER_HIGHER_PRIO + 1)
#define MAIL_MAX 10
k_stack_t stack_task_receiver_higher_prio[STK_SIZE_TASK_RECEIVER];
k_stack_t stack_task_receiver_lower_prio[STK_SIZE_TASK_RECEIVER];
k_stack_t stack_task_sender[STK_SIZE_TASK_SENDER];
typedef struct mail_st {
char *message;
int payload;
} mail_t;
uint8_t mail_pool[MAIL_MAX * sizeof(mail_t)];
k_task_t task_receiver_higher_prio;
k_task_t task_receiver_lower_prio;
k_task_t task_sender;
k_mail_q_t mail_q;
extern void entry_task_receiver_higher_prio(void *arg);
extern void entry_task_receiver_lower_prio(void *arg);
extern void entry_task_sender(void *arg);
void entry_task_receiver_higher_prio(void *arg)
{
k_err_t err;
mail_t mail;
size_t mail_size;
while (K_TRUE) {
err = tos_mail_q_pend(&mail_q, &mail, &mail_size, TOS_TIME_FOREVER);
if (err == K_ERR_NONE) {
TOS_ASSERT(mail_size == sizeof(mail_t));
printf("higher: msg incoming[%s], payload[%d]\n", mail.message, mail.payload);
}
}
}
void entry_task_receiver_lower_prio(void *arg)
{
k_err_t err;
mail_t mail;
size_t mail_size;
while (K_TRUE) {
err = tos_mail_q_pend(&mail_q, &mail, &mail_size, TOS_TIME_FOREVER);
if (err == K_ERR_NONE) {
TOS_ASSERT(mail_size == sizeof(mail_t));
printf("lower: msg incoming[%s], payload[%d]\n", mail.message, mail.payload);
}
}
}
void entry_task_sender(void *arg)
{
int i = 1;
mail_t mail;
while (K_TRUE) {
if (i == 2) {
printf("sender: send a mail to one receiver, and shoud be the highest priority one\n");
mail.message = "1st time post";
mail.payload = 1;
tos_mail_q_post(&mail_q, &mail, sizeof(mail_t));
}
if (i == 3) {
printf("sender: send a message to all recevier\n");
mail.message = "2nd time post";
mail.payload = 2;
tos_mail_q_post_all(&mail_q, &mail, sizeof(mail_t));
}
if (i == 4) {
printf("sender: send a message to one receiver, and shoud be the highest priority one\n");
mail.message = "3rd time post";
mail.payload = 3;
tos_mail_q_post(&mail_q, &mail, sizeof(mail_t));
}
if (i == 5) {
printf("sender: send a message to all recevier\n");
mail.message = "4th time post";
mail.payload = 4;
tos_mail_q_post_all(&mail_q, &mail, sizeof(mail_t));
}
tos_task_delay(1000);
++i;
}
}
int main(void)
{
board_init();
tos_knl_init();
tos_mail_q_create(&mail_q, mail_pool, MAIL_MAX, sizeof(mail_t));
(void)tos_task_create(&task_receiver_higher_prio, "receiver_higher_prio",
entry_task_receiver_higher_prio, NULL, PRIO_TASK_RECEIVER_HIGHER_PRIO,
stack_task_receiver_higher_prio, STK_SIZE_TASK_RECEIVER, 0);
(void)tos_task_create(&task_receiver_lower_prio, "receiver_lower_prio",
entry_task_receiver_lower_prio, NULL, PRIO_TASK_RECEIVER_LOWER_PRIO,
stack_task_receiver_lower_prio, STK_SIZE_TASK_RECEIVER, 0);
(void)tos_task_create(&task_sender, "sender", entry_task_sender, NULL,
5, stack_task_sender, STK_SIZE_TASK_SENDER, 0);
tos_knl_start();
}
```
##### 运行效果
> sender: send a mail to one receiver, and shoud be the highest priority one
> higher: msg incoming[1st time post], payload[1]
> sender: send a message to all recevier
> higher: msg incoming[2nd time post], payload[2]
> lower: msg incoming[2nd time post], payload[2]
> sender: send a message to one receiver, and shoud be the highest priority one
> higher: msg incoming[3rd time post], payload[3]
> sender: send a message to all recevier
> higher: msg incoming[4th time post], payload[4]
> lower: msg incoming[4th time post], payload[4]
[实例代码](code/2.3.8%20mail%20queue/main.c)
#### 2.3.9 优先级消息队列
##### 概述
优先级消息队列相对消息队列来说,给消息附加了一个优先级的概念,较高优先级的消息会比较低优先级的消息更快地被其他任务收到(本质上,消息队列的底层数据容器是环形队列,优先级消息队列的底层数据容器是优先级队列)。
##### API讲解
##### 编程实例
1、在tos_config.h中配置优先级消息队列组件开关TOS_CFG_PRIORITY_MESSAGE_QUEUE_EN
`#define TOS_CFG_PRIORITY_MESSAGE_QUEUE_EN 1u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_RECEIVER 512
#define STK_SIZE_TASK_SENDER 512
#define MESSAGE_MAX 10
k_stack_t stack_task_receiver[STK_SIZE_TASK_RECEIVER];
k_stack_t stack_task_sender[STK_SIZE_TASK_SENDER];
uint8_t msg_pool[MESSAGE_MAX * sizeof(void *)];
