/////////////////////////////////////////////////////////////////////
//功 能:复位RC522
//返 回: 成功返回MI_OK
/////////////////////////////////////////////////////////////////////
char PcdReset(void)
{
//PORTD|=(1<<RC522RST);
SET_RC522RST;
delay_ns(10);
//PORTD&=~(1<<RC522RST);
CLR_RC522RST;
delay_ns(10);
//PORTD|=(1<<RC522RST);
SET_RC522RST;
delay_ns(10);
WriteRawRC(CommandReg,PCD_RESETPHASE);
WriteRawRC(CommandReg,PCD_RESETPHASE);
delay_ns(10);
WriteRawRC(ModeReg,0x3D); //和Mifare卡通讯,CRC初始值0x6363
WriteRawRC(TReloadRegL,30);
WriteRawRC(TReloadRegH,0);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
WriteRawRC(TxAutoReg,0x40);//必须要
return MI_OK;
}
///////////////////
///防冲撞寻卡号
///@param pSnr 返回的卡片序列号 4字节
///@retval 是否成功
///////////////////
bool MFRC522::PcdAntiColl(unsigned char *pSnr)
{
bool status;
unsigned char i,snr_check=0;
unsigned int unLen;
unsigned char ucComMF522Buf[MFRC522_MaxReceiveLen];
ClearBitMask(MFRC522_Status2Reg,0x08);
WriteRawRC(MFRC522_BitFramingReg,0x00);
ClearBitMask(MFRC522_CollReg,0x80);
ucComMF522Buf[0] = MFRC522_PICC_ANTICOLL1;
ucComMF522Buf[1] = 0x20;
status = PcdComPicc(MFRC522_PCD_TRANSCEIVE,ucComMF522Buf,2,ucComMF522Buf,&unLen);
if (status)
{
for (i=0; i<4; i++)
{
*(pSnr+i) = ucComMF522Buf[i];
snr_check ^= ucComMF522Buf[i];
}
if (snr_check != ucComMF522Buf[i])
{ status = false; }
}
SetBitMask(MFRC522_CollReg,0x80);
return status;
}
void ClearBitMask(uint8_t reg,uint8_t mask)
{
FUNCTION() ;
char tmp = 0x0;
tmp = ReadRawRC(reg);
WriteRawRC(reg, tmp & ~mask); // clear bit mask
}
/////////////////////////////////////////////////////////////////////
//功 能:防冲撞
//参数说明: pSnr[OUT]:卡片序列号,4字节
//返 回: 成功返回MI_OK
/////////////////////////////////////////////////////////////////////
char PcdAnticoll(unsigned char *pSnr)
{
char status;
unsigned char i,snr_check=0;
unsigned int unLen;
unsigned char ucComMF522Buf[MAXRLEN];
ClearBitMask(Status2Reg,0x08);
WriteRawRC(BitFramingReg,0x00);
ClearBitMask(CollReg,0x80);
ucComMF522Buf[0] = PICC_ANTICOLL1;
ucComMF522Buf[1] = 0x20;
status = PcdComMF522(PCD_TRANSCEIVE,ucComMF522Buf,2,ucComMF522Buf,&unLen);
if (status == MI_OK)
{
for (i=0; i<4; i++)
{
*(pSnr+i) = ucComMF522Buf[i];
snr_check ^= ucComMF522Buf[i];
}
if (snr_check != ucComMF522Buf[i])
{ status = MI_ERR; }
}
SetBitMask(CollReg,0x80);
return status;
}
/////////////////////////////////////////////////////////////////////
//功 能:寻卡
//参数说明: req_code[IN]:寻卡方式
// 0x52 = 寻感应区内所有符合14443A标准的卡
// 0x26 = 寻未进入休眠状态的卡
// pTagType[OUT]:卡片类型代码
// 0x4400 = Mifare_UltraLight
// 0x0400 = Mifare_One(S50)
// 0x0200 = Mifare_One(S70)
// 0x0800 = Mifare_Pro(X)
// 0x4403 = Mifare_DESFire
//返 回: 成功返回MI_OK
/////////////////////////////////////////////////////////////////////
char PcdRequest(unsigned char req_code,unsigned char *pTagType)
{
char status;
unsigned int unLen;
unsigned char ucComMF522Buf[MAXRLEN];
ClearBitMask(Status2Reg,0x08);
WriteRawRC(BitFramingReg,0x07);
SetBitMask(TxControlReg,0x03);
ucComMF522Buf[0] = req_code;
status = PcdComMF522(PCD_TRANSCEIVE,ucComMF522Buf,1,ucComMF522Buf,&unLen);
if ((status == MI_OK) && (unLen == 0x10))
{
*pTagType = ucComMF522Buf[0];
