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>NEC CEB-V850/SA1 Hardware Setup</TITLE

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CLASS="SECT1"

><H1

CLASS="SECT1"

><A

NAME="SETUP-V850-CEBSA1">NEC CEB-V850/SA1 Hardware Setup</H1

><P

>The CEB-V850 board is fitted with a socketed EPROM. The internal

Flash of the V850 supplied with the CEB-V850 boards defaults to

vectoring into this EPROM. A  GDB stub image should be programmed

into an EPROM fitted to this board, and a pre-built image is provided

at <TT

CLASS="FILENAME"

>loaders/v850-ceb_v850/v850sa1/gdb_module.bin </TT

>under

the root of your eCos installation.</P

><P

>The EPROM is installed to the socket labelled U7 on the board.

Attention should be paid to the correct orientation of the EPROM

during installation. </P

><P

>When programming an EPROM using the binary image, be careful

to get the byte order correct. It needs to be little-endian. If

the EPROM burner software has a hex-editor, check that the first

few bytes of the image look similar to: </P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>00000000: 0018 8007 5e02 0000 0000 0000 0000 0000</PRE

></TD

></TR

></TABLE

><P

>If the byte order is wrong you will see 1800 instead of 0018

etc. Use the EPROM burner software to make a byte-swap before you

burn to image to the EPROM. </P

><P

>If the GDB stub EPROM you burn does not work, try reversing

the byte-order, even if you think you have it the right way around.

At least one DOS-based EPROM burner program is known to have the

byte-order upside down.</P

><P

>The GDB stub in the EPROM allows communication with GDB using

the serial port. The communication parameters are fixed at 38400

baud, 8 data bits, no parity bit and 1 stop bit (8-N-1). No flow

control is employed. Connection to the host computer should be made

using a dedicated serial cable as specified in the CEB-V850/SA1

manual.</P

><DIV

CLASS="SECT2"

><H2

CLASS="SECT2"

><A

NAME="AEN4279">Installing the Stubs into ROM</H2

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4281">Preparing the Binaries</H3

><P

>These two binary preparation steps are not strictly necessary

as the eCos distribution ships with pre-compiled binaries in the

directory loaders/v850-ceb_v850 relative to the

installation root.</P

><DIV

CLASS="SECT4"

><H4

CLASS="SECT4"

><A

NAME="AEN4284">Building the ROM images with the eCos Configuration Tool</H4

><P

></P

><OL

TYPE="1"

><LI

><P

>Start with a new document - selecting the

<SPAN

CLASS="emphasis"

><I

CLASS="EMPHASIS"

>File-&#62;New</I

></SPAN

>

 menu item if necessary to do this.</P

></LI

><LI

><P

>Choose the

<SPAN

CLASS="emphasis"

><I

CLASS="EMPHASIS"

>Build-&#62;Templates</I

></SPAN

>

 menu item, and then select the NEC CEB-V850/SA1 hardware.</P

></LI

><LI

><P

>While still displaying the

<SPAN

CLASS="emphasis"

><I

CLASS="EMPHASIS"

>Build-&#62;Templates</I

></SPAN

>

 dialog box, select the “stubs” package template

to build a GDB stub. Click

<SPAN

CLASS="emphasis"

><I

CLASS="EMPHASIS"

>OK</I

></SPAN

>.</P

></LI

><LI

><P

>Build eCos using

<SPAN

CLASS="emphasis"

><I

CLASS="EMPHASIS"

>Build-&#62;Library</I

></SPAN

>. </P

></LI

><LI

><P

>When the build completes, the image files can be found

in the bin/ subdirectory of the install tree. GDB stub

ROM images have the  prefix &#8220;gdb_module&#8221;.</P

></LI

></OL

></DIV

><DIV

CLASS="SECT4"

><H4

CLASS="SECT4"

><A

NAME="AEN4302">Building the ROM images with ecosconfig</H4

><P

></P

><OL

TYPE="1"