k_task_t task_receiver;
k_task_t task_sender;
k_prio_msg_q_t prio_msg_q;
extern void entry_task_receiver(void *arg);
extern void entry_task_sender(void *arg);
void entry_task_receiver(void *arg)
{
k_err_t err;
void *msg_received;
while (K_TRUE) {
err = tos_prio_msg_q_pend(&prio_msg_q, &msg_received, TOS_TIME_FOREVER);
if (err == K_ERR_NONE) {
printf("receiver: msg incoming[%s]\n", (char *)msg_received);
}
}
}
void entry_task_sender(void *arg)
{
char *msg_prio_0 = "msg with priority 0";
char *msg_prio_1 = "msg with priority 1";
char *msg_prio_2 = "msg with priority 2";
printf("sender: post a message with priority 2\n");
tos_prio_msg_q_post(&prio_msg_q, msg_prio_2, 2);
printf("sender: post a message with priority 1\n");
tos_prio_msg_q_post(&prio_msg_q, msg_prio_1, 1);
printf("sender: post a message with priority 0\n");
tos_prio_msg_q_post(&prio_msg_q, msg_prio_0, 0);
}
int main(void)
{
board_init();
tos_knl_init();
tos_prio_msg_q_create(&prio_msg_q, msg_pool, MESSAGE_MAX);
(void)tos_task_create(&task_receiver, "receiver", entry_task_receiver, NULL,
5, stack_task_receiver, STK_SIZE_TASK_RECEIVER, 0);
(void)tos_task_create(&task_sender, "sender", entry_task_sender, NULL,
4, stack_task_sender, STK_SIZE_TASK_SENDER, 0);
tos_knl_start();
}
```
##### 运行效果
> sender: post a message with priority 2
> sender: post a message with priority 1
> sender: post a message with priority 0
> receiver: msg incoming[msg with priority 0]
> receiver: msg incoming[msg with priority 1]
> receiver: msg incoming[msg with priority 2]
[实例代码](code/2.3.9%20priority%20message%20queue/main.c)
#### 2.3.10 优先级邮箱队列
##### 概述
优先级邮箱队列相对邮箱队列来说,给邮件附加了一个优先级的概念,较高优先级的邮件会比较低优先级的邮件更快地被其他任务收到(本质上,邮箱队列的底层数据容器是环形队列,优先级邮箱队列的底层数据容器是优先级队列)。
##### API讲解
##### 编程实例
1、在tos_config.h中配置优先级邮箱队列组件开关TOS_CFG_PRIORITY_MAIL_QUEUE_EN
`#define TOS_CFG_PRIORITY_MAIL_QUEUE_EN 1u`
2、编写main.c示例代码
```c
/*
这里演示了优先级邮箱队列的使用从sender任务中的逻辑可以看出来依次post了三个mail优先级按时间顺序依次为2、1、0数值越高优先级越低。如果是传统的邮箱队列那个receiver应该是依次收到优先级为2、1、0的邮件但这是优先级邮箱队列因而receiver会按优先级顺序收到这三个邮件也就是依次收到优先级为0、1、2的邮件。
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_RECEIVER 512
#define STK_SIZE_TASK_SENDER 512
#define MAIL_MAX 10
k_stack_t stack_task_receiver[STK_SIZE_TASK_RECEIVER];
k_stack_t stack_task_sender[STK_SIZE_TASK_SENDER];
typedef struct mail_st {
char *message;
int payload;
} mail_t;
uint8_t mail_pool[MAIL_MAX * sizeof(mail_t)];
k_task_t task_receiver;
k_task_t task_sender;
k_prio_mail_q_t prio_mail_q;
extern void entry_task_receiver(void *arg);
extern void entry_task_sender(void *arg);
void entry_task_receiver(void *arg)
{
k_err_t err;
mail_t mail;
size_t mail_size;
while (K_TRUE) {
err = tos_prio_mail_q_pend(&prio_mail_q, &mail, &mail_size, TOS_TIME_FOREVER);
if (err == K_ERR_NONE) {
TOS_ASSERT(mail_size == sizeof(mail_t));
printf("receiver: msg incoming[%s], payload[%d]\n", mail.message, mail.payload);
}
}
}
void entry_task_sender(void *arg)
{
mail_t mail_0, mail_1, mail_2;
printf("sender: post a mail with priority 2\n");
mail_2.message = "priority 2";
mail_2.payload = 2;
tos_prio_mail_q_post(&prio_mail_q, &mail_2, sizeof(mail_t), 2);
printf("sender: post a mail with priority 1\n");
mail_1.message = "priority 1";
mail_1.payload = 1;
tos_prio_mail_q_post_all(&prio_mail_q, &mail_1, sizeof(mail_t), 1);
printf("sender: post a mail with priority 0\n");
mail_0.message = "priority 0";
mail_0.payload = 0;
tos_prio_mail_q_post(&prio_mail_q, &mail_0, sizeof(mail_t), 0);
}
int main(void)
{
board_init();
tos_knl_init();
tos_prio_mail_q_create(&prio_mail_q, mail_pool, MAIL_MAX, sizeof(mail_t));
(void)tos_task_create(&task_receiver, "receiver", entry_task_receiver, NULL,
6, stack_task_receiver, STK_SIZE_TASK_RECEIVER, 0);
(void)tos_task_create(&task_sender, "sender", entry_task_sender, NULL,
5, stack_task_sender, STK_SIZE_TASK_SENDER, 0);
tos_knl_start();
}
```
##### 运行效果
> sender: post a mail with priority 2
> sender: post a mail with priority 1
> sender: post a mail with priority 0