*(pTagType+1) = ucComMF522Buf[1];
}
else
{ status = MI_ERR;
}
return status;
}
char PcdRequest(uint8_t req_code,uint8_t *pTagType)
{
FUNCTION() ;
char status;
uint8_t unLen;
uint8_t ucComMF522Buf[MAXRLEN];
WriteRawRC(BitFramingReg,0x07);
ucComMF522Buf[0] = req_code;
status = PcdComMF522(PCD_TRANSCEIVE,ucComMF522Buf,1,ucComMF522Buf,&unLen);
if ((status == TAG_OK) && (unLen == 0x10))
{
*pTagType = ucComMF522Buf[0];
*(pTagType+1) = ucComMF522Buf[1];
}
else if (status == TAG_COLLISION) {
// printf("ATQA %02x%02x\n",ucComMF522Buf[0],ucComMF522Buf[1]);
}
else if (status!=TAG_NOTAG) {
status = TAG_ERR;
}
return status;
}
void SetBitMask(uint8_t reg,uint8_t mask)
{
FUNCTION() ;
char tmp = 0x0;
tmp = ReadRawRC(reg);
// printf("tmp --------------> by jaosn 0x%x\n",tmp);
WriteRawRC(reg,tmp | mask); // set bit mask
}
char PcdAnticoll(uint8_t cascade, uint8_t *pSnr)
{
FUNCTION() ;
char status;
uint8_t i,snr_check=0;
uint8_t unLen;
uint8_t ucComMF522Buf[MAXRLEN];
uint8_t pass=32;
uint8_t collbits=0;
i=0;
WriteRawRC(BitFramingReg,0x00);
do {
ucComMF522Buf[0] = cascade;
ucComMF522Buf[1] = 0x20+collbits;
// WriteRawRC(0x0e,0);
status = PcdComMF522(PCD_TRANSCEIVE,ucComMF522Buf,2+i,ucComMF522Buf,&unLen);
if (status == TAG_COLLISION) {
collbits=ReadRawRC(CollReg)&0x1f;
if (collbits==0) collbits=32;
i=(collbits-1)/8 +1;
// printf ("--- %02x %02x %02x %02x %d\n",ucComMF522Buf[0],ucComMF522Buf[1],ucComMF522Buf[2],ucComMF522Buf[3],unLen);
ucComMF522Buf[i-1]|=(1<<((collbits-1)%8));
ucComMF522Buf[5]=ucComMF522Buf[3];
ucComMF522Buf[4]=ucComMF522Buf[2];
ucComMF522Buf[3]=ucComMF522Buf[1];
ucComMF522Buf[2]=ucComMF522Buf[0];
WriteRawRC(BitFramingReg,(collbits % 8));
// printf (" %d %d %02x %d\n",collbits,i,ucComMF522Buf[i+1],collbits % 8);
}
} while (((--pass)>0)&&(status==TAG_COLLISION));
if (status == TAG_OK)
{
for (i=0; i<4; i++)
{
*(pSnr+i) = ucComMF522Buf[i];
snr_check ^= ucComMF522Buf[i];
}
if (snr_check != ucComMF522Buf[i])
{ status = TAG_ERR; }
}
return status;
}
/////////////////////////////////////////////////////////////////////
//功 能:复位RC522
//返 回: 成功返回MI_OK
/////////////////////////////////////////////////////////////////////
char PcdReset(void)
{
//unsigned char i;
MF522_RST_SET;
Tos_TaskDelay(1);
MF522_RST_CLR;
Tos_TaskDelay(1);
MF522_RST_SET;
Tos_TaskDelay(1);
WriteRawRC(CommandReg,PCD_RESETPHASE);
Tos_TaskDelay(1);
WriteRawRC(ModeReg,0x3D); //和Mifare卡通讯,CRC初始值0x6363
WriteRawRC(TReloadRegL,30);
WriteRawRC(TReloadRegH,0);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
WriteRawRC(TxAutoReg,0x40);
return MI_OK;
}
void CalulateCRC(uint8_t *pIn ,uint8_t len,uint8_t *pOut )
{
uint8_t i,n;
ClearBitMask(DivIrqReg,0x04);
WriteRawRC(CommandReg,PCD_IDLE);
SetBitMask(FIFOLevelReg,0x80);
for (i=0; i<len; i++)
{ WriteRawRC(FIFODataReg, *(pIn +i)); }
WriteRawRC(CommandReg, PCD_CALCCRC);
i = 0xFF;
do
{
n = ReadRawRC(DivIrqReg);
i--;
}
while ((i!=0) && !(n&0x04));
pOut [0] = ReadRawRC(CRCResultRegL);
pOut [1] = ReadRawRC(CRCResultRegM);
}
/**
* @brief 寻卡
* @param
* @req_code[IN]: 寻卡方式 PICC_REQALL/PICC_REQIDL
* 0x52 = 寻感应区内所有符合14443A标准的卡
* 0x26 = 寻未进入休眠状态的卡
* @pTagType[OUT]: 卡片类型代码
