example_280xi2c_eeprom.c
来自「DSP2808例程。TMS320F2808DSP的各个模块的应用例程」· C语言 代码 · 共 687 行 · 第 1/2 页
C
687 行
// TI File $Revision: /main/3 $
// Checkin $Date: December 3, 2004 13:40:48 $
//###########################################################################
//
// FILE: Example_280xI2c_eeprom.c
//
// TITLE: DSP280x I2C EEPROM Example
//
// ASSUMPTIONS:
//
// This program requires the DSP280x header files.
//
// This program requires an external I2C EEPROM connected to
// the I2C bus at address 0x50.
//
// As supplied, this project is configured for "boot to SARAM"
// operation. The 280x Boot Mode table is shown below.
// For information on configuring the boot mode of an eZdsp,
// please refer to the documentation included with the eZdsp,
//
// Boot GPIO18 GPIO29 GPIO34
// Mode SPICLKA SCITXDA
// SCITXB
// -------------------------------------
// Flash 1 1 1
// SCI-A 1 1 0
// SPI-A 1 0 1
// I2C-A 1 0 0
// ECAN-A 0 1 1
// SARAM 0 1 0 <- "boot to SARAM"
// OTP 0 0 1
// I/0 0 0 0
//
// DESCRIPTION:
//
// This program will write 1-14 words to EEPROM and read them back.
// The data written and the EEPROM address written to are contained
// in the message structure, I2cMsgOut1. The data read back will be
// contained in the message structure I2cMsgIn1.
//
// This program will work with the on-board I2C EEPROM supplied on
// the F280x eZdsp.
//
//
//###########################################################################
// Original Author: D.F.
//
// $TI Release: DSP280x V1.30 $
// $Release Date: February 10, 2006 $
//###########################################################################
#include "DSP280x_Device.h" // DSP280x Headerfile Include File
#include "DSP280x_Examples.h" // DSP280x Examples Include File
/* 2线接口的位操作,与单片机有关 */
#define CH452_SCL_SET GpioDataRegs.GPBSET.bit.GPIO33 = 1//{CH452_SCL=1;}
#define CH452_SCL_CLR GpioDataRegs.GPBCLEAR.bit.GPIO33 = 1//{CH452_SCL=0;}
#define CH452_SDA_SET GpioDataRegs.GPBSET.bit.GPIO32 = 1//{CH452_SDA=1;}
#define CH452_SDA_CLR GpioDataRegs.GPBCLEAR.bit.GPIO32 = 1//{CH452_SDA=0;}
#define CH452_SDA_IN GpioDataRegs.GPBDAT.bit.GPIO32//(CH452_SDA)
#define CH452_SDA_D_OUT GpioCtrlRegs.GPBDIR.bit.GPIO32 = 1; // 设置SDA为输出方向,对于双向I/O需切换为输出
#define CH452_SDA_D_IN GpioCtrlRegs.GPBDIR.bit.GPIO32 = 0; //{CH452_SDA=1;} // 设置SDA为输入方向,对于双向I/O需切换为输入
/* CH451和CH452的常用命令码 */
#define CH452_NOP 0x0000 // 空操作
#define CH452_RESET 0x0201 // 复位
#define CH452_LEVEL 0x0100 // 加载光柱值
#define CH452_CLR_BIT 0x0180 // 段位清0
#define CH452_SET_BIT 0x01C0 // 段位置1
#define CH452_SLEEP 0x0202 // 进入睡眠状态
#define CH452_LEFTMOV 0x0300 //设置移动方式-作移
#define CH452_LEFTCYC 0x0301 //设置移动方式-左循
#define CH452_RIGHTMOV 0x0302 //设置移动方式-右移
#define CH452_RIGHTCYC 0x0303 //设置移动方式-右循
#define CH452_SELF_BCD 0x0380 //自定义BCD码
#define CH452_SYSOFF 0x0400 //关显示、键盘
#define CH452_SYSON1 0x0401 //开显示
#define CH452_SYSON2 0x0403 //开显示、键盘
#define CH452_SYSON2W 0x0423 //开显示、键盘, 真正2线接口
#define CH452_DSP 0x0500 //设置默认显示方式
#define CH452_BCD 0x0580 //设置BCD译码方式
#define CH452_TWINKLE 0x0600 //设置闪烁控制
#define CH452_GET_KEY 0x0700 // 获取按键
#define CH452_DIG0 0x0800 //数码管位0显示
#define CH452_DIG1 0x0900 //数码管位1显示
#define CH452_DIG2 0x0a00 //数码管位2显示
#define CH452_DIG3 0x0b00 //数码管位3显示
#define CH452_DIG4 0x0c00 //数码管位4显示
#define CH452_DIG5 0x0d00 //数码管位5显示
#define CH452_DIG6 0x0e00 //数码管位6显示
#define CH452_DIG7 0x0f00 //数码管位7显示
// Note: I2C Macros used in this example can be found in the
// DSP280x_I2C_defines.h file
// Prototype statements for functions found within this file.