> receiver: msg incoming[priority 0], payload[0]
> receiver: msg incoming[priority 1], payload[1]
> receiver: msg incoming[priority 2], payload[2]
[实例代码](code/2.3.10%20priority%20mail%20queue/main.c)
### 2.4 内存管理
#### 2.4.1 动态内存
##### 概述
动态内存管理模块,提供了一套动态管理系统内存的机制,支持用户动态的申请、释放不定长内存块。
##### API讲解
##### 编程实例
1、在tos_config.h中配置动态内存组件开关TOS_CFG_MMHEAP_EN
`#define TOS_CFG_MMHEAP_EN 1u`
2、在tos_config.h中配置动态内存池大小
`#define TOS_CFG_MMHEAP_POOL_SIZE 0x2000`
3、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
extern void entry_task_demo(void *arg);
void entry_task_demo(void *arg)
{
void *p = K_NULL, *p_aligned = K_NULL;
int i = 0;
while (K_TRUE) {
if (i == 1) {
p = tos_mmheap_alloc(0x30);
if (p) {
printf("alloc: %x\n", (cpu_addr_t)p);
}
} else if (i == 2) {
if (p) {
printf("free: %x\n", p);
tos_mmheap_free(p);
}
} else if (i == 3) {
p = tos_mmheap_alloc(0x30);
if (p) {
printf("alloc: %x\n", (cpu_addr_t)p);
}
} else if (i == 4) {
p_aligned = tos_mmheap_aligned_alloc(0x50, 16);
if (p_aligned) {
printf("aligned alloc: %x\n", (cpu_addr_t)p_aligned);
if ((cpu_addr_t)p_aligned % 16 == 0) {
printf("%x is 16 aligned\n", (cpu_addr_t)p_aligned);
} else {
printf("should not happen\n");
}
}
} else if (i == 5) {
p = tos_mmheap_realloc(p, 0x40);
if (p) {
printf("realloc: %x\n", (cpu_addr_t)p);
}
} else if (i == 6) {
if (p) {
tos_mmheap_free(p);
}
if (p_aligned) {
tos_mmheap_free(p_aligned);
}
}
tos_task_delay(1000);
++i;
}
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "receiver_higher_prio", entry_task_demo, NULL,
4, stack_task_demo, STK_SIZE_TASK_DEMO, 0);
tos_knl_start();
}
```
##### 运行效果
> alloc: 20000c8c
> free: 20000c8c
> alloc: 20000c8c
> aligned alloc: 20000cc0
> 20000cc0 is 16 aligned
> realloc: 20000d14
[实例代码](code/2.4.1%20mmheap/main.c)
#### 2.4.2 静态内存
##### 概述
静态内存管理模块,提供了一套管理静态内存块的机制,支持用户申请、释放定长的内存块。
##### API讲解
创建静态内存池接口:
```c
k_err_t tos_mmblk_pool_create(k_mmblk_pool_t *mbp, void *pool_start, size_t blk_num, size_t blk_size);
```
这里详细讲解此api参数意义
- mbp
静态内存池句柄。
- pool_start
静态内存池起始地址。
- blk_num
内存池将要划分的内存块个数。
- blk_size
每个内存块的大小。
##### 编程实例
1、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
#define MMBLK_BLK_NUM 5
#define MMBLK_BLK_SIZE 0x20
k_mmblk_pool_t mmblk_pool;
// 需要管理的静态内存池
uint8_t mmblk_pool_buffer[MMBLK_BLK_NUM * MMBLK_BLK_SIZE];
// 记录从内存池中分配到的地址
void *p[MMBLK_BLK_NUM] = { K_NULL };
extern void entry_task_demo(void *arg);
void entry_task_demo(void *arg)
{
void *p_dummy = K_NULL;
k_err_t err;
int i = 0;
printf("mmblk_pool has %d blocks, size of each block is 0x%x\n", 5, 0x20);
// 从内存池中获取所有的block
for (; i < MMBLK_BLK_NUM; ++i) {
err = tos_mmblk_alloc(&mmblk_pool, &p[i]);
if (err == K_ERR_NONE) {
printf("%d block alloced: 0x%x\n", i, p[i]);
} else {
printf("should not happen\n");
}
}
// 前文逻辑已经将所有可用block分配完毕继续分配会返回K_ERR_MMBLK_POOL_EMPTY错误码
err = tos_mmblk_alloc(&mmblk_pool, &p_dummy);
if (err == K_ERR_MMBLK_POOL_EMPTY) {
printf("blocks exhausted, all blocks is alloced\n");
} else {
printf("should not happen\n");
}
// 将前文分配得到的所有block归还到池中
for (i = 0; i < MMBLK_BLK_NUM; ++i) {
err = tos_mmblk_free(&mmblk_pool, p[i]);
if (err != K_ERR_NONE) {
printf("should not happen\n");
}
}
// 前文的归还动作中已经将所有的block归还到池中继续规范会返回K_ERR_MMBLK_POOL_FULL错误码
err = tos_mmblk_free(&mmblk_pool, p[0]);
if (err == K_ERR_MMBLK_POOL_FULL) {
printf("pool is full\n");
} else {
printf("should not happen\n");
}
}
int main(void)
{
board_init();
tos_knl_init();
// 创建静态内存池
tos_mmblk_pool_create(&mmblk_pool, mmblk_pool_buffer, MMBLK_BLK_NUM, MMBLK_BLK_SIZE);
(void)tos_task_create(&task_demo, "receiver_higher_prio", entry_task_demo, NULL,
4, stack_task_demo, STK_SIZE_TASK_DEMO, 0);
tos_knl_start();
}
```
##### 运行效果
> mmblk_pool has 5 blocks, size of each block is 0x20
> 0 block alloced: 0x20000974
> 1 block alloced: 0x20000994
> 2 block alloced: 0x200009b4
> 3 block alloced: 0x200009d4
> 4 block alloced: 0x200009f4
> blocks exhausted, all blocks is alloced