* 0x0002 = Mifare_One(S70)
* 0x0004 = Mifare_One(S50) 白卡
8 0x0008 = Mifare_Pro 校园卡
* 0x0010 = Mifare_Light
* 0x0044 = Mifare_UltraLight
* 0x0304 = Mifare_ProX
* 0x0344 = Mifare_DesFire
* 1. ATQA 的实际作用有两个,
* 一个是告诉读写器自己是否遵循防冲突机制,
* 其次,通过 ATQA 可以获知卡片的序列号(即UID)的长度
* 2. 以 ATQA 判断卡片的类型是不准确的
* 3. 有 ATQA 是 0044H 和 0344H,但不属于 Mifare UltraLight 和 Mifare Desfire。
* 而是一种新的7字节的Mifare S50卡。
* @ret 成功返回 MI_OK/ 错误代码 MI_BITCOUNTERR、MI_COLLERR
* @global none
* @attention:
* 调用 PcdCmdProcess()与卡通讯
*/
signed char PiccRequest(unsigned char req_code, unsigned char *pTagType)
{
signed char status;
struct TranSciveBuffer MfComData;
struct TranSciveBuffer *pi;
pi = &MfComData;
//****************************** initialize ******************************
WriteRawRC(RegChannelRedundancy,0x03); // 奇校验(RxCRC and TxCRC disable, parity enable)
// 在 ISO14443A 下进一步配置
ClearBitMask(RegControl,0x08); // 数据加密,disable Crypto-1 unit
WriteRawRC(RegBitFraming,0x07); // 最后一个字节发送七位,0x52/0x26最高位均为0
SetBitMask(RegTxControl,0x03); // 管脚TX1/TX2上的输出信号将传递调制的13.56MHz能量载波
// Tx2RF-En, Tx1RF-En enable
PcdSetTmo(4); // 寻卡超时阈值4.83ms,通过超时标志位判断是否超时
// ISO14443A 场配置为 PcdSetTmo(1)
MfComData.MfCommand = PCD_TRANSCEIVE; // 发送并接受命令
MfComData.MfLength = 1; // 发送数据长度1
MfComData.MfData[0] = req_code; // M1卡寻卡命令字 PICC_REQIDL或 PICC_REQALL
status = PcdCmdProcess(pi); // 发送并接收,与卡进行通讯
#ifdef __MYDEBUG__
USART_TransmitOne(0xdd);
USART_TransmitOne(status&0xFF);
USART_TransmitOne(MfComData.mfcurrent&0xFF);
for(i=0; i<MfComData.mfcurrent; i++){
USART_TransmitOne(MfComData.MfData[i]);
}
#endif
if (MI_OK == status){
if (MfComData.MfLength != 0x10){ // 卡片类型代码,16 bits
return MI_BITCOUNTERR;
}
*pTagType = MfComData.MfData[0];
*(pTagType+1) = MfComData.MfData[1];
}
return status;
}
/////////////////////////////////////////////////////////////////////
//用MF522计算CRC16函数
/////////////////////////////////////////////////////////////////////
void CalulateCRC(unsigned char *pIndata,unsigned char len,unsigned char *pOutData)
{
unsigned char i,n;
ClearBitMask(DivIrqReg,0x04);
WriteRawRC(CommandReg,PCD_IDLE);
SetBitMask(FIFOLevelReg,0x80);
for (i=0; i<len; i++)
{ WriteRawRC(FIFODataReg, *(pIndata+i)); }
WriteRawRC(CommandReg, PCD_CALCCRC);
i = 0xFF;
do
{
n = ReadRawRC(DivIrqReg);
i--;
}
while ((i!=0) && !(n&0x04));
pOutData[0] = ReadRawRC(CRCResultRegL);
pOutData[1] = ReadRawRC(CRCResultRegM);
}
void MFRC522::PCDInit()
{
WriteRawRC(MFRC522_CommandReg,MFRC522_PCD_RESETPHASE); //想启动寄存器写入复位命令
tskmgr.DelayMs(1);
WriteRawRC(MFRC522_ModeReg,0x3D); //定义发送和接收的模式,和Mifare卡通讯,CRC初始值0x6363
WriteRawRC(MFRC522_TReloadRegL,30); //定时器重装值
WriteRawRC(MFRC522_TReloadRegH,0); //定时器重装值
WriteRawRC(MFRC522_TModeReg,0x8D); //定时器模式设置
WriteRawRC(MFRC522_TPrescalerReg,0x3E);//预分频设置
WriteRawRC(MFRC522_TxAskReg,0x40); //传输调制设置:强制100%ASK调制独立的ModGsPReg的寄存器设置
PcdAntennaOff();//关载波
tskmgr.DelayMs(1);
PcdAntennaOn();//开载波
tskmgr.DelayMs(1);
}
/////////////////////////////////////////////////////////////////////
//功 能:复位RC522
//返 回: 成功返回MI_OK
/////////////////////////////////////////////////////////////////////
char PcdReset(void)
{
SET_RC522RST;
Delay_NOP_us(1);
CLR_RC522RST;
Delay_NOP_us(1);
