/*
 * I2C.cpp
 *
 *  Created on: Mar 21, 2024
 *      Author: User
 */

#include "I2C.h"
#include <stdio.h>
#include <string.h>


//#define DUMP_REG_RW

I2C::I2C()
:m_i2c_dev(NULL){
	// TODO Auto-generated constructor stub

}

I2C::~I2C() {
	// TODO Auto-generated destructor stub
}

bool I2C::Open(const char *pDevName, alt_u32 nDeviceAddr /* 7-bit addr */){
	bool bSuccess = false;
	ALT_AVALON_I2C_DEV_t *i2c_dev;

	Close();

	//get a pointer to the avalon i2c instance
	i2c_dev = alt_avalon_i2c_open(pDevName);
	if (NULL==i2c_dev){
		printf("Error: Cannot find %s\n", pDevName);
	}else{
	  alt_avalon_i2c_master_target_set(i2c_dev,nDeviceAddr);
  	  bSuccess = true;
  	  m_i2c_dev = i2c_dev;
	}


	return bSuccess;
}

void I2C::Close(){
	if (m_i2c_dev){
		//alt_avalon_i2c_close(m_i2c_dev);
		m_i2c_dev = NULL;
	}
}

bool I2C::ReadReg8s(alt_u16 nRegByteOffset, alt_u8 nByteCnt, alt_u8 *pBuffer){
	bool bSuccess = false;
	ALT_AVALON_I2C_STATUS_CODE status;


	if (m_i2c_dev == NULL){
		printf("m_i2c_dev is NULL\r\n");
		return false;
	}

	// reg byte offset
	m_txbuffer[0]= nRegByteOffset >> 8; // high byte of byte-offset
	m_txbuffer[1]= nRegByteOffset & 0xFF; // low byte of  byte-offset


	status=alt_avalon_i2c_master_tx_rx(m_i2c_dev, m_txbuffer, 2, m_rxbuffer, nByteCnt, ALT_AVALON_I2C_NO_INTERRUPTS);
	if (status==ALT_AVALON_I2C_SUCCESS){
		memcpy(pBuffer, m_rxbuffer, nByteCnt);
    	bSuccess = true;
#ifdef DUMP_REG_RW
    	if (nByteCnt == 1){
    		printf("  REG[%04xh] --> %02xh\r\n", nRegByteOffset, *pBuffer);
    	}else{
    		for(int i=0; i< nByteCnt; i+=2){
        		printf("  REG[%04xh] --> %04xh \r\n", nRegByteOffset+i, *(alt_u16 *)(pBuffer+i));
    		}
    	}
#endif
	}else{
		printf("alt_avalon_i2c_master_tx_rx failed in ReadReg8s\r\n");
	}

	return bSuccess;
}

bool I2C::Addr8_ReadReg8s(alt_u8 nRegByteOffset, alt_u8 nByteCnt, alt_u8 *pBuffer){
	bool bSuccess = false;
	ALT_AVALON_I2C_STATUS_CODE status;


	if (m_i2c_dev == NULL){
		printf("m_i2c_dev is NULL\r\n");
		return false;
	}

	// reg byte offset
	m_txbuffer[0]= nRegByteOffset; // byte-offset

	status=alt_avalon_i2c_master_tx_rx(m_i2c_dev, m_txbuffer, 1, m_rxbuffer, nByteCnt, ALT_AVALON_I2C_NO_INTERRUPTS);
	if (status==ALT_AVALON_I2C_SUCCESS){
		memcpy(pBuffer, m_rxbuffer, nByteCnt);
    	bSuccess = true;
#ifdef DUMP_REG_RW
    	if (nByteCnt == 1){
    		printf("  REG[%02xh] --> %02xh\r\n", nRegByteOffset, *pBuffer);
    	}else{
    		for(int i=0; i< nByteCnt; i+=2){
        		printf("  REG[%02xh] --> %04xh \r\n", nRegByteOffset+i, *(alt_u16 *)(pBuffer+i));
    		}
    	}
#endif
	}else{
		printf("alt_avalon_i2c_master_tx_rx failed in ReadReg8s\r\n");
	}

	return bSuccess;
}

bool I2C::ReadReg8(alt_u16 nRegByteOffset, alt_u8 *pnRead8){
	bool bSuccess;

	bSuccess = ReadReg8s(nRegByteOffset, 1, pnRead8);

	return bSuccess;
}

bool I2C::ReadReg16(alt_u16 nRegByteOffset, alt_u16 *pnRead16){
	bool bSuccess;

	bSuccess = ReadReg8s(nRegByteOffset, 2, (alt_u8 *)pnRead16);