> pool is full
[实例代码](code/2.4.2%20mmblk/main.c)
### 2.5 时间管理
#### 概述
时间管理,提供了一族与时间相关的函数,可以获取/设置系统时钟滴答数systick、systick与毫秒单位之间互相转化、按毫秒、墙上时钟等单位进行任务睡眠的功能。
#### API讲解
#### 编程实例
1、配置每秒钟的系统滴答数TOS_CFG_CPU_TICK_PER_SECOND
`#define TOS_CFG_CPU_TICK_PER_SECOND 1000u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
extern void entry_task_demo(void *arg);
void entry_task_demo(void *arg)
{
k_time_t ms;
k_tick_t systick, after_systick;
// 因为TOS_CFG_CPU_TICK_PER_SECOND为1000也就是一秒钟会有1000个systick因此1000个systick等于1000毫秒。
systick = tos_millisec2tick(2000);
printf("%d millisec equals to %lld ticks\n", 2000, systick);
ms = tos_tick2millisec(1000);
printf("%lld ticks equals to %d millisec\n", (k_tick_t)1000, ms);
systick = tos_systick_get();
printf("before sleep, systick is %lld\n", systick);
tos_msleep(2000);
after_systick = tos_systick_get();
printf("after sleep %d ms, systick is %lld\n", 2000, after_systick);
printf("milliseconds sleep is about: %d\n", tos_ticks2millisec(after_systick - systick));
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "receiver_higher_prio", entry_task_demo, NULL,
4, stack_task_demo, STK_SIZE_TASK_DEMO, 0);
tos_knl_start();
}
```
#### 运行效果
> 2000 millisec equals to 2000 ticks
> 1000 ticks equals to 1000 millisec
> before sleep, systick is 7
> after sleep 2000 ms, systick is 2009
> milliseconds sleep is about: 2002
[实例代码](code/2.5%20time/main.c)
### 2.6 软件定时器
#### 概述
软件定时器提供了一套从软件层次实现的定时器机制,相对应的概念是硬件定时器。用户可以创建一系列的软件定时器,并指定软件定时器到期的条件以及执行回调,当软件定时器到期时会执行注册的回调。
通常来说,用户注册的软件定时器回调中很可能包含延迟动作或同步等待操作,或者回调函数本身逻辑复杂执行耗时较长,因此系统将软件定时器管理逻辑设计成一个任务,在这个任务中扫描定时器是否过期并执行定时器回调。但是如你所知,创建一个任务是需要消耗系统内存资源的(任务的栈、任务句柄本身的内存空间等等),而如果用户注册的软件定时器回调中并不包含延迟动作也不包含同步等待操作,或者回调本身执行耗时很短,这种情况下软件定时器管理逻辑无需被设计成任务,而是可以被设计成时钟中断中被调用的一个函数。当软件定时器管理逻辑被设计成一个函数时,就可以节省创建任务所需的资源。
系统默认采用的实现是将定时器管理逻辑设计为任务当用户的定时器回调都是耗时极短的操作时用户可以通过将软件定时器管理逻辑配置为函数来节省内存资源。通过在tos_config.h中打开TOS_CFG_TIMER_AS_PROC开关来讲软件定时器管理逻辑配置为函数
`#define TOS_CFG_TIMER_AS_PROC 1u`
#### API讲解
```c
k_err_t tos_timer_create(k_timer_t *tmr,
k_tick_t delay,
k_tick_t period,
k_timer_callback_t callback,
void *cb_arg,
k_opt_t opt)
```
这里详细讲解此api参数意义
- tmr
软件定时器句柄。
- delay
该定时器延迟多久后执行。
- period
一个定时器的执行周期。
- callback
定时器到期后的执行回调。
- cb_arg
执行回调的入参。
- opt
此opt的传入主要是界定tmr的属性如果传入的是TOS_OPT_TIMER_ONESHOT表明此tmr是一次性的当delay时间到期tmr的执行回调调用完毕后此tmr生命周期就结束了如果传入的是TOS_OPT_TIMER_PERIODIC表明此tmr是周期性定时器当tmr定时时间到期tmr的执行回调调用完毕后系统会重新按period参数为到期时间将tmr加入到定时队列开启下一个周期。
#### 编程实例
1、在tos_config.h中配置软件定时器组件开关TOS_CFG_TIMER_EN
`#define TOS_CFG_TIMER_EN 1000u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
extern void entry_task_demo(void *arg);
void oneshot_timer_cb(void *arg)
{
printf("this is oneshot timer callback, current systick: %lld\n", tos_systick_get());
}
void periodic_timer_cb(void *arg)
{
printf("this is periodic timer callback, current systick: %lld\n", tos_systick_get());
}
void entry_task_demo(void *arg)
{
k_timer_t oneshot_tmr;
k_timer_t periodic_tmr;
// 这是一个一次性的timer且超时时间是3000个tick之后
tos_timer_create(&oneshot_tmr, 3000, 0, oneshot_timer_cb, K_NULL, TOS_OPT_TIMER_ONESHOT);
// 这是一个周期性的timer第一次超时时间是2000个tick之后之后按3000个tick为周期执行回调
tos_timer_create(&periodic_tmr, 2000, 3000, periodic_timer_cb, K_NULL, TOS_OPT_TIMER_PERIODIC);
printf("current systick: %lld\n", tos_systick_get());
tos_timer_start(&oneshot_tmr);
tos_timer_start(&periodic_tmr);
while (K_TRUE) {
tos_task_delay(1000);
}
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "receiver_higher_prio", entry_task_demo, NULL,
4, stack_task_demo, STK_SIZE_TASK_DEMO, 0);
tos_knl_start();
}
```
#### 运行效果
> current systick: 0
> this is periodic timer callback, current systick: 2001
> this is oneshot timer callback, current systick: 3001
> this is periodic timer callback, current systick: 5001
> this is periodic timer callback, current systick: 8001
> this is periodic timer callback, current systick: 11001
> this is periodic timer callback, current systick: 14001
[实例代码](code/2.6%20timer/main.c)