SET_RC522RST;
Delay_NOP_us(1);
WriteRawRC(CommandReg,PCD_RESETPHASE); //启动卡操作
Delay_NOP_us(1);
WriteRawRC(ModeReg,0x3D); //和Mifare卡通讯,CRC初始值0x6363
WriteRawRC(TReloadRegL,30);
WriteRawRC(TReloadRegH,0);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
WriteRawRC(TxAutoReg,0x40);
return MI_OK;
}
bool MFRC522::FindCard(unsigned char whichTag,unsigned char *pTagType)
{
bool status=false;unsigned int unLen=0; //存放接收到的数据的长度
unsigned char ucComMF522Buf[MFRC522_MaxReceiveLen]; //存放接收到的数据,这里不直接使用pTagType是保险,防止用户传入长度太短的数组,导致数组越界程序崩溃
ClearBitMask(MFRC522_Status2Reg,0x08);//清MIFAREe认证标志
WriteRawRC(MFRC522_BitFramingReg,0x07);//面向位的帧调节,置位最后一个字节的位数,当此标志位0时,代表数据发送完毕
SetBitMask(MFRC522_TxControlReg,0x03);//使能管脚TX1和TX2经载波后发送
status = PcdComPicc(MFRC522_PCD_TRANSCEIVE,&whichTag,1,ucComMF522Buf,&unLen);
if ((status == true) && (unLen == 0x10))
{
*pTagType = ucComMF522Buf[0];
*(pTagType+1) = ucComMF522Buf[1];
}
else
{ status = false; }
return status;
}
//////////////////////////////////////////////////////////////////////
//设置RC632的工作方式
//////////////////////////////////////////////////////////////////////
char M500PcdConfigISOType(u8 type)
{
if (type == 'A') //ISO14443_A
{
ClearBitMask(Status2Reg,0x08);
WriteRawRC(ModeReg,0x3D);//3F
WriteRawRC(RxSelReg,0x86);//84
WriteRawRC(RFCfgReg,0x7F); //4F
WriteRawRC(TReloadRegL,30);//tmoLength);// TReloadVal = 'h6a =tmoLength(dec)
WriteRawRC(TReloadRegH,0);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
delay_ns(1000);
PcdAntennaOn();
}
else{ return 1; }
return MI_OK;
}
/////////////////////////////////////////////////////////////////////
//功 能:复位RC522
//返 回: 成功返回MI_OK
/////////////////////////////////////////////////////////////////////
char PcdReset()
{
RST522_1;
_NOP();
RST522_0;
_NOP();
RST522_1;
_NOP();
WriteRawRC(CommandReg,PCD_RESETPHASE);
_NOP();
WriteRawRC(ModeReg,0x3D);
WriteRawRC(TReloadRegL,30);
WriteRawRC(TReloadRegH,0);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
return MI_OK;
}
/**
* @brief 14443A 防冲突循环 ANTICOLLISION 命令
* @param
* unsigned char *pSnr: 每个串联级别的 UID CLn
* unsigned char SelType: ANTICOLLISION 命令的 SEL 部分,
* 0x93 为级别一,0x95 为级别二,0x97 为级别三
* @ret 成功返回 MI_OK/ 错误代码 MI_BITCOUNTERR、MI_COLLERR
* @global none
* @attention:
* 调用 PcdCmdProcess()与卡通讯
*/
signed char PiccAnticollisionLoop(unsigned char *pSnr, unsigned char SelType)
{
signed char status;
unsigned char i;
unsigned char ucBytes; // number of bytes known
unsigned char ucBits; // remaining number of bits
unsigned char snr_check = 0; // snr_xor vs snr_check
unsigned char ucCollPosition = 0; // record CollPos
unsigned char ucTemp;
unsigned char ucSnr[5] = {0, 0, 0, 0 ,0}; // local snr and BCC
unsigned char dummyShift1; // dummy byte for snr shifting
unsigned char dummyShift2; // dummy byte for snr shifting
/*
* struct TranSciveBuffer{
unsigned char MfCommand; // MFRC500命令字或 M1卡命令字
unsigned int MfLength; // 发送数据长度(/byte)或接收数据长度(/bit)
unsigned char MfData[128]; // 发送数据或接收数据临时缓冲区
unsigned int mfcurrent; // 接收字节数
};
*/
struct TranSciveBuffer MfComData;
struct TranSciveBuffer *pi;
memset(MfComData.MfData, 0, 128); // initialize buffer to zeros.