	return bSuccess;
}

bool I2C::Addr8_ReadReg8(alt_u8 nRegByteOffset, alt_u8 *pnRead8){
	bool bSuccess;

	bSuccess = Addr8_ReadReg8s(nRegByteOffset, 1, pnRead8);

	return bSuccess;
}

bool I2C::Addr8_ReadReg16(alt_u8 nRegByteOffset, alt_u16 *pnRead16){
	bool bSuccess;

	bSuccess = Addr8_ReadReg8s(nRegByteOffset, 2, (alt_u8 *)pnRead16);

	return bSuccess;
}


bool I2C::WriteReg8s(alt_u16 nRegByteOffset, alt_u8 nByteCnt, alt_u8 *pData){
	bool bSuccess;
	ALT_AVALON_I2C_STATUS_CODE status;

	if (m_i2c_dev == NULL){
		printf("m_i2c_dev is NULL\r\n");
		return false;
	}

	// reg byte offset
	m_txbuffer[0]= nRegByteOffset >> 8; // high byte of byte-offset
	m_txbuffer[1]= nRegByteOffset & 0xFF; // low byte of  byte-offset
	memcpy(m_txbuffer+2, pData, nByteCnt);
    status=alt_avalon_i2c_master_tx(m_i2c_dev,m_txbuffer, nByteCnt+2, ALT_AVALON_I2C_NO_INTERRUPTS);
	if (status == ALT_AVALON_I2C_SUCCESS){
    	bSuccess = true;
#ifdef DUMP_REG_RW
    	if (nByteCnt == 1){
    		printf("  %02xh --> REG[%04xh]\r\n", *pData, nRegByteOffset);
    	}else{
    		for(int i=0; i< nByteCnt; i+=2){
        		printf("  %04xh --> REG[%04xh]\r\n", *(alt_u16 *)(pData+i), nRegByteOffset+i);
    		}
    	}
#endif
	}
	return bSuccess;
}

bool I2C::Addr8_WriteReg8s(alt_u8 nRegByteOffset, alt_u8 nByteCnt, alt_u8 *pData){
	bool bSuccess;
	ALT_AVALON_I2C_STATUS_CODE status;

	if (m_i2c_dev == NULL){
		printf("m_i2c_dev is NULL\r\n");
		return false;
	}

	// reg byte offset
	m_txbuffer[0]= nRegByteOffset; // byte-offset
	memcpy(m_txbuffer+1, pData, nByteCnt);
    status=alt_avalon_i2c_master_tx(m_i2c_dev,m_txbuffer, nByteCnt+1, ALT_AVALON_I2C_NO_INTERRUPTS);
	if (status == ALT_AVALON_I2C_SUCCESS){
    	bSuccess = true;
#ifdef DUMP_REG_RW
    	if (nByteCnt == 1){
    		printf("  %02xh --> REG[%02xh]\r\n", *pData, nRegByteOffset);
    	}else{
    		for(int i=0; i< nByteCnt; i+=2){
        		printf("  %04xh --> REG[%02xh]\r\n", *(alt_u16 *)(pData+i), nRegByteOffset+i);
    		}
    	}
#endif
	}
	return bSuccess;
}


bool I2C::WriteReg8(alt_u16 nRegByteOffset, alt_u8 nValue8){
	bool bSuccess;

	bSuccess = WriteReg8s(nRegByteOffset, 1, &nValue8);

	return bSuccess;
}

bool I2C::WriteReg16(alt_u16 nRegByteOffset, alt_u16 nValue16){
	bool bSuccess;

	bSuccess = WriteReg8s(nRegByteOffset, 2, (alt_u8 *)&nValue16);

	return bSuccess;
}


bool I2C::Addr8_WriteReg8(alt_u8 nRegByteOffset, alt_u8 nValue8){
	bool bSuccess;

	bSuccess = Addr8_WriteReg8s(nRegByteOffset, 1, &nValue8);

	return bSuccess;
}

bool I2C::Addr8_WriteReg16(alt_u8 nRegByteOffset, alt_u16 nValue16){
	bool bSuccess;

	bSuccess = Addr8_WriteReg8s(nRegByteOffset, 2, (alt_u8 *)&nValue16);

	return bSuccess;
}


bool I2C::DumpReg8(alt_u16 nRegByteOffset, alt_u8 nReg8Cnt){
	bool bSuccess;
	alt_u8 szBuf[256];
	int i;

	bSuccess = ReadReg8s(nRegByteOffset, nReg8Cnt, szBuf);

	if (bSuccess){
		for(i=0;i<nReg8Cnt;i++){
			printf("[%d]=%d(%xh)\r\n", i, szBuf[i], szBuf[i]);
		}

	}


	return bSuccess;



}