### 2.7 时间片轮转机制
#### 概述
TencentOS tiny操作系统内核是一个抢占式内核抢占式内核的特点是如果最高优先级的任务不放弃CPU调用tos_task_delay、tos_task_yeild等主动放权或者任务间同步通信机制的pend接口等那么CPU将会一直被此任务独占。
假设这样一种场景系统中包含多个同等优先级的任务且这几个任务体中都没有放弃CPU的行为则会出现的情况是这几个任务始终只有第一个被得到调度的那个在运行因为第一个得到调度的任务体中不会主动放弃CPU而其他任务优先级上与其相等无法抢占。此种场景下其他任务会因得不到CPU而陷入饥饿状态。
时间片轮转机制提供了按时间片占用调度的策略,可以解决上述场景下的任务饥饿问题。
#### API讲解
#### 编程实例
1、在tos_config.h中配置时间片轮转组件开关TOS_CFG_ROUND_ROBIN_EN
`#define TOS_CFG_ROUND_ROBIN_EN 1u`
2、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
#define STK_SIZE_TASK_SAMPLE 512
/*
此代码中创建了两个同等优先级PRIO_TASK_DEMO的任务task_demo1、task_demo2两个任务体中做的操作是不断对各自的计数器demo1_counter、demo2_counter做自增操作没有放弃CPU的操作时间片分别为timeslice_demo1、timeslice_demo2。
同时创建了一个优先级比task_demo1、task_demo2较高的采样任务task_sample此任务不间歇的对两个计数器进行采样。在开启时间片轮转的情况下task_demo1、task_demo2得到运行的时间比例应该是timeslice_demo1与timeslice_demo2的比例那么demo1_counter和demo2_counter值的比例应该也差不多是timeslice_demo1与timeslice_demo2的比例。
*/
// task_demo1和task_demo2的优先级
#define PRIO_TASK_DEMO 4
// 采样任务的优先级
#define PRIO_TASK_SAMPLE (PRIO_TASK_DEMO - 1)
// task_demo1的时间片在tos_task_create时传入
const k_timeslice_t timeslice_demo1 = 10;
// task_demo2的时间片在tos_task_create时传入
const k_timeslice_t timeslice_demo2 = 20;
k_stack_t stack_task_demo1[STK_SIZE_TASK_DEMO];
k_stack_t stack_task_demo2[STK_SIZE_TASK_DEMO];
k_stack_t stack_task_sample[STK_SIZE_TASK_SAMPLE];
k_task_t task_demo1;
k_task_t task_demo2;
k_task_t task_sample;
extern void entry_task_demo1(void *arg);
extern void entry_task_demo2(void *arg);
extern void entry_task_sample(void *arg);
uint64_t demo1_counter = 0;
uint64_t demo2_counter = 0;
void entry_task_demo1(void *arg)
{
while (K_TRUE) {
++demo1_counter;
}
}
void entry_task_demo2(void *arg)
{
while (K_TRUE) {
++demo2_counter;
}
}
void entry_task_sample(void *arg)
{
while (K_TRUE) {
++demo2_counter;
printf("demo1_counter: %lld\n", demo1_counter);
printf("demo2_counter: %lld\n", demo2_counter);
printf("demo2_counter / demo1_counter = %f\n",
(double)demo2_counter / demo1_counter);
printf("should almost equals to:\n");
printf("timeslice_demo2 / timeslice_demo1 = %f\n\n", (double)timeslice_demo2 / timeslice_demo1);
tos_task_delay(1000);
}
}
int main(void)
{
board_init();
tos_knl_init();
// 配置robin机制参数
tos_robin_default_timeslice_config((k_timeslice_t)500u);
(void)tos_task_create(&task_demo1, "demo1", entry_task_demo1, NULL,
PRIO_TASK_DEMO, stack_task_demo1, STK_SIZE_TASK_DEMO,
timeslice_demo1);
(void)tos_task_create(&task_demo2, "demo2", entry_task_demo2, NULL,
PRIO_TASK_DEMO, stack_task_demo2, STK_SIZE_TASK_DEMO,
timeslice_demo2);
(void)tos_task_create(&task_sample, "sample", entry_task_sample, NULL,
PRIO_TASK_SAMPLE, stack_task_sample, STK_SIZE_TASK_SAMPLE,
0);
tos_knl_start();
}
```
#### 运行效果
> demo1_counter: 0
> demo2_counter: 1
> demo2_counter / demo1_counter = 0.000000
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 1915369
> demo2_counter: 3720158
> demo2_counter / demo1_counter = 1.942267
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 3774985
> demo2_counter: 7493508
> demo2_counter / demo1_counter = 1.985043
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 5634601
> demo2_counter: 11266858
> demo2_counter / demo1_counter = 1.999584
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 7546896
> demo2_counter: 14987015
> demo2_counter / demo1_counter = 1.985852
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 9406512
> demo2_counter: 18759340
> demo2_counter / demo1_counter = 1.994293
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 11266128
> demo2_counter: 22531664
> demo2_counter / demo1_counter = 1.999947
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 13177398
> demo2_counter: 26251821
> demo2_counter / demo1_counter = 1.992185
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 15037014
> demo2_counter: 30023632
> demo2_counter / demo1_counter = 1.996649
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 16896630
> demo2_counter: 33795443