void I2CA_Init(void);
Uint16 I2CA_WriteData(struct I2CMSG *msg);
Uint16 I2CA_ReadData(struct I2CMSG *msg);
interrupt void i2c_int1a_isr(void);
void pass(void);
void fail(void);
void CH452_Write(unsigned char);
unsigned char CH452_Read(void);
void CH452_I2c_Start();
void CH452_I2c_Stop();
void CH452_I2c_WrByte(unsigned char);
unsigned char CH452_I2c_RdByte();
#define I2C_SLAVE_ADDR 0x50
#define I2C_NUMBYTES 4
#define I2C_EEPROM_HIGH_ADDR 0x00
#define I2C_EEPROM_LOW_ADDR 0x30
// Global variables
// Two bytes will be used for the outgoing address,
// thus only setup 14 bytes maximum
struct I2CMSG I2cMsgOut1={I2C_MSGSTAT_SEND_WITHSTOP,
I2C_SLAVE_ADDR,
I2C_NUMBYTES,
I2C_EEPROM_HIGH_ADDR,
I2C_EEPROM_LOW_ADDR,
0x12, // Msg Byte 1
0x34, // Msg Byte 2
0x56, // Msg Byte 3
0x78, // Msg Byte 4
0x9A, // Msg Byte 5
0xBC, // Msg Byte 6
0xDE, // Msg Byte 7
0xF0, // Msg Byte 8
0x11, // Msg Byte 9
0x10, // Msg Byte 10
0x11, // Msg Byte 11
0x12, // Msg Byte 12
0x13, // Msg Byte 13
0x12}; // Msg Byte 14
struct I2CMSG I2cMsgIn1={ I2C_MSGSTAT_SEND_NOSTOP,
I2C_SLAVE_ADDR,
I2C_NUMBYTES,
I2C_EEPROM_HIGH_ADDR,
I2C_EEPROM_LOW_ADDR};
struct I2CMSG *CurrentMsgPtr; // Used in interrupts
Uint16 PassCount;
Uint16 FailCount;
void DELAY_1US()
{Uint16 i;
for(i=0;i<1000;i++)
{
}
}
void main(void)
{
Uint16 Error;
Uint16 i;
CurrentMsgPtr = &I2cMsgOut1;
// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the DSP280x_SysCtrl.c file.
InitSysCtrl();
// Step 2. Initalize GPIO:
// This example function is found in the DSP280x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio();
// Setup only the GP I/O only for I2C functionality
InitI2CGpio();
// Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
DINT;
// Initialize PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the DSP280x_PieCtrl.c file.
InitPieCtrl();
// Disable CPU interrupts and clear all CPU interrupt flags:
IER = 0x0000;
IFR = 0x0000;
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in DSP280x_DefaultIsr.c.
// This function is found in DSP280x_PieVect.c.
InitPieVectTable();
// Interrupts that are used in this example are re-mapped to
// ISR functions found within this file.
