单片机按键处理框架

写过一段时间单片机程序，也看了一些单片机程序，书上的，网上的，基本都是非常原始的读取按键，延时判断，这些按键相关代码穿插于整个程序，着实不够美观，最重要的是不能复用，so俺就想做个按键框架，只需提供按键处理代码即可，言归正传，先简介一下几个文件，ringfifo.c提供了一个简单的环形缓冲队列，用以通知按键消息，key.c 实现的按键的框架处理(读取按键,调用按键处理函数），key_port.c 需提供底层硬件接口及用户的按键处理函数，目前支持的按键消息类型有4类：keyDown,keyRelease,longPress, double click.

key.h中提供了4个函数:InitKey()为初始化, KeyProc() 须在主循环中调用,KeyScan()须定时(10-20ms)调用，SetKeyHandler()用来设置按键处理函数

#ifndef __KEY_H__
#define __KEY_H__

#define NULL 0

typedef enum{
    KEY_EVENT_DOWN = 0,
    KEY_EVENT_UP,
    KEY_EVENT_LONGPRESS,
    KEY_EVENT_DOUBLECLICK,
    KEY_EVENT_COMBO_KEYDOWN,
}KeyEventType;

typedef void (*pKeyEventCB)(void *para);

typedef struct _tagKeyInfo
{
    unsigned char keyCode;
    unsigned char keyStatus;
    unsigned char comboKeyFlag;
    unsigned int keyDbClickTime;    
    unsigned int keyDownTime;
    unsigned int keyRepeatTime;
    pKeyEventCB FuncCB[5]; 
    void * para[5];    
}KeyInfo;

typedef struct _tagMessageInfo
{
    unsigned int keyEvent;
    unsigned int keyCode;
    KeyInfo* pContext;
}MessageInfo;



void InitKey(void);        // 

void KeyProc(void);// call this func in main loop

void KeyScan(void);    // call it in timer service, 20ms

pKeyEventCB SetKeyHandler(unsigned char key,KeyEventType event,pKeyEventCB pFunc,void *para);

#endif

#include "key_port.h"
#include "key.h"
#include "ringfifo.h"
#include <string.h>

#define KEY_STATE_UP 0X0
#define KEY_STATE_DOWN 0X3
#define KEY_STATE_LONGRESS 0XF
#define KEY_STATE_RELEASE 0XC

static KeyInfo kInfo[KEY_AMOUNT];
static RingFifo MsgQ;


void PostMessage(MessageInfo* pMsg)
{
    PushFifo(&MsgQ,pMsg);    
}

unsigned char GetMessage(MessageInfo*pMsg)
{
    return PopFifo(&MsgQ,pMsg);
}

// call it in timer service
void KeyScan(void)
{
    int i = 0;
    unsigned char c = 0;
    KeyInfo * pInfo = kInfo; 
    MessageInfo Msg;
    for(i=0;i<KEY_AMOUNT;++i)
    {
        Msg.pContext = pInfo;
        Msg.keyCode = pInfo->keyCode;
        c = ReadKeyStatus(Msg.keyCode);    //
        pInfo->keyStatus |= c;
        pInfo->keyStatus &= 0xF;
        switch(pInfo->keyStatus)
        {
            case KEY_STATE_UP:
                    pInfo->keyDownTime = 0;
                    break;
            case KEY_STATE_DOWN:
                    Msg.keyEvent = KEY_EVENT_DOWN;
                    PostMessage(&Msg);                                    // post event
                    break;
            case KEY_STATE_LONGRESS:
                    if(pInfo->keyDownTime < KEY_LONGPRESS_TIME /POLLING_INTERVAL)
                    {
                        pInfo->keyDownTime++;
                    }
                    else
                    {
                        if(pInfo->keyRepeatTime <  KEY_LONGPRESS_REPEAT_INTERVAL/POLLING_INTERVAL)
                        {
                            ++pInfo->keyRepeatTime;
                        }
                        else
                        {
                            pInfo->keyRepeatTime = 0;
                            Msg.keyEvent = KEY_EVENT_LONGPRESS;
                            PostMessage(&Msg);    // post event
                        }
                    }
                    break;
            case KEY_STATE_RELEASE:
                    Msg.keyEvent = KEY_EVENT_UP;                            
                    PostMessage(&Msg);                                        // post event
                    if(pInfo->keyDbClickTime)    //double click 
                    {
                        Msg.keyEvent = KEY_EVENT_DOUBLECLICK;
                        PostMessage(&Msg);                                        // post event
                    }
                    pInfo->keyDbClickTime = KEY_DBCLICK_TIME /POLLING_INTERVAL;
                    break;
        }
        if(pInfo->keyDbClickTime)pInfo->keyDbClickTime--;
        pInfo->keyStatus <<= 1;
        ++pInfo;
    }
    
}



// call this func in main()
void KeyProc(void)
{
    KeyInfo * pInfo = 0;
    int k = 10;
    MessageInfo msg;
    while(GetMessage(&msg) &&(k--))
    {
        pInfo = msg.pContext;
        if(pInfo->FuncCB[msg.keyEvent])
        {
            pInfo->FuncCB[msg.keyEvent](pInfo->para[msg.keyEvent]);
        }
    }
}

pKeyEventCB SetKeyHandler(unsigned char key,KeyEventType event,pKeyEventCB pFunc,void *para)
{
    pKeyEventCB pf = NULL;
    int i = 0;
    for(i = 0;i<KEY_AMOUNT;++i)
    {
        if(key == kInfo[i].keyCode)
        {
            pf = kInfo[i].FuncCB[event];
            kInfo[i].FuncCB[event] = pFunc;
            kInfo[i].para[event] = para;
            break;
        }
    }
    return pf;
}

void InitKey(void)
{
    int i = 0;
    InitFifo(&MsgQ);
    memset(kInfo,0,sizeof(kInfo));
    for(i = 0;i<KEY_AMOUNT;++i)
    {
        kInfo[i].keyCode = KeyCodeTable[i];
    }
    