><LI

><P

>Make an empty directory to contain the build tree,

and cd into it. </P

></LI

><LI

><P

>To build a GDB stub ROM image, enter the command:

<TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>$ ecosconfig new ceb-v850 stubs </PRE

></TD

></TR

></TABLE

></P

></LI

><LI

><P

>Enter the commands:

<TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>$ ecosconfig tree

$ make</PRE

></TD

></TR

></TABLE

>

 </P

></LI

><LI

><P

>When the build completes, the image files can be found

in the bin/ subdirectory of the install tree. GDB stub

ROM images have the prefix &#8220;gdb_module&#8221;.</P

></LI

></OL

></DIV

></DIV

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4315">Installing the Stubs into ROM or FLASH</H3

><P

></P

><OL

TYPE="1"

><LI

><P

> Program the binary image file gdb_module.bin

into ROM or FLASH referring to the instructions of your ROM

                  programmer. </P

></LI

><LI

><P

> Plug the ROM/FLASH into the socket as described

at the beginning of this section.</P

></LI

></OL

></DIV

></DIV

><DIV

CLASS="SECT2"

><H2

CLASS="SECT2"

><A

NAME="AEN4322">Debugging with the NEC V850 I.C.E.</H2

><P

>eCos applications may be debugged using the NEC V850 In Circuit

Emulator (I.C.E.) A PC running Microsoft Windows is required in

order to run the NEC ICE software and drivers. In addition Red Hat

have developed a “libremote” server application

named v850ice.exe which is used on the PC connected to the I.C.E.

in order to allow connections from GDB.</P

><P

>The I.C.E. must be physically connected to a Windows NT system

through NEC"s PCI or PC Card interface.  A driver, DLLs,

and application are provided by NEC to control the I.C.E.</P

><P

>v850ice is a Cygwin based server that runs on the NT system

and provides an interface between the gdb client and the I.C.E.

software. v850-elf-gdb may be run on the Windows NT system or on

a remote system. v850-elf-gdb communicates with the libremote server

using the gdb remote protocol over a TCP/IP socket.  v850ice

communicates with the I.C.E. by calling functions in the NECMSG.DLL provided

by NEC.</P

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4327">INITIAL SETUP</H3

><P

></P

><OL

TYPE="1"

><LI

><P

>Configure the hardware including the I.C.E., SA1 or

SB1 Option Module, and target board.  Install the interface card

in the Windows NT system. Reference NEC"s documentation

for interface installation, jumper settings, etc.</P

></LI

><LI

><P

>Install the Windows NT device driver provided by NEC.</P

></LI

><LI

><P

>Copy the NEC DLLs, MDI application, and other support

files to a directory on the Windows NT system. The standard location

is C:\NecTools32. This directory will be referred to as

the "libremote server directory" in this document. v850ice.exe must

also be copied to this directory after being built. The required

files are:  cpu.cfg, Nec.cfg, MDI.EXE, NECMSG.DLL, EX85032.DLL,

V850E.DLL, IE850.MON, IE850E.MON, and D3037A.800.</P

></LI

><LI

><P

>Make certain the file cpu.cfg contains the line:</P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>CpuOption=SA1</PRE

></TD

></TR

></TABLE

><P

>if using a V850/SA1 module, or:</P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>CpuOption=SB1</PRE

></TD

></TR

></TABLE

><P

>if using a V850/SB1 module.</P

></LI

><LI

><P

>Set the environment variable IEPATH to point to the libremote

server</P

><P

>directory.</P

></LI

></OL

></DIV

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4345">BUILD PROCEDURES</H3

><P

>A pre-built v850ice.exe executable is supplied in the loaders/v850-ceb_v850 directory

relative to the root of the eCos installation. However the following process

will allow the rebuilding of this executable if required:</P

><P

>For this example assume the v850ice libremote tree has been

copied to a directory named "server".  The directory structure will

be similar to the following diagram:</P

><P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>                server

                   |

                 devo

                 /  \

           config    libremote

                      /     \

                   lib       v850ice</PRE

></TD

></TR

></TABLE

></P

><P

>Build the v850ice source as follows.  Be sure to use the native

Cygwin compiler tools that were supplied alongside eCos.</P

><P

>cd server

mkdir build

cd build

../devo/configure --target=v850-elf --host=i686-pc-cygwin

make</P

><P

>The resultant libremote server image (v850ice.exe) can be

found in build/libremote/v850ice.  Copy v850ice.exe

to the lib remote server directory.</P

></DIV

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4354">V850ICE.EXE EXECUTION</H3