> demo2_counter / demo1_counter = 2.000129
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
>
> demo1_counter: 18807900
> demo2_counter: 37515600
> demo2_counter / demo1_counter = 1.994672
> should almost equals to:
> timeslice_demo2 / timeslice_demo1 = 2.000000
[实例代码](code/2.7%20robin/main.c)
### 2.8 内核基础组件
#### 2.8.1 环形队列
##### 概述
环形队列本质上就是支持先入先出操作的环形buffer是系统的一个基础组件通常用来作为实现上层机制的底层数据容器。
##### API讲解
##### 编程实例
1、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
#define PRIO_TASK_DEMO 4
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
typedef struct item_st {
int a;
int b;
int c;
} item_t;
#define RING_QUEUE_ITEM_MAX 5
uint8_t ring_q_buffer[RING_QUEUE_ITEM_MAX * sizeof(item_t)];
k_ring_q_t rinq_q;
void entry_task_demo(void *arg)
{
k_err_t err;
int i = 0;
item_t item;
size_t item_size;
tos_ring_q_create(&rinq_q, ring_q_buffer, RING_QUEUE_ITEM_MAX, sizeof(item_t));
for (i = 0; i < RING_QUEUE_ITEM_MAX; ++i) {
printf("enqueue: %d %d %d\n", i, i, i);
item.a = i;
item.b = i;
item.c = i;
err = tos_ring_q_enqueue(&rinq_q, &item, sizeof(item_t));
if (err != K_ERR_NONE) {
printf("should never happen\n");
}
}
err = tos_ring_q_enqueue(&rinq_q, &item, sizeof(item_t));
if (err == K_ERR_RING_Q_FULL) {
printf("ring queue is full: %s\n", tos_ring_q_is_full(&rinq_q) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
for (i = 0; i < RING_QUEUE_ITEM_MAX; ++i) {
err = tos_ring_q_dequeue(&rinq_q, &item, &item_size);
if (err == K_ERR_NONE) {
printf("dequeue: %d %d %d\n", item.a, item.b, item.c);
} else {
printf("should never happen\n");
}
}
err = tos_ring_q_dequeue(&rinq_q, &item, &item_size);
if (err == K_ERR_RING_Q_EMPTY) {
printf("ring queue is empty: %s\n", tos_ring_q_is_empty(&rinq_q) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "demo", entry_task_demo, NULL,
PRIO_TASK_DEMO, stack_task_demo, STK_SIZE_TASK_DEMO,
0);
tos_knl_start();
}
```
##### 运行效果
> enqueue: 0 0 0
> enqueue: 1 1 1
> enqueue: 2 2 2
> enqueue: 3 3 3
> enqueue: 4 4 4
> ring queue is full: TRUE
> dequeue: 0 0 0
> dequeue: 1 1 1
> dequeue: 2 2 2
> dequeue: 3 3 3
> dequeue: 4 4 4
> ring queue is empty: TRUE
[实例代码](code/2.8.1%20ring%20queue/main.c)
#### 2.8.2 字符流先入先出队列
##### 概述
字符流先入先出队列,提供的是一个面向字符操作的环形队列实现,提供了基本的字符流入队出队操作。本质上就是环形队列中元素为字符(单字节长度)时的特例,实际上字符流先出先出队列底层的实现就是环形队列。
##### API讲解
##### 编程实例
1、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
#define PRIO_TASK_DEMO 4
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
#define FIFO_BUFFER_SIZE 5
uint8_t fifo_buffer[FIFO_BUFFER_SIZE];
k_chr_fifo_t fifo;
extern void entry_task_demo(void *arg);
void char_push(void)
{
k_err_t err;
int i = 0;
uint8_t data;
// 往fifo中压入FIFO_BUFFER_SIZE个字符分别是a、b、c、d、e
for (i = 0; i < FIFO_BUFFER_SIZE; ++i) {
printf("char pushed: %c\n", 'a' + i);
err = tos_chr_fifo_push(&fifo, 'a' + i);
if (err != K_ERR_NONE) {
printf("should never happen\n");
}
}
// fifo最多包含FIFO_BUFFER_SIZE个字符上文逻辑中已经压入了最大的字符量此时继续压入字符会返回K_ERR_FIFO_FULLfifo已满
err = tos_chr_fifo_push(&fifo, 'z');
if (err == K_ERR_RING_Q_FULL) {
printf("fifo is full: %s\n", tos_chr_fifo_is_full(&fifo) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
// 从fifo中把所有的字符都弹出来
for (i = 0; i < FIFO_BUFFER_SIZE; ++i) {
err = tos_chr_fifo_pop(&fifo, &data);
if (err == K_ERR_NONE) {
printf("%d pop: %c\n", i, data);
} else {
printf("should never happen\n");
}
}
// 此时继续弹出字符会返回K_ERR_FIFO_EMPTYfifo已空
err = tos_chr_fifo_pop(&fifo, &data);
if (err == K_ERR_RING_Q_EMPTY) {
printf("fifo is empty: %s\n", tos_chr_fifo_is_empty(&fifo) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
}
void stream_push(void)
{
int count = 0, i = 0;
uint8_t stream[FIFO_BUFFER_SIZE] = { 'a', 'b', 'c', 'd', 'e' };
uint8_t stream_dummy[1] = { 'z' };
uint8_t stream_pop[FIFO_BUFFER_SIZE];
// 压入字符流字符流的长度是5不超过fifo的最大长度FIFO_BUFFER_SIZE会压入成功并返回压入字符流的长度5
count = tos_chr_fifo_push_stream(&fifo, &stream[0], FIFO_BUFFER_SIZE);
if (count != FIFO_BUFFER_SIZE) {
printf("should never happen\n");
}