pi = &MfComData;
// ****************************** Registers Initialisation ******************************
WriteRawRC(RegDecoderControl, 0x28); // 启用 ZeroAfterColl
// 在一个位冲突之后的任何位都屏蔽为 0,
// 由 ISO14443A 定义的防冲突机制进行处理
ClearBitMask(RegControl,0x08); // disable crypto 1 unit
WriteRawRC(RegChannelRedundancy,0x03); // RxCRC and TxCRC disable, parity enable
PcdSetTmo(3); // medium timeout (4.833 ms)
// ****************************** Anticollision Loop ******************************
do
{
// -------------------- 更新 ucBits、ucBytes,设置 RegBitFraming --------------------
ucBits = (ucCollPosition) % 8; // remaining number of bits
// 不完整字节需额外处理
if (ucBits != 0){
ucBytes = ucCollPosition / 8 + 1; // 不足一个字节也需要按一个字节计数
// RxAlign[6:4] 用于位方式帧的接收,定义了接收的第一个位存储在 FIFO 的位置,
// 更多的位存储在后面的位位置。
// TxLastBits[2:0] 用于位方式帧的发送,定义要发送的最后一个字节的位数目。
WriteRawRC(RegBitFraming, (ucBits << 4) + ucBits); // TxLastBits/RxAlign
// in order to solve an inconsistancy in the anticollision sequence
// (will be solved soon), the case of 7 bits has to be treated in a
// separate way - 官方文档:强烈建议不要使用 RxAlign=7 以防止数据丢失!!
if (ucBits == 7){
WriteRawRC(RegBitFraming, ucBits); // reset RxAlign to zero,TxLastBits=ucBits
}
}
else{
ucBytes = ucCollPosition / 8; // 没有不足一个字节的情况
}
// -------------------------- 构建发送命令信息 --------------------------
MfComData.MfCommand = PCD_TRANSCEIVE;
MfComData.MfData[0] = SelType; // PICC_ANTICOLL1
/*
* NVB 初始值为 0x20,表示该命令只含有 2 个字节,即"0x93+0x20",不含 UID 数据,
* MIFARE 卡须返回全部 UID 字节作为响应。
* 若返回的 UID 数据有位冲突的情况发生,则根据冲突位置更新 NVB 值。
* 在搜索循环中,随着 UID 已知比特数的加入,NVB 不断增加,直到 0x70 为止。
* 它表示除了"0x93+0x70"两个命令字节外,还有 UID0~UID3 和 BCC 5个UID数据字节。
* 此时命令字节共有 7 个,防冲突命令转变为卡片选择命令。
* BCC 只有在 UID CLn 为 40bit 才有,是前面 5 个字节的异或!!!
*/
MfComData.MfData[1] = 0x20 + ((ucCollPosition / 8) << 4) + (ucBits & 0x0F);
for (i=0; i<ucBytes; i++){ // 发送缓冲区描述
MfComData.MfData[i + 2] = ucSnr[i];
}
MfComData.MfLength = ucBytes + 2; // 发送数据字节数
status = PcdCmdProcess(pi);
#ifdef __MYDEBUG__
USART_TransmitOne((unsigned char)0xcc);
USART_TransmitOne(status); // 此处应为 MI_OK/MI_COLLERR
USART_TransmitOne(MfComData.MfLength);
USART_TransmitOne(MfComData.mfcurrent);
for(i=0; i<MfComData.mfcurrent; i++){
USART_TransmitOne(MfComData.MfData[i]);
}
#endif
// -------------------------- 接收数据预处理 --------------------------
/* RxAlign=7 数据可能会丢失,在位位置 7、15、23、31、39(CollPos)
* 检测到的位冲突不能通过 RxAlign 解决,需要软件来实现
*/
if(ucBits == 7){
// xxxx xxx? ---- ---[x] ==> 3 bytes!
