原文出处： http://blog.csdn.net/embbnux/article/details/17619621

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之前建立stm32开发环境,程序也已经编译好生成main.bin,接下来就是要把该文件烧录到stm32上.在linux下给arm烧录程序主要使用openocd,这个软件开源,而且支持众多芯片,从ARM9到A8都可以,当然STM32也可以.支持的JTAG工具也很多,JLINK ST-LINK OSBDM都可以,我这正好有一个openjtag基于FT2232C的,也是被支持的.

       个人原创,转载请注明

      参考:

           How-to manual  Installing a toolchain for Cortex-M3/STM32 on Ubuntu   by Peter Seng

一  安装openocd

      在ubuntu下安装openocd

      

sudo apt-get install openocd

      也可以到官网下载源码包自己编译

二 安装openjtag驱动

      插上openjtag

user@ubuntu:~/$ lsusb

Bus 002 Device 005: ID 093a:2521 Pixart Imaging, Inc.

Bus 002 Device 003: ID 1457:5118 First International Computer, Inc. OpenMoko Neo1973 Debug board (V2+)

   第二个就是了,记下ID 1457:5118

sudo gedit /etc/udev/rules.d/45-ftdi2232-libftdi.rules   在里面添加

SYSFS{idProduct}=="5118", SYSFS{idVendor}=="1457", MODE="666", GROUP="plugdev"

   权限666,使用openocd就不用sudo了.

sudo /etc/init.d/udev restart

拔下在插上就可以了.

三 使用openocd 连openjtag

      JTAG接口配置文件openjtag.cfg.根据JTAG设备不同,修改下面

 

#interface configuration openjtag#############################

interface ft2232

ft2232_device_desc "USB<=>JTAG&RS232"

ft2232_layout jtagkey

ft2232_vid_pid 0x1457 0x5118

    可以参考openocd目录下的文件:/usr/share/openocd/scripts/interface,主要是设备ID以及设备名字,可以通过dmesg | grep usb命令查看.

    要烧录stm32f103就得有这个设备的相关配置,可以查看/usr/share/openocd/scripts/target/stm32f1x.cfg

 这里把两个文件合在一起openocd.cfg

#daemon configuration###############################################################

telnet_port 4444

gdb_port 3333

#interface configuration openjtag#############################

interface ft2232

ft2232_device_desc "USB<=>JTAG&RS232"

ft2232_layout jtagkey

ft2232_vid_pid 0x1457 0x5118

#board configuration################################################################

# Adjust Work-area size (RAM size) according to MCU in use:

#STM32F103RB --> 20KB

#set WORKAREASIZE 0x5000

#STM32F103ZE --> 64KB

set WORKAREASIZE 0x10000

#target configuration###############################################################

# script for stm32f1x family

if { [info exists CHIPNAME] } {

set _CHIPNAME $CHIPNAME

} else {

set _CHIPNAME stm32f1x

}

if { [info exists ENDIAN] } {

set _ENDIAN $ENDIAN

} else {

set _ENDIAN little

}

# Work-area is a space in RAM used for flash programming

# By default use 16kB

if { [info exists WORKAREASIZE] } {

set _WORKAREASIZE $WORKAREASIZE

} else {

set _WORKAREASIZE 0x4000

}

# JTAG speed should be <= F_CPU/6. F_CPU after reset is 8MHz, so use F_JTAG = 1MHz

adapter_khz 500

adapter_nsrst_delay 100

jtag_ntrst_delay 100

#jtag scan chain

if { [info exists CPUTAPID] } {

set _CPUTAPID $CPUTAPID

} else {

# See STM Document RM0008

# Section 31.6.3

set _CPUTAPID 0x3ba00477

}

jtag newtap $_CHIPNAME cpu -irlen 4 -ircapture 0x1 -irmask 0xf -expected-id $_CPUTAPID