// 继续压入字符流即使是长度为1的字符流因fifo已满无法继续压入返回长度0压入失败
count = tos_chr_fifo_push_stream(&fifo, &stream_dummy[0], 1);
if (count == 0) {
printf("fifo is full: %s\n", tos_chr_fifo_is_full(&fifo) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
// 将前文中压入的字符流全部弹出返回前文压入的字符流长度5弹出的字符流长度
count = tos_chr_fifo_pop_stream(&fifo, &stream_pop[0], FIFO_BUFFER_SIZE);
if (count == FIFO_BUFFER_SIZE) {
printf("stream popped:\n");
for (i = 0; i < FIFO_BUFFER_SIZE; ++i) {
printf("%c", stream_pop[i]);
}
printf("\n");
} else {
printf("should never happen\n");
}
// 继续弹出因fifo已空返回0
count = tos_chr_fifo_pop_stream(&fifo, &stream_pop[0], 1);
if (count == 0) {
printf("fifo is empty: %s\n", tos_chr_fifo_is_empty(&fifo) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
}
void entry_task_demo(void *arg)
{
// 创建了一个最多包含FIFO_BUFFER_SIZE个字符的fifo
tos_chr_fifo_create(&fifo, &fifo_buffer[0], FIFO_BUFFER_SIZE);
printf("fifo, dealing with char\n");
char_push();
printf("fifo, dealing with stream\n");
stream_push();
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "demo", entry_task_demo, NULL,
PRIO_TASK_DEMO, stack_task_demo, STK_SIZE_TASK_DEMO,
0);
tos_knl_start();
}
```
##### 运行效果
> fifo, dealing with char
> char pushed: a
> char pushed: b
> char pushed: c
> char pushed: d
> char pushed: e
> fifo is full: TRUE
> 0 pop: a
> 1 pop: b
> 2 pop: c
> 3 pop: d
> 4 pop: e
> fifo is empty: TRUE
> fifo, dealing with stream
> fifo is full: TRUE
> stream popped:
> abcde
> fifo is empty: TRUE
[实例代码](code/2.8.2%20char%20fifo/main.c)
#### 2.8.3 二项堆
##### 概述
此组件用来内部实现优先级队列,不推荐用户使用。
#### 2.8.4 优先级队列
##### 概述
提供了基于优先级的队列管理。环形队列的入队出队规则是先入队的先出队first in, first out优先级队列的出队顺序是按照优先级来的优先级较高的元素先出队。
##### API讲解
##### 编程实例
1、编写main.c示例代码
```c
/*
此案例展示了优先级队列的出队规则依次入队优先级为5、4、3、2、1的元素出队时的顺序是按照优先级来的也就是按优先级从高到低数值越大优先级越小依次出队优先级为1、2、3、4、5元素。
*/
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
#define PRIO_TASK_DEMO 4
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
typedef struct item_st {
int a;
int b;
int c;
} item_t;
#define PRIO_QUEUE_ITEM_MAX 5
uint8_t ring_q_buffer[PRIO_QUEUE_ITEM_MAX * sizeof(item_t)];
uint8_t mgr_pool[TOS_PRIO_Q_MGR_ARRAY_SIZE(PRIO_QUEUE_ITEM_MAX)];
k_prio_q_t prio_q;
void entry_task_demo(void *arg)
{
k_err_t err;
int i = 0;
item_t item;
k_prio_t prio;
size_t item_size;
tos_prio_q_create(&prio_q, mgr_pool, ring_q_buffer, PRIO_QUEUE_ITEM_MAX, sizeof(item_t));
for (i = PRIO_QUEUE_ITEM_MAX; i > 0; --i) {
printf("enqueue: %d %d %d\n", i, i, i);
item.a = i;
item.b = i;
item.c = i;
err = tos_prio_q_enqueue(&prio_q, &item, sizeof(item_t), i);
if (err != K_ERR_NONE) {
printf("should never happen\n");
}
}
err = tos_prio_q_enqueue(&prio_q, &item, sizeof(item_t), i);
if (err == K_ERR_PRIO_Q_FULL) {
printf("priority queue is full: %s\n", tos_prio_q_is_full(&prio_q) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
for (i = 0; i < PRIO_QUEUE_ITEM_MAX; ++i) {
err = tos_prio_q_dequeue(&prio_q, &item, &item_size, &prio);
if (err == K_ERR_NONE) {
printf("dequeue: %d %d %d, prio: %d\n", item.a, item.b, item.c, prio);
} else {
printf("should never happen\n");
}
}
err = tos_prio_q_dequeue(&prio_q, &item, &item_size, &prio);
if (err == K_ERR_PRIO_Q_EMPTY) {
printf("priority queue is empty: %s\n", tos_prio_q_is_empty(&prio_q) ? "TRUE" : "FALSE");
} else {
printf("should never happen\n");
}
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "demo", entry_task_demo, NULL,
PRIO_TASK_DEMO, stack_task_demo, STK_SIZE_TASK_DEMO,
0);
tos_knl_start();
}
```
##### 运行效果
> enqueue: 5 5 5
> enqueue: 4 4 4
> enqueue: 3 3 3
> enqueue: 2 2 2
> enqueue: 1 1 1
> priority queue is full: TRUE
> dequeue: 1 1 1, prio: 1
> dequeue: 2 2 2, prio: 2
> dequeue: 3 3 3, prio: 3
> dequeue: 4 4 4, prio: 4
> dequeue: 5 5 5, prio: 5
> priority queue is empty: TRUE
[实例代码](code/2.8.4%20priority%20queue/main.c)
### 2.9 功耗管理
#### 2.9.1 低功耗
##### 概述
TencentOS tiny提供了多级低功耗管理框架。初级低功耗的方案是当系统处于“空闲”状态也即进入idle任务时系统调用处理器目前支持的架构是arm v7m低功耗接口进入短暂的睡眠模式。