if( (MfComData.MfLength%8)==0 ){
MfComData.mfcurrent += 1;
}
dummyShift1 = 0x00; // reorder received bits
/*
* 软件实现 RxAlign=7 时接收数据的移位恢复
* xxxx xxx? ---- ---[x] **** ***[-] 0000 000[*]
* ?000 0000 [x]xxx xxxx [-]--- ---- [*]*** ****
*/
if( MfComData.MfData[0] ){
for (i=1; i<MfComData.mfcurrent; i++){ // MfData[0] keeps the CollPos
dummyShift2 = MfComData.MfData[i];
/*
* xxxx xxx?(>>1) ==> 0xxx xxxx
* ---- ---[x](<<7) ==> [x]00 0000
* 0xxx xxxx | [x]00 0000 ==> [x]xxx xxxx
*/
MfComData.MfData[i] = (dummyShift1 >> 1) | (MfComData.MfData[i] << 7);
dummyShift1 = dummyShift2;
}
//MfComData.MfLength -= MfComData.mfcurrent; // no need to update bits&bytes
// recalculation of collision position
//MfComData.MfData[0] += 7 - (MfComData.MfData[0] + 6) / 9;
} // end of if( MfComData.MfData[0] )
else{
for (i=0; i<MfComData.mfcurrent; i++){
dummyShift2 = MfComData.MfData[i];
MfComData.MfData[i] = (dummyShift1 >> 1) | (MfComData.MfData[i] << 7);
dummyShift1 = dummyShift2;
}
}
} // end of if(ucBits == 7)
// -------------------------- 更新当前 UID 信息 --------------------------
ucTemp = ucSnr[(ucCollPosition / 8)];
// MI_COLLERR/MI_OK, no other occured
if(status == MI_COLLERR){
for (i=0; i < MfComData.mfcurrent; i++){// MfData[0] keeps the CollPos
ucSnr[i + (ucCollPosition / 8)] = MfComData.MfData[i+1];
}
ucSnr[(ucCollPosition / 8)] |= ucTemp;
ucCollPosition += MfComData.MfData[0]; // Update the ucCollPosition
#ifdef __ANTICOLL_LOOP_DEBUG__
USART_TransmitOne(0xbc);
USART_TransmitOne(ucCollPosition);
#endif
}
else if(status == MI_OK){
for (i=0; i < MfComData.mfcurrent; i++){
ucSnr[4 - i] = MfComData.MfData[MfComData.mfcurrent - i - 1];
}
ucSnr[(ucCollPosition / 8)] |= ucTemp;
}
} while(status == MI_COLLERR);
/////////////////////////////////////////////////////////////////////
//功 能:通过RC522和ISO14443卡通讯
//参数说明:Command[IN]:RC522命令字
// pInData[IN]:通过RC522发送到卡片的数据
// InLenByte[IN]:发送数据的字节长度
// pOutData[OUT]:接收到的卡片返回数据
// *pOutLenBit[OUT]:返回数据的位长度
/////////////////////////////////////////////////////////////////////
char PcdComMF522(unsigned char Command,
unsigned char *pInData,
unsigned char InLenByte,
unsigned char *pOutData,
unsigned int *pOutLenBit)
{
char status = MI_ERR;
unsigned char irqEn = 0x00;
unsigned char waitFor = 0x00;
unsigned char lastBits;
unsigned char n;
unsigned int i;
switch (Command)
{
case PCD_AUTHENT:
irqEn = 0x12;
waitFor = 0x10;
break;
case PCD_TRANSCEIVE:
irqEn = 0x77;
waitFor = 0x30;
break;
default:
break;
}
WriteRawRC(ComIEnReg,irqEn|0x80);
ClearBitMask(ComIrqReg,0x80);
WriteRawRC(CommandReg,PCD_IDLE);
SetBitMask(FIFOLevelReg,0x80);
for (i=0; i<InLenByte; i++)
{ WriteRawRC(FIFODataReg, pInData[i]); }
WriteRawRC(CommandReg, Command);
if (Command == PCD_TRANSCEIVE)
{ SetBitMask(BitFramingReg,0x80); }
i = 600;//根据时钟频率调整,操作M1卡最大等待时间25ms
do
{
n = ReadRawRC(ComIrqReg);
i--;
}
while ((i!=0) && !(n&0x01) && !(n&waitFor));
ClearBitMask(BitFramingReg,0x80);
if (i!=0)
{
if(!(ReadRawRC(ErrorReg)&0x1B))
{
status = MI_OK;
if (n & irqEn & 0x01)
{ status = MI_NOTAGERR; }
if (Command == PCD_TRANSCEIVE)
{
n = ReadRawRC(FIFOLevelReg);
lastBits = ReadRawRC(ControlReg) & 0x07;
if (lastBits)
{ *pOutLenBit = (n-1)*8 + lastBits; }
else
{ *pOutLenBit = n*8; }
if (n == 0)
{ n = 1; }
if (n > MAXRLEN)
{ n = MAXRLEN; }
for (i=0; i<n; i++)
{ pOutData[i] = ReadRawRC(FIFODataReg); }
}
}
else
{ status = MI_ERR; }
}
SetBitMask(ControlReg,0x80); // stop timer now
WriteRawRC(CommandReg,PCD_IDLE);
return status;
}
bool MFRC522::PcdComPicc(unsigned char Command,unsigned char *pDataToPicc,unsigned char toPiccLength,
unsigned char *pDataInPcd, unsigned int *pInBitLength)
{
bool status = false;
unsigned char irqEn = 0x00;
unsigned char waitFor = 0x00;
unsigned char lastBits;
unsigned char n;
unsigned int i;
char temp;
switch (Command)
{
case MFRC522_PCD_AUTHENT:
irqEn = 0x12;
waitFor = 0x10;
break;
case MFRC522_PCD_TRANSCEIVE:
irqEn = 0x77;
