芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
Susan Yang:请您参考下C2000WARE内例程
C:\ti\c2000\C2000Ware_2_00_00_02\device_support\f2806x\examples\c28\watchdog
芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
Susan Yang:
//########################################################################### // // FILE: Example_2806xWatchdog.c // // TITLE: Watchdog interrupt Test Example // //!\addtogroup f2806x_example_list //!<h1>Watchdog interrupt Test(watchdog)</h1> //! //!This program exercises the watchdog. //! //!First the watchdog is connected to the WAKEINT interrupt of the //!PIE block.The code is then put into an infinite loop. //! //!The user can select to feed the watchdog key register or not //!by commenting the following line of code in the infinite loop: //!\b ServiceDog(); \n //! //!If the watchdog key register is fed by the ServiceDog function //!then the WAKEINT interrupt is not taken.If the key register //!is not fed by the ServiceDog function then WAKEINT will be taken. //! //!\b Watch \b Variables \n //!- \b LoopCount , for the number of times through the infinite loop //!- \b WakeCount , for the number of times through WAKEINT // //########################################################################### // $TI Release: F2806x Support Library v2.04.00.00 $ // $Release Date: Mon May 27 06:46:38 CDT 2019 $ // $Copyright: // Copyright (C) 2009-2019 Texas Instruments Incorporated - http://www.ti.com/ // // Redistribution and use in source and binary forms, with or without// modification, are permitted provided that the following conditions// are met: ////Redistributions of source code must retain the above copyright//notice, this list of conditions and the following disclaimer. ////Redistributions in binary form must reproduce the above copyright //notice, this list of conditions and the following disclaimer in the//documentation and/or other materials provided with the//distribution. ////Neither the name of Texas Instruments Incorporated nor the names of //its contributors may be used to endorse or promote products derived //from this software without specific prior written permission. //// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // $ //###########################################################################// // Included Files // #include "DSP28x_Project.h"// Device Headerfile and Examples Include File// // Function Prototypes // __interrupt void wakeint_isr(void);// // Globals // Uint32 WakeCount; Uint32 LoopCount;// // Main // void main(void) {//// Step 1. Initialize System Control:// PLL, WatchDog, enable Peripheral Clocks// This example function is found in the F2806x_SysCtrl.c file.//InitSysCtrl();//// Step 2. Initalize GPIO:// This example function is found in the F2806x_Gpio.c file and// illustrates how to set the GPIO to it's default state.//// InitGpio();// Skipped for this example//// 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 F2806x_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 F2806x_DefaultIsr.c.// This function is found in F2806x_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 registersPieVectTable.WAKEINT = &wakeint_isr;EDIS;// This is needed to disable write to EALLOW protected registers//// Step 4. Initialize all the Device Peripherals:// This function is found in F2806x_InitPeripherals.c////InitPeripherals(); // Not required for this example//// Step 5. User specific code, enable interrupts////// Clear the counters//WakeCount = 0; // Count interruptsLoopCount = 0; // Count times through idle loop//// Connect the watchdog to the WAKEINT interrupt of the PIE// Write to the whole SCSR register to avoid clearing WDOVERRIDE bit//EALLOW;SysCtrlRegs.SCSR = BIT1;EDIS;//// Enable WAKEINT in the PIE: Group 1 interrupt 8// Enable INT1 which is connected to WAKEINT://PieCtrlRegs.PIECTRL.bit.ENPIE = 1;// Enable the PIE blockPieCtrlRegs.PIEIER1.bit.INTx8 = 1;// Enable PIE Gropu 1 INT8IER |= M_INT1;// Enable CPU INT1EINT;// Enable Global Interrupts//// Reset the watchdog counter//ServiceDog();//// Enable the watchdog//EALLOW;SysCtrlRegs.WDCR = 0x0028;EDIS;//// Step 6. IDLE loop. Just sit and loop forever (optional)//for(;;){LoopCount++;//// Uncomment ServiceDog to just loop here// Comment ServiceDog to take the WAKEINT instead//ServiceDog();} }// // Step 7. Insert all local Interrupt Service Routines (ISRs) and functions// here: If local ISRs are used, reassign vector addresses in vector table as // shown in Step 5 //// // wakeint_isr -// __interrupt void wakeint_isr(void) {WakeCount++;//// Acknowledge this interrupt to get more from group 1//PieCtrlRegs.PIEACK.all = PIEACK_GROUP1; }// // End of File //
芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
mangui zhang:看看能不能进入到中断参考下面帖子
e2echina.ti.com/…/147938
芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
user5170101:
回复 mangui zhang:
我现在用例程 不喂狗 连中断都进不了
芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
user5170101:
回复 Susan Yang:
我现在用例程 不喂狗 连中断都进不了
我的cmd文件:
/*//###########################################################################//// FILE: F28069.cmd//// TITLE: Linker Command File For F28069 Device////###########################################################################// $TI Release: F2806x C/C++ Header Files and Peripheral Examples V135 $ // $Release Date: Sep 8, 2012 $ //###########################################################################*/
/* ======================================================// For Code Composer Studio V2.2 and later// —————————————// In addition to this memory linker command file,// add the header linker command file directly to the project.// The header linker command file is required to link the// peripheral structures to the proper locations within// the memory map.//// The header linker files are found in <base>\F2806x_headers\cmd//// For BIOS applications add: F2806x_Headers_BIOS.cmd// For nonBIOS applications add: F2806x_Headers_nonBIOS.cmd========================================================= */
/* ======================================================// For Code Composer Studio prior to V2.2// ————————————–// 1) Use one of the following -l statements to include the// header linker command file in the project. The header linker// file is required to link the peripheral structures to the proper// locations within the memory map */
/* Uncomment this line to include file only for non-BIOS applications *//* -l F2806x_Headers_nonBIOS.cmd */
/* Uncomment this line to include file only for BIOS applications *//* -l F2806x_Headers_BIOS.cmd */
/* 2) In your project add the path to <base>\F2806x_headers\cmd to the library search path under project->build options, linker tab, library search path (-i). *//*========================================================= */
/* Define the memory block start/length for the F2806x PAGE 0 will be used to organize program sections PAGE 1 will be used to organize data sections
Notes: Memory blocks on F28069 are uniform (ie same physical memory) in both PAGE 0 and PAGE 1. That is the same memory region should not be defined for both PAGE 0 and PAGE 1. Doing so will result in corruption of program and/or data.
Contiguous SARAM memory blocks can be combined if required to create a larger memory block.*/
MEMORY{PAGE 0 : /* Program Memory */ /* Memory (RAM/FLASH/OTP) blocks can be moved to PAGE1 for data allocation */ RAML0_1 : origin = 0x008000, length = 0x000C00 /* on-chip RAM block L0 and L1 */ OTP : origin = 0x3D7800, length = 0x000400 /* on-chip OTP */
FLASHH : origin = 0x3D8000, length = 0x004000 /* on-chip FLASH */ FLASHG : origin = 0x3DC000, length = 0x004000 /* on-chip FLASH */ FLASHF : origin = 0x3E0000, length = 0x004000 /* on-chip FLASH */ FLASHE : origin = 0x3E4000, length = 0x004000 /* on-chip FLASH */ FLASHD : origin = 0x3E8000, length = 0x004000 /* on-chip FLASH */ //FLASHC : origin = 0x3EC000, length = 0x004000 /* on-chip FLASH */ FLASHA_B : origin = 0x3EC000, length = 0x00BF80 /* on-chip FLASH */ CSM_RSVD : origin = 0x3F7F80, length = 0x000076 /* Part of FLASHA. Program with all 0x0000 when CSM is in use. */ BEGIN : origin = 0x3F7FF6, length = 0x000002 /* Part of FLASHA. Used for "boot to Flash" bootloader mode. */ CSM_PWL_P0 : origin = 0x3F7FF8, length = 0x000008 /* Part of FLASHA. CSM password locations in FLASHA */
FPUTABLES : origin = 0x3FD590, length = 0x0006A0 /* FPU Tables in Boot ROM */ IQTABLES : origin = 0x3FDC30, length = 0x000B50 /* IQ Math Tables in Boot ROM */ IQTABLES2 : origin = 0x3FE780, length = 0x00008C /* IQ Math Tables in Boot ROM */ IQTABLES3 : origin = 0x3FE80C, length = 0x0000AA /* IQ Math Tables in Boot ROM */