##### API讲解
##### 编程实例
对于初级低功耗模式无需用户编写任何代码直接通过在tos_config.h打开TOS_CFG_PMR_MGR_EN开关即可
`#define TOS_CFG_PWR_MGR_EN 1u`
##### 运行效果
#### 2.9.2 tickless
##### 概述
TencentOS tiny的tickless机制提供了一套非周期性时钟的方案在系统无需systick驱动调度的情况下停掉systick。
初级功耗管理方案下因为还有系统systick的存在因此系统进入idle任务后并不会在睡眠模式下停留太久。要想进入到更极致的低功耗状态需要暂停systick。
arm架构提供三级低功耗模式sleep、stop、standby模式三种模式运行功耗逐次降低standby模式最低。TencentOS tiny的内核提供了简洁清晰的接口来管理各级模式。
##### API讲解
```c
void tos_tickless_wkup_alarm_install(k_cpu_lpwr_mode_t mode, k_tickless_wkup_alarm_t *wkup_alarm);
```
此接口用以安装各低功耗模式下的唤醒闹钟。当内核进入tickless模式下后systick以及停止了因此需要其他计时器来将CPU从低功耗模式下唤醒。
根据arm v7m的芯片规格三种模式下的唤醒源分别为
- sleep
CPU进入sleep模式后可以由systick、硬件timer、RTC时钟唤醒wakeup/alarm中断
- stop
CPU进入stop模式后可以由RTC时钟wakeup/alarm中断唤醒。
- standby
CPU进入standby模式后只可由RTC时钟的alarm中断唤醒还可以通过外部管脚唤醒但这不属于TencentOS tiny内核机制设计的范畴
k_tickless_wkup_alarm_t定义如下
```c
typedef struct k_tickless_wakeup_alarm_st {
int (*init)(void);
int (*setup)(k_time_t millisecond);
int (*dismiss)(void);
k_time_t (*max_delay)(void); /* in millisecond */
} k_tickless_wkup_alarm_t;
```
一个唤醒闹钟有四个成员方法:
- init
闹钟初始化函数。
- setup
闹钟设定函数入参为闹钟到期时间单位毫秒。此闹钟在设定完毕后的millisecond毫秒时来中断。
- dismiss
闹钟解除函数,执行完后闹钟中断不会再来。
- max_delay
此闹钟最长的到期时间(单位为毫秒)。
```c
k_err_t tos_tickless_wkup_alarm_init(k_cpu_lpwr_mode_t mode);
```
此函数用来初始化特定模式下的唤醒闹钟实际上调用的是tos_tickless_wkup_alarm_install接口中安装的k_tickless_wkup_alarm_t的init方法
```c
k_err_t tos_pm_cpu_lpwr_mode_set(k_cpu_lpwr_mode_t cpu_lpwr_mode);
```
设置内核在tickless模式下进入的CPU低功耗模式。
##### 编程实例
1、在tos_config.h中配置低功耗组件开关TOS_CFG_PWR_MGR_EN
`#define TOS_CFG_PWR_MGR_EN 1u`
2、在tos_config.h中配置tickless组件开关TOS_CFG_TICKLESS_EN
`#define TOS_CFG_TICKLESS_EN 1u`
3、编写main.c示例代码
```c
#include "tos_k.h"
#include "mcu_init.h"
#define STK_SIZE_TASK_DEMO 512
#define PRIO_TASK_DEMO 4
k_stack_t stack_task_demo[STK_SIZE_TASK_DEMO];
k_task_t task_demo;
extern void entry_task_demo(void *arg);
void timer_callback(void *arg)
{
printf("timer callback: %lld\n", tos_systick_get());
}
void entry_task_demo(void *arg)
{
k_timer_t tmr;
// 创建一个软件定时器每6000个tick触发一次
tos_timer_create(&tmr, 0u, 6000u, timer_callback, K_NULL, TOS_OPT_TIMER_PERIODIC);
tos_timer_start(&tmr);
// 此任务体内每3000个tick运行一次
while (K_TRUE) {
printf("entry task demo: %lld\n", tos_systick_get());
tos_task_delay(3000);
}
}
int main(void)
{
board_init();
tos_knl_init();
(void)tos_task_create(&task_demo, "demo1", entry_task_demo, NULL,
PRIO_TASK_DEMO, stack_task_demo, STK_SIZE_TASK_DEMO,
0);
tos_knl_start();
}
```
4、实现tos_bsp_tickless_setup回调参考board\TOS_tiny_EVK_STM32L431CBT6\BSP\Src\tickless\bsp_pwr_mgr.c、board\TOS_tiny_EVK_STM32L431CBT6\BSP\Src\tickless\bsp_tickless_alarm.c
```c
#include "tos_k.h"
#include "tickless/bsp_pm_device.h"
#include "tickless/bsp_tickless_alarm.h"
int tos_bsp_tickless_setup(void)
{
#if TOS_CFG_TICKLESS_EN > 0u
// sleep模式下的唤醒源基本定时器
tos_tickless_wkup_alarm_install(TOS_LOW_POWER_MODE_SLEEP, &tickless_wkup_alarm_tim);
// 初始化唤醒源闹钟
tos_tickless_wkup_alarm_init(TOS_LOW_POWER_MODE_SLEEP);
// 设置tickless状态时进入sleep模式
tos_pm_cpu_lpwr_mode_set(TOS_LOW_POWER_MODE_SLEEP);
#endif
}
```
5、为了观察在tickless时是否确实没有systick中断在tos_sys.c的idle任务体内加一句调试代码
```c
__STATIC__ void knl_idle_entry(void *arg)
{
arg = arg; // make compiler happy
while (K_TRUE) {
// 这里在idle任务体内加上一句打印如果systick正常开启在没有用户任务运行时此调试信息会不断打印如果是tickless状态此调试信息应该只会第一次进入idle任务时或在用户任务等待到期或用户的软件定时器到期时才打印一次。
printf("idle entry: %lld\n", tos_systick_get());
#if TOS_CFG_PWR_MGR_EN > 0u
pm_power_manager();
#endif
}
}
```
##### 运行效果
> entry task demo: 0
> idle entry: 2
> entry task demo: 3002
> idle entry: 3002
> timer callback: 6000
> idle entry: 6000
> entry task demo: 6002
> idle entry: 6002
> entry task demo: 9002
> idle entry: 9002
> timer callback: 12000
> idle entry: 12000
> entry task demo: 12002
> idle entry: 12002
> entry task demo: 15002
> idle entry: 15002
> timer callback: 18000
> idle entry: 18000
> entry task demo: 18002
> idle entry: 18002
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