if { [info exists BSTAPID] } {

# FIXME this never gets used to override defaults...

set _BSTAPID $BSTAPID

} else {

# See STM Document RM0008

# Section 31.6.2

# Low density devices, Rev A

set _BSTAPID1 0x06412041

# Medium density devices, Rev A

set _BSTAPID2 0x06410041

# Medium density devices, Rev B and Rev Z

set _BSTAPID3 0x16410041

set _BSTAPID4 0x06420041

# High density devices, Rev A

set _BSTAPID5 0x06414041

# Connectivity line devices, Rev A and Rev Z

set _BSTAPID6 0x06418041

# XL line devices, Rev A

set _BSTAPID7 0x06430041

# VL line devices, Rev A and Z In medium-density and high-density value line devices

set _BSTAPID8 0x06420041

# VL line devices, Rev A

set _BSTAPID9 0x06428041

}

jtag newtap $_CHIPNAME bs -irlen 5 -expected-id $_BSTAPID1 \

    -expected-id $_BSTAPID2 -expected-id $_BSTAPID3 \

    -expected-id $_BSTAPID4 -expected-id $_BSTAPID5 \

    -expected-id $_BSTAPID6 -expected-id $_BSTAPID7 \

    -expected-id $_BSTAPID8 -expected-id $_BSTAPID9

set _TARGETNAME $_CHIPNAME.cpu

target create $_TARGETNAME cortex_m -endian $_ENDIAN -chain-position $_TARGETNAME

$_TARGETNAME configure -work-area-phys 0x20000000 -work-area-size $_WORKAREASIZE -work-area-backup 0

# flash size will be probed

set _FLASHNAME $_CHIPNAME.flash

flash bank $_FLASHNAME stm32f1x 0x08000000 0 0 0 $_TARGETNAME

# if srst is not fitted use SYSRESETREQ to

# perform a soft reset

cortex_m reset_config sysresetreq

开始烧录:

  < 1 >  在一个终端下执行:

openocd -f openocd.cfg

出现:

Open On-Chip Debugger 0.7.0 (2013-05-15-17:28)

Licensed under GNU GPL v2

For bug reports, read

    http://openocd.sourceforge.net/doc/doxygen/bugs.html

Info : only one transport option; autoselect 'jtag'

adapter speed: 500 kHz

adapter_nsrst_delay: 100

jtag_ntrst_delay: 100

cortex_m3 reset_config sysresetreq

Info : clock speed 500 kHz

Info : JTAG tap: stm32f1x.cpu tap/device found: 0x3ba00477 (mfg: 0x23b, part: 0xba00, ver: 0x3)

Info : JTAG tap: stm32f1x.bs tap/device found: 0x06414041 (mfg: 0x020, part: 0x6414, ver: 0x0)

Info : stm32f1x.cpu: hardware has 6 breakpoints, 4 watchpoints

没有提示出错,就表示连接上STM32了 .如果出现出错,就在开发板上按下RESET 键复位,查看BOOT0和BOOT1有没有设置出错.

< 2 > 在另一个终端下,输入:

       

telnet localhost 4444

依次输入:

reset halt

flash probe 0

stm32f1x mass_erase 0

flash write_bank 0 /you_stm32_project_dir/main.bin 0

reset run

程序就烧好了,按下reset键,就开始运行了.

 要输入这么多命令太麻烦了,写个perl脚本使它一步运行.

首先安装perl-telnet

    

sudo apt-get install libnet-telnet-perl

  在工程目录下新建do_flash.pl文件

#!/usr/bin/perl

use Net::Telnet;

$numArgs = $#ARGV + 1;

if($numArgs != 1){

die( "Usage ./do_flash.pl [main.bin] \n");

}

$file = $ARGV[0];

$ip = "127.0.0.1";

$port = 4444;

$telnet = new Net::Telnet (

Port => $port,

Timeout=>10,

Errmode=>'die',

Prompt =>'/>/');

$telnet->open($ip);

print $telnet->cmd('reset halt');

print $telnet->cmd('flash probe 0');

print $telnet->cmd('stm32f1x mass_erase 0');

print $telnet->cmd('flash write_bank 0 '.$file.' 0');

print $telnet->cmd('reset halt');

print $telnet->cmd('exit');

print "\n";

   在根目录下的Makefile文件里面加入这段语句:

flash:all

    ./do_flash.pl $(TOP)/main.bin

这样只要,执行make flash就可以直接运行第二步了,方便简介.