ROM : origin = 0x3FF3B0, length = 0x000C10 /* Boot ROM */ RESET : origin = 0x3FFFC0, length = 0x000002 /* part of boot ROM */ VECTORS : origin = 0x3FFFC2, length = 0x00003E /* part of boot ROM */
PAGE 1 : /* Data Memory */ /* Memory (RAM/FLASH/OTP) blocks can be moved to PAGE0 for program allocation */ /* Registers remain on PAGE1 */
BOOT_RSVD : origin = 0x000000, length = 0x000050 /* Part of M0, BOOT rom will use this for stack */ RAMM0 : origin = 0x000050, length = 0x0003B0 /* on-chip RAM block M0 */ RAMM1 : origin = 0x000400, length = 0x000400 /* on-chip RAM block M1 */ RAML2_3 : origin = 0x008C00, length = 0x001400 /* on-chip RAM block L2 */ RAML4 : origin = 0x00A000, length = 0x002000 /* on-chip RAM block L4 */ RAML5 : origin = 0x00C000, length = 0x002000 /* on-chip RAM block L5 */ RAML6 : origin = 0x00E000, length = 0x002000 /* on-chip RAM block L6 */ RAML7 : origin = 0x010000, length = 0x002000 /* on-chip RAM block L7 */ RAML8 : origin = 0x012000, length = 0x001800 /* on-chip RAM block L8. From 0x13800 to 0x14000 is reserved for InstaSPIN */ USB_RAM : origin = 0x040000, length = 0x000800 /* USB RAM */ }
/* Allocate sections to memory blocks. Note: codestart user defined section in DSP28_CodeStartBranch.asm used to redirect code execution when booting to flash ramfuncs user defined section to store functions that will be copied from Flash into RAM*/
SECTIONS{
/* Allocate program areas: */ .cinit : > FLASHA_B, PAGE = 0 .pinit : > FLASHA_B, PAGE = 0 .text : > FLASHA_B, PAGE = 0 codestart : > BEGIN, PAGE = 0 ramfuncs : LOAD = FLASHD, RUN = RAML0_1, LOAD_START(_RamfuncsLoadStart), LOAD_END(_RamfuncsLoadEnd), RUN_START(_RamfuncsRunStart), PAGE = 0
csmpasswds : > CSM_PWL_P0, PAGE = 0 csm_rsvd : > CSM_RSVD, PAGE = 0
/* Allocate uninitalized data sections: */ .stack : > RAMM0, PAGE = 1 .ebss : > RAML2_3, PAGE = 1 .esysmem : > RAML2_3, PAGE = 1
/* Initalized sections to go in Flash */ /* For SDFlash to program these, they must be allocated to page 0 */ .econst : > FLASHA_B, PAGE = 0 .switch : > FLASHA_B, PAGE = 0
/* Allocate IQ math areas: */ IQmath : > FLASHA_B, PAGE = 0 /* Math Code */ IQmathTables : > IQTABLES, PAGE = 0, TYPE = NOLOAD /* Allocate FPU math areas: */ FPUmathTables : > FPUTABLES, PAGE = 0, TYPE = NOLOAD DMARAML5 : > RAML5, PAGE = 1 DMARAML6 : > RAML6, PAGE = 1 DMARAML7 : > RAML7, PAGE = 1 DMARAML8 : > RAML8, PAGE = 1
/* Uncomment the section below if calling the IQNexp() or IQexp() functions from the IQMath.lib library in order to utilize the relevant IQ Math table in Boot ROM (This saves space and Boot ROM is 1 wait-state). If this section is not uncommented, IQmathTables2 will be loaded into other memory (SARAM, Flash, etc.) and will take up space, but 0 wait-state is possible. */ /* IQmathTables2 : > IQTABLES2, PAGE = 0, TYPE = NOLOAD {
IQmath.lib<IQNexpTable.obj> (IQmathTablesRam)
} */ /* Uncomment the section below if calling the IQNasin() or IQasin() functions from the IQMath.lib library in order to utilize the relevant IQ Math table in Boot ROM (This saves space and Boot ROM is 1 wait-state). If this section is not uncommented, IQmathTables3 will be loaded into other memory (SARAM, Flash, etc.) and will take up space, but 0 wait-state is possible. */ /* IQmathTables3 : > IQTABLES3, PAGE = 0, TYPE = NOLOAD {
IQmath.lib<IQNasinTable.obj> (IQmathTablesRam)
} */
/* .reset is a standard section used by the compiler. It contains the */ /* the address of the start of _c_int00 for C Code. */ /* When using the boot ROM this section and the CPU vector */ /* table is not needed. Thus the default type is set here to */ /* DSECT */ .reset : > RESET, PAGE = 0, TYPE = DSECT vectors : > VECTORS, PAGE = 0, TYPE = DSECT
}
/*//===========================================================================// End of file.//===========================================================================*/
芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
mangui zhang:
回复 user5170101:
1) Make sure SCSR.WDENINT = 0; //Disable WD interrupt and enable wd reset condition
2) Write WDCR = 0;
芯片F28069
初始化并使能:
void WDIOInit(void)
{
//配置SCSR
EALLOW;//关闭保护、
//将中断信号WDINT使能,且允许屏蔽看门狗
SysCtrlRegs.SCSR = 0x0002;//0010
EDIS;//打开保护
EnableDog();
}
void EnableDog(void)
{
EALLOW;
SysCtrlRegs.WDCR= 0x0028; //0010 1000
EDIS;
}
没有喂狗,但程序没有复位,我复位后会有灯亮,我最后步调观看看门狗寄存器的时候,发现配置的时候,寄存器值个我写入的不一样,好像就没写入到寄存器里面?
Green Deng:
回复 user5170101:
请问你的问题是否已经解决?