waitFor = 0x30;
break;
default:
break;
}
WriteRawRC(MFRC522_ComIEnReg,irqEn|0x80);//管脚IRQ上的信号与寄存器StatusReg的IRQ位的值相反
ClearBitMask(MFRC522_ComIrqReg,0x80); //中断标志,定义CommIRqReg寄存器中的屏蔽位置位
WriteRawRC(MFRC522_CommandReg,MFRC522_PCD_IDLE);//设置为IDLE状态(模拟电路开启,MFR522唤醒,取消当前命令的执行,命令为0)
SetBitMask(MFRC522_FIFOLevelReg,0x80); //清FIFO状态标志和错误标志,FIFO计数清零
for (i=0; i<toPiccLength; i++)
WriteRawRC(MFRC522_FIFODataReg, pDataToPicc[i]);
WriteRawRC(MFRC522_CommandReg, Command);
if (Command == MFRC522_PCD_TRANSCEIVE)
SetBitMask(MFRC522_BitFramingReg,0x80);//启动数据发送
i = 0;//操作M1卡最大等待时间25ms
double timeOut=tskmgr.Time();
do
{
if(tskmgr.Time()-timeOut > 0.027)
{
i=1;//超时
break;
}
n = ReadRawRC(MFRC522_ComIrqReg);//获取中断标志寄存器
}while (!(n&0x01) && !(n&waitFor));//等待传输完成,并且定时器的值递减到零时退出
ClearBitMask(MFRC522_BitFramingReg,0x80);//清掉启动数据发送位
if (i==0)//没有超时
{
temp=(ReadRawRC(MFRC522_ErrorReg));
if(!(temp&0x1B))
{
status = true;
if (n & irqEn & 0x01)
status = false;
if (Command == MFRC522_PCD_TRANSCEIVE)
{
n = ReadRawRC(MFRC522_FIFOLevelReg);//获取FIFO中数据的长度
lastBits = ReadRawRC(MFRC522_ControlReg) & 0x07;//最后接收到的字节的有效位数,为零时整个字节有效
if (lastBits)
*pInBitLength = (n-1)*8 + lastBits;
else
*pInBitLength = n*8;
if (n == 0)//队列中没有数据
n = 1;
if (n > MFRC522_MaxReceiveLen)//长度超过了最大长度
n = MFRC522_MaxReceiveLen;
for (i=0; i<n; i++)
pDataInPcd[i] = ReadRawRC(MFRC522_FIFODataReg);
}
}
else//出错
status = false;
}
SetBitMask(MFRC522_ControlReg,0x80); // stop timer now
WriteRawRC(MFRC522_CommandReg,MFRC522_PCD_IDLE); //取消当前命令的执行
return status;
}
/////////////////////////////////////////////////////////////////////
//功 能:清RC522寄存器位
//参数说明:reg[IN]:寄存器地址
// mask[IN]:清位值
/////////////////////////////////////////////////////////////////////
void ClearBitMask(unsigned char reg,unsigned char mask)
{
char tmp = 0x0;
tmp = ReadRawRC(reg);
WriteRawRC(reg, tmp & ~mask); // clear bit mask
}
/////////////////////////////////////////////////////////////////////
//功 能:置RC522寄存器位
//参数说明:reg[IN]:寄存器地址
// mask[IN]:置位值
/////////////////////////////////////////////////////////////////////
void SetBitMask(unsigned char reg,unsigned char mask)
{
char tmp = 0x0;
tmp = ReadRawRC(reg);
WriteRawRC(reg,tmp | mask); // set bit mask
}
char PcdComMF522(uint8_t Command,
uint8_t *pIn ,
uint8_t InLenByte,
uint8_t *pOut ,
uint8_t *pOutLenBit)
{
FUNCTION() ;
char status = TAG_ERR;
uint8_t irqEn = 0x00;
uint8_t waitFor = 0x00;
uint8_t lastBits;
uint8_t n;
uint32_t i;
uint8_t PcdErr;
// printf("CMD %02x\n",pIn[0]);
switch (Command)
{
case PCD_AUTHENT:
irqEn = 0x12;
waitFor = 0x10;
break;
case PCD_TRANSCEIVE:
irqEn = 0x77;
waitFor = 0x30;
break;
default:
break;
}
WriteRawRC(ComIEnReg,irqEn|0x80);
// WriteRawRC(ComIEnReg,irqEn);
ClearBitMask(ComIrqReg,0x80);
SetBitMask(FIFOLevelReg,0x80);
WriteRawRC(CommandReg,PCD_IDLE);
for (i=0; i<InLenByte; i++) {
WriteRawRC(FIFODataReg, pIn [i]);
}
WriteRawRC(CommandReg, Command);
if (Command == PCD_TRANSCEIVE) {
SetBitMask(BitFramingReg,0x80);
}
//i = 600;//���ʱ��Ƶ�ʵ������M1�����ȴ�ʱ��25ms
i = 150;
do
{
usleep(200);
// bcm2835_delayMicroseconds(200);
n = ReadRawRC(ComIrqReg);
i--;
}
while ((i!=0) && (!(n&0x01)) && (!(n&waitFor)));
ClearBitMask(BitFramingReg,0x80);
if (i!=0)
{
PcdErr=ReadRawRC(ErrorReg);
if (!(PcdErr & 0x11))
{
status = TAG_OK;
if (n & irqEn & 0x01) {status = TAG_NOTAG;}
if (Command == PCD_TRANSCEIVE) {
n = ReadRawRC(FIFOLevelReg);
lastBits = ReadRawRC(ControlReg) & 0x07;
if (lastBits) {*pOutLenBit = (n-1)*8 + lastBits;}
else {*pOutLenBit = n*8;}
if (n == 0) {n = 1;}
if (n > MAXRLEN) {n = MAXRLEN;}
for (i=0; i<n; i++) {
pOut [i] = ReadRawRC(FIFODataReg);
// printf (".%02X ",pOut[i]);
}
}
}
else {
// fprintf (stderr,"Err %02x\n",PcdErr);
status = TAG_ERR;}
if (PcdErr&0x08) {
if (debug) fprintf (stderr,"COllision \n");
status = TAG_COLLISION;
}
}
// SetBitMask(ControlReg,0x80); // stop timer now
// WriteRawRC(CommandReg,PCD_IDLE); ???????