><P

>The v850ice command line syntax is:</P

><P

>v850ice [-d] [-t addr] [port number]</P

><P

>The optional -d option enables debug output.  The -t option

is associated with thread debugging - see the "eCos thread debugging"

section below for details. By default v850ice listens on port 2345

for an attach request from a gdb client.  A different port number

may be specified on the command line.</P

><P

>To run the libremote server:</P

><P

></P

><OL

TYPE="1"

><LI

><P

>Power on the I.C.E. and target board.</P

></LI

><LI

><P

>Open a Cygwin window.</P

></LI

><LI

><P

>Run v850ice.</P

></LI

><LI

><P

>You will see the MDI interface window appear.  In this

window you should see the "Connected to In-Circuit Emulator" message.

 In the Cygwin window, the libremote server will indicate it is

ready to accept a gdb client connection with the message "v850ice:

 listening on port 2345."</P

></LI

></OL

></DIV

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4369">V850-ELF-GDB EXECUTION</H3

><P

>Run the v850-elf-gdb client to debug the V850 target.  It

is necessary to issue certain configuration commands to the I.C.E.

software.  These commands may be issued directly in the MDI window

or they may be issued from the gdb client through the "monitor"

command.</P

><P

>On the Cosmo CEB-V850 board, on-chip Flash is mapped at address

0x0, the on-board EPROM at 0x100000 and the on-board RAM at 0xfc0000.

Since a stand alone V850 will start executing from address 0x0 on

reset, it is normal to load either an application or a bootstrap

loader for Flash at this address. eCos programs may be built to

boot from Flash or the on-board EPROM. If building for the on-board

EPROM, it would be expected that the Flash will contain the default

CEB-V850 flash contents. An ELF format version of the default contents

may be found in the eCos distribution with the name v850flash.img.</P

><P

>In stand alone operation, normally the code in this flash image

would have been programmed into the V850 on the Cosmo board, and

this would cause it to vector into the on-board EPROM to run the

application located there. In the case of eCos, this application

may be a GDB stub ROM application, allowing the further download

to RAM over serial of actual applications to debug.</P

><P

>As an example, we shall demonstrate how to use the I.C.E.

to download the v850flash.img and GDB stub EPROM image using I.C.E.

emulator memory only, and not requiring any actual programming of

devices.</P

><P

>v850-elf-gdb -nw

(gdb) file v850flash.img

(gdb) target remote localhost:2345

(gdb) monitor reset

(gdb) monitor cpu r=256 a=16

(gdb) monitor map r=0x100000-L 0x80000

(gdb) monitor map u=0xfc0000-L 0x40000

(gdb) monitor pinmask k

(gdb) monitor step

(gdb) monitor step

(gdb) monitor step

(gdb) monitor step

(gdb) load

(gdb) detach

(gdb) file gdb_module.img

(gdb) target remote localhost:2345

(gdb) load

(gdb) continue</P

><P

>NOTE: The four "monitor step" commands are only required the

first time the board is connected to the I.C.E., otherwise the program

will fail.</P

><P

>This is because of a limitation of the I.C.E. hardware that

means that the first time it is used, the "map" commands are not

acted on and the addresses "0x100000" and "0xfc0000" are not mapped.

This can be observed using the command "td e-20" in the MDI application"s

console to display the trace buffer, which will show that the contents

of address 0x100000 are not valid. Subsequent runs do not require

the "monitor step" commands.</P

><P

>It is unusual to load two executable images to a target through

gdb.  From the example above notice that this is accomplished by

attaching to the libremote server, loading the flash image, detaching,

reattaching, and loading the ROM/RAM image. It is more

normal to build an executable image that can be executed directly.