    RegisterKeyHandler();
}

#ifndef __RINGFIFO_H__
#define __RINGFIFO_H__

#include "key.h"

#define FIFO_SIZE 10

typedef  MessageInfo ElemDataType;

typedef struct _tagFifo
{
    ElemDataType data[FIFO_SIZE];        // message 
    unsigned char read;                    //
    unsigned char write;                //
}RingFifo;

void InitFifo(RingFifo * pFifo);
unsigned char PopFifo(RingFifo * pFifo,ElemDataType * pMsg);
unsigned char PushFifo(RingFifo * pFifo,ElemDataType * pMsg);
unsigned char PeekFifo(RingFifo * pFifo,ElemDataType * pMsg);

#endif

#include "RingFifo.h"
#include <string.h>
//#include <assert.h>

#define assert(x)

void InitFifo(RingFifo * pFifo)
{
        assert(pFifo);
        memset(pFifo,0,sizeof(RingFifo));
}

unsigned char PopFifo(RingFifo * pFifo,ElemDataType * pMsg)
{
        assert(pFifo&&pMsg);
        if(pFifo->read == pFifo->write)
        {
            return 0;
        }
        else
        {
            memcpy(pMsg,pFifo->data+pFifo->read,sizeof(ElemDataType));
            pFifo->read = (pFifo->read+1)%FIFO_SIZE;
            return 1;
        }
    
}

unsigned char PushFifo(RingFifo * pFifo,ElemDataType * pMsg)
{
    assert(pFifo&&pMsg);
    memcpy(pFifo->data+pFifo->write,pMsg,sizeof(ElemDataType));
    pFifo->write = (pFifo->write + 1) % FIFO_SIZE;
    return 1;
}

unsigned char PeekFifo(RingFifo * pFifo,ElemDataType * pMsg)
{
    assert(pFifo&&pMsg);
    if(pFifo->read == pFifo->write)
    {
        return 0;
    }
    else
    {
        memcpy(pMsg,&pFifo->data[pFifo->read],sizeof(ElemDataType));
        return 1;
    }
}

key_port.h中， KEY_AMOUNT代表能识别的按键个数，      用户需实现ReadKeyStatus(),RegisterKeyHandler()这2个函数，其中

ReadKeyStatus()用来读取硬件按键状态，具体可参见key_port.c示例

RegisterKeyHandler()用来设置按键处理函数。

#ifndef __KEY_PORT_H__
#define __KEY_PORT_H__

#define KEY_AMOUNT 6

#define KEY_LONGPRESS_TIME 3000                        //   3S
#define KEY_DBCLICK_TIME 500    
#define POLLING_INTERVAL 20                                //timer interval
#define KEY_LONGPRESS_REPEAT_INTERVAL 500
extern unsigned char KeyCodeTable[KEY_AMOUNT];
unsigned char ReadKeyStatus(unsigned char key);
void RegisterKeyHandler(void);

#endif

#include "key_port.h"
#include "key.h"
#include "stm32f10x.h"
#include "timer.h"
#include "stepper.h"

#define KEY_1  1
#define KEY_2  2
#define KEY_3  3
#define KEY_4  4
#define KEY_5  5
#define KEY_6  6

unsigned char KeyCodeTable[KEY_AMOUNT]=
{
    KEY_1,
    KEY_2,
    KEY_3,
    KEY_4,
    KEY_5,
    KEY_6
};

void startStateMachine(void);
void key1handler(void *p)    //
{
   startStateMachine();
}

void key2handler(void *p)    //reset
{
   
}


void key3handler(void *p)    // reserve
{
   
        
}

void key3handler_up(void *p)    // 
{
    
}

void key4handler(void *p)
{

}

void key5handler(void *p)
{

}

void key6handler(void *p)
{

}

// get key status,return 1 if key down ,
unsigned char ReadKeyStatus(unsigned char key)
{
    unsigned char c = 0;
    switch(key)
    {
        case KEY_1:
            c = !GPIO_ReadInputDataBit(GPIOC,GPIO_Pin_5);
            break;
        case KEY_2:
            c = !GPIO_ReadInputDataBit(GPIOA,GPIO_Pin_15);
            break;
        case KEY_3:
            c = GPIO_ReadInputDataBit(GPIOC,GPIO_Pin_4);
            break;
        case KEY_4:
            
            c = 0;
            break;
        case KEY_5:
            
            c= 0;
            break;
        case KEY_6:
            c= 0;
            break;
    }
    return c;
}

void RegisterKeyHandler(void)
{
    // Add you key event func here
    SetKeyHandler(KEY_1,KEY_EVENT_DOWN,key1handler ,0);
    SetKeyHandler(KEY_2,KEY_EVENT_DOWN,key2handler ,0);
    SetKeyHandler(KEY_3,KEY_EVENT_DOWN,key3handler ,0);
    SetKeyHandler(KEY_3,KEY_EVENT_UP,key3handler_up ,0);
    SetKeyHandler(KEY_4,KEY_EVENT_DOWN,key4handler ,0);
    SetKeyHandler(KEY_5,KEY_EVENT_DOWN,key5handler ,0);
    SetKeyHandler(KEY_6,KEY_EVENT_UP,key6handler ,0);
}

在key_port.c中，提供了一个示例，分别设置了3个按键key_1,key_2,key_3的keydown处理函数，同时设置了key_3的keyUp处理函数。