EALLOW; // This is needed to write to EALLOW protected registers
PieVectTable.I2CINT1A = &i2c_int1a_isr;
EDIS; // This is needed to disable write to EALLOW protected registers
// Step 4. Initialize all the Device Peripherals:
// This function is found in DSP280x_InitPeripherals.c
// InitPeripherals(); // Not required for this example
I2CA_Init();
// Step 5. User specific code
// Clear Counters
PassCount = 0;
FailCount = 0;
// Clear incoming message buffer
for (i = 0; i < I2C_MAX_BUFFER_SIZE; i++)
{
I2cMsgIn1.MsgBuffer[i] = 0x0000;
}
// Enable interrupts required for this example
// Enable I2C interrupt 1 in the PIE: Group 8 interrupt 1
PieCtrlRegs.PIEIER8.bit.INTx1 = 1;
// Enable CPU INT8 which is connected to PIE group 8
IER |= M_INT8;
EINT;
CH452_Write(CH452_SYSON1); //两线制方式,如果SDA用做按键中断输出,那么命令应该为(0x04,0x23)
DELAY_1US();
CH452_Write(CH452_BCD); // BCD译码,8个数码管
DELAY_1US();
CH452_Write(CH452_DIG0 | 8); // 显示字符8
DELAY_1US();
CH452_Write(CH452_DIG1 | 8);
DELAY_1US();
CH452_Write(CH452_DIG2 | 8);
DELAY_1US();
CH452_Write(CH452_DIG3 | 8);
DELAY_1US();
CH452_Write(CH452_DIG4 | 8);
DELAY_1US();
CH452_Write(CH452_DIG5 | 8);
DELAY_1US();
CH452_Write(CH452_DIG6 | 8);
DELAY_1US();
CH452_Write(CH452_DIG7 | 8);
DELAY_1US();
//CH452_SDA_SET;
//CH452_SDA_CLR;
//CH452_SCL_SET;
//CH452_SCL_CLR;
// Application loop
for(;;)
{
CH452_Write(CH452_DIG0 | 8);
DELAY_1US();
DELAY_1US();
/*
//////////////////////////////////
// Write data to EEPROM section //
//////////////////////////////////
// Check the outgoing message to see if it should be sent.
// In this example it is initialized to send with a stop bit.
if(I2cMsgOut1.MsgStatus == I2C_MSGSTAT_SEND_WITHSTOP)
{
Error = I2CA_WriteData(&I2cMsgOut1);
// If communication is correctly initiated, set msg status to busy
// and update CurrentMsgPtr for the interrupt service routine.
// Otherwise, do nothing and try again next loop. Once message is
// initiated, the I2C interrupts will handle the rest. Search for
// ICINTR1A_ISR in the i2c_eeprom_isr.c file.
if (Error == I2C_SUCCESS)
{
CurrentMsgPtr = &I2cMsgOut1;
I2cMsgOut1.MsgStatus = I2C_MSGSTAT_WRITE_BUSY;
}
} // end of write section
///////////////////////////////////
// Read data from EEPROM section //
///////////////////////////////////
// Check outgoing message status. Bypass read section if status is
// not inactive.
if (I2cMsgOut1.MsgStatus == I2C_MSGSTAT_INACTIVE)
{
// Check incoming message status.
if(I2cMsgIn1.MsgStatus == I2C_MSGSTAT_SEND_NOSTOP)
{
// EEPROM address setup portion
while(I2CA_ReadData(&I2cMsgIn1) != I2C_SUCCESS)
{
// Maybe setup an attempt counter to break an infinite while
// loop. The EEPROM will send back a NACK while it is performing
// a write operation. Even though the write communique is
// complete at this point, the EEPROM could still be busy
// programming the data. Therefore, multiple attempts are
// necessary.
}
// Update current message pointer and message status
CurrentMsgPtr = &I2cMsgIn1;
I2cMsgIn1.MsgStatus = I2C_MSGSTAT_SEND_NOSTOP_BUSY;
}
// Once message has progressed past setting up the internal address
// of the EEPROM, send a restart to read the data bytes from the
// EEPROM. Complete the communique with a stop bit. MsgStatus is
// updated in the interrupt service routine.
else if(I2cMsgIn1.MsgStatus == I2C_MSGSTAT_RESTART)
{
// Read data portion
while(I2CA_ReadData(&I2cMsgIn1) != I2C_SUCCESS)
{
// Maybe setup an attempt counter to break an infinite while
// loop.
}
// Update current message pointer and message status
CurrentMsgPtr = &I2cMsgIn1;
I2cMsgIn1.MsgStatus = I2C_MSGSTAT_READ_BUSY;
}
} // end of read section
*/
} // end of for(;;)
} // end of main
void I2CA_Init(void)
{
// Initialize I2C
I2caRegs.I2CSAR = 0x0050; // Slave address - EEPROM control code
I2caRegs.I2CPSC.all = 9; // Prescaler - need 7-12 Mhz on module clk
I2caRegs.I2CCLKL = 10; // NOTE: must be non zero
I2caRegs.I2CCLKH = 5; // NOTE: must be non zero
I2caRegs.I2CIER.all = 0x24; // Enable SCD & ARDY interrupts
I2caRegs.I2CMDR.all = 0x0020; // Take I2C out of reset
⌨️ 快捷键说明
复制代码Ctrl + C
搜索代码Ctrl + F
全屏模式F11
增大字号Ctrl + =
减小字号Ctrl + -
显示快捷键?