In eCos this is achieved by selecting either the ROM or ROMRAM startup

type, and optionally enable building for the internal FLASH. The

I.C.E. emulator memory can emulate both the internal FLASH and the

EPROM, so real hardware programming is not required.</P

><P

>Upon running this example you will notice that the libremote

server does not exit upon detecting a detach request, but simply

begins listening for the next attach request.  To cause v850ice

to terminate, issue the "monitor quit" or "monitor exit" command

from the gdb client.  v850ice will then terminate with the next

detach request.  (You can also enter control-c in the Cygwin/DOS

window where v850ice is running.)</P

></DIV

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4380">MDI INTERFACE VS. GDB INTERFACE</H3

><P

>If a filename is referenced in an MDI command, whether the

command is entered in the MDI window or issued from the gdb client

with the monitor command, the file must reside on the Windows NT

libremote server system.  When specifying a filename when entering

a command in the MDI window it is obvious that a server local file

is being referenced.  When issuing an MDI command from the gdb client, the

user must remember that the command line is simply passed to the

I.C.E. software on the server system.  The command is executed by

the I.C.E. software as though it were entered locally.</P

><P

>Executable images may be loaded into the V850 target by entering

the "load" command in the MDI window or with the gdb "load" command.

 If the MDI load command is used, the executable image must be located

on the server system and must be in S Record format.  If the gdb

load command is used, the executable image must be located on the

client system and must be in ELF format.</P

><P

>Be aware that the gdb client is not aware of debugger commands

issued from the MDI window.  It is possible to cause the gdb client

and the I.C.E. software to get out of sync by issuing commands from

both interfaces during the same debugging session.</P

></DIV

><DIV

CLASS="SECT3"

><H3

CLASS="SECT3"

><A

NAME="AEN4385">eCos THREAD DEBUGGING</H3

><P

>eCos and the V850 I.C.E. libremote server have been written

to work together to allow debugging of eCos threads. This is an

optional feature, disabled by default because of the overheads trying

to detect a threaded program involves.</P

><P

>Obviously thread debugging is not possible for programs with

"RAM" startup type, as they are expected to operate underneath a

separate ROM monitor (such as a GDB stub ROM), that itself would

provide its own thread debugging capabilities over the serial line.

Thread debugging is relevant only for programs built for Flash, ROM,

or ROMRAM startup.</P

><P

>To configure the libremote server to support thread debugging,

use the command:</P

><P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>(gdb) monitor syscallinfo ADDRESS</PRE

></TD

></TR

></TABLE

></P

><P

>at the GDB console prompt, where ADDRESS is the address of

the syscall information structure included in the applications.

In eCos this has been designed to be located at a consistent address

for each CPU model (V850/SA1 or V850/SB1). It

may be determined from an eCos executable using the following command

at a cygwin bash prompt:</P

><P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>v850-elf-nm EXECUTABLE | grep hal_v85x_ice_syscall_info</PRE

></TD

></TR

></TABLE

></P

><P

>At the current time, this address is 0xfc0400 for a Cosmo

board fitted with a V850/SA1, or 0xfc0540 for a Cosmo board

fitted with a V850/SB1.</P

><P

>So for example, the GDB command for the SB1 would be:</P

><P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>(gdb) monitor syscallinfo 0xfc0540</PRE

></TD

></TR

></TABLE

></P

><P

>Given that the syscallinfo address is fixed over all eCos

executables for a given target, it is possible to define it on the

libremote command line as well using the "-t" option, for example:</P

><P

><TABLE

BORDER="5"

BGCOLOR="#E0E0F0"

WIDTH="70%"

><TR

><TD

><PRE

CLASS="PROGRAMLISTING"

>bash$ v850ice -t 0xfc0400

v850ice: listening on port 2345</PRE

></TD

></TR

></TABLE

></P

></DIV

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