// printf ("PCD Err %02x\n",PcdErr);
return status;
}
char PcdReset(void)
{
WriteRawRC(CommandReg,PCD_RESETPHASE);
usleep(10000);
ClearBitMask(TxControlReg,0x03);
usleep(10000);
SetBitMask(TxControlReg,0x03);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
WriteRawRC(TReloadRegL,30);
WriteRawRC(TReloadRegH,0);
WriteRawRC(TxASKReg,0x40);
WriteRawRC(ModeReg,0x3D); //6363
// WriteRawRC(DivlEnReg,0x90);
WriteRawRC(RxThresholdReg,0x84);
WriteRawRC(RFCfgReg,0x68);
WriteRawRC(GsNReg,0xff);
WriteRawRC(CWGsCfgReg,0x2f);
// WriteRawRC(ModWidthReg,0x2f);
return TAG_OK;
}
char PcdReset(void)
{
uint8_t i = 0;
FUNCTION() ;
i = ReadRawRC(ComIEnReg);
printf("before soft reset 0x02 address value is 0x%x\n",i);
WriteRawRC(CommandReg,PCD_RESETPHASE);
usleep(10000);
// this is by myself
i = ReadRawRC(ComIEnReg);
if (i == 0x80) {
printf("read success and after reset 0x02 value is 0x%x\n",i);
}else {
printf("after reset 0x02 value is 0x%x , not is 0x80",i);
}
#if 0
i &= 0x0F;
if(i == PCD_IDLE) {
printf("now a20 tran cancle command : 0x%x \n",PCD_IDLE);
}else if(i == PCD_AUTHENT) {
printf("now a20 tran authent command : 0x%x\n",PCD_AUTHENT);
}else if(i == PCD_RECEIVE) {
printf("now a20 tran receive command : 0x%x\n",PCD_RECEIVE);
}else if(i == PCD_TRANSMIT) {
printf("now a20 tran transmit command : 0x%x\n",PCD_TRANSMIT);
}else if(i == PCD_RESETPHASE) {
printf("now a20 tran so_reset command : 0x%x\n",PCD_RESETPHASE);
}else if(i == PCD_CALCCRC) {
printf("now a20 tran calccrc command: 0x%x\n",PCD_CALCCRC);
}else {
printf("unkonw a20 command,check spi read/write code\n");
}
#endif
#if 1
ClearBitMask(TxControlReg,0x03);
usleep(10000);
SetBitMask(TxControlReg,0x03);
WriteRawRC(TModeReg,0x8D);
WriteRawRC(TPrescalerReg,0x3E);
WriteRawRC(TReloadRegL,30);
WriteRawRC(TReloadRegH,0);
WriteRawRC(TxASKReg,0x40);
WriteRawRC(ModeReg,0x3D); //6363
// WriteRawRC(DivlEnReg,0x90);
WriteRawRC(RxThresholdReg,0x84);
WriteRawRC(RFCfgReg,0x68);
WriteRawRC(GsNReg,0xff);
WriteRawRC(CWGsCfgReg,0x2f);
// WriteRawRC(ModWidthReg,0x2f);
#endif
return TAG_OK;
}
/////////////////////////////////////////////////////////////////////
//功 能:清RC522寄存器位
//参数说明:reg[IN]:寄存器地址
// mask[IN]:清位值
/////////////////////////////////////////////////////////////////////
void ClearBitMask(u8 reg,u8 mask)
{
char tmp = 0x0;
tmp = ReadRawRC(reg);
WriteRawRC(reg, tmp & ~mask); // clear bit mask
}
/////////////////////////////////////////////////////////////////////
//功 能:置RC522寄存器位
//参数说明:reg[IN]:寄存器地址
// mask[IN]:置位值
/////////////////////////////////////////////////////////////////////
void SetBitMask(u8 reg,u8 mask)
{
char tmp = 0x0;
tmp = ReadRawRC(reg);
WriteRawRC(reg,tmp | mask); // set bit mask
}
