Difference between revisions of "How to boot from MicroSD Card"

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Notes: The kernel binary resides inside the directory: $/home/jdoe/linux-omap-2.6/arch/arm/boot/'''zImage'''
 
Notes: The kernel binary resides inside the directory: $/home/jdoe/linux-omap-2.6/arch/arm/boot/'''zImage'''
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Alternatively you can download the kernel binary from this [http://downloads.isee.biz/pub/releases/linux_kernel/v2.6.37-3/zImage-2.6.37-3.bin link] and modules from [http://downloads.isee.biz/pub/releases/linux_kernel/v2.6.37-3/modules-2.6.37-3.tar.gz this].
 
Alternatively you can download the kernel binary from this [http://downloads.isee.biz/pub/releases/linux_kernel/v2.6.37-3/zImage-2.6.37-3.bin link] and modules from [http://downloads.isee.biz/pub/releases/linux_kernel/v2.6.37-3/modules-2.6.37-3.tar.gz this].
  

Revision as of 16:15, 10 July 2012

Overview

This how to explains how to create a customized microSD card to boot IGEPv2 or IGEP COM MODULE with other software distributions.

That is, you can boot your IGEP Processor Boards with a different distribution than the pre-installed by ISEE (manufacturer).


Information.jpg To update your board with the latest version of the pre-installed software you can follow the article: Update the PRE-INSTALLED software image to a current release.



Theory

OMAP35xx or DM37xx processors can boot from a microSD. IGEPv2 or IGEP COM MODULE use the microSD card as highest boot priority, it means that the processor try to boot from the microsd card before try to boot from other devices such the OneNand.

There exist some rules to boot from a microSD card.

  • The microsd card must be content at latest 2 partitions.
  • The first one must be primary partition with the boot flag mark and formated using FAT file system.
  • All names used in this partition must be msdos names, it means you cannot use a extended names.
  • The processor must load a first program called MLO, this program must reside in the first partition, this program it's also called x-loader.

The processor ONLY load and execute the MLO program and ignore all the rest it's the X-loader(MLO) the program responsible to load the next programs such kernel or uboot if you use this last one approach.

Therefore, we are going to setup a microSD card with these requirements and install a custom software distribution into it.


Prerequisites

  • PC with Linux (We use for this how to Ubuntu 11.04)
  • MicroSD Card (4 Gbytes - class 4)
  • Tools such, fdisk, mkfs.ext3, mkfs.vfat, gparted ...
  • ToolChain.


ToolChain

We will use the Ubuntu/Linaro Toolchain in this howto.

You can install it using synaptic package manager.

LinaroUbuntu ToolChain.png

Preparing the microSD card

Open a terminal window and clear your dmesg using:

sudo dmesg -c

Now insert a new microsd card in your PC and then check your dmesg:

dmesg

You should see something like this:

mmc0: new high speed SDHC card at address 0001
mmcblk0: mmc0:0001 00000 3.79 GiB
mmcblk0: unknown partition table

Ensure all in your microsd card it's erased:

$ sudo dd if=/dev/zero of=/dev/mmcblk0 bs=1024 count=1024
[sudo] password for jdoe:
1024+0 records in
1024+0 records out
1048576 bytes (1.0 MB) copied, 0.43556 s, 2.4 MB/s


Install GParted

We will use the gparted program for create the partitions, if you don't have this program installed then you must install it with this command:

sudo apt-get install gparted


GParted and Creation of Partitions

When the install procedure ends you can call the program from your system tools menu or directly using a terminal console.

Gparted initial.png
Create the MSDOS Partition Table

The next step it's create the msdos table partition for it you should click in the "Device" menu and then in the "Create Partition Table" option.

Gparted create msdos table partition.png
Check the default option it's create a msdos partition table.

After that you can Apply.


Create the BOOT Partition

The Next step it's create the partitions for it you should go to the partition menu and select the "New" option then the application show a window like this:

Gparted create first partition.png
We will configure the partition as:
  • Primary Partition
  • Format: FAT32
  • Size: 100 MegaBytes
  • Label: Boot
  • Align to: cylinder


We must "add" the partition and gparted shows a partitions structure like this:

Gparted configure boot partition.png

It is recommended to apply changes now or you might get an error later.


Create the ROOTFS Partition

The Next step it's create the root file system partition.

First you should select the unallocated partition area and then  you should go to the partition menu and select the "New" option then the application show a window like this:
Gparted create first partition.png
We will configure the rootfs partition as:
  • Primary Partition
  • Format: EXT4
  • Size: All the Rest
  • Label: Rootfs

At end we will click on "Add" button.

Gparted all configured.png


Apply all Changes

Click on apply button in the main menu after that gparted show a window like this for confirm all operations

Gparted apply changes.png
We should click on apply button.
Gparted apply information.png
When the process finish we can see all changes applied
Gparted operations complete.png

Now we can see all partitions and configurations done in the main gparted window

Gparted partitions done.png
Select "Boot flag" for the boot partition

Now we must select the boot flag for the first partition for it we use the right mouse button over the boot partition and select "Manage Flags" option

Gparted boot flag.png
Now we have the microsd prepared for copy the boot files


Boot Partition Structure

We commented in the theory point the OMAP needs only the MLO (x-loader) file for boot, we will start checking this point.

Before you follow the next points you should mount the microsd boot partition in your host pc.

Select the boot partition and mount it in your host.

Microsd partitions.png



X-Loader (MLO)

You can follow this other howto about the IGEP-X-loader.

We will compile the sources and get it from our git repository:

$/home/jdoe> git clone git://git.isee.biz/pub/scm/igep-x-loader.git

$/home/jdoe> cd igep-x-loader

$/home/jdoe/igep-x-loader> make igep00x0_config

$/home/jdoe/igep-x-loader> make

$/home/jdoe/igep-x-loader> contrib/signGP

Alternatively you can download the binary package from here


Copy the x-loader.bin.ift into the boot partition.

Copy Xloader.png

Rename the x-loader.bin.ift to MLO

Rename Xloader to MLO.png
Now we're ready for test the board boot from the microsd card.


X-Loader Boot

We will eject the boot and rootfs partitions from our Host PC, this step it's a lot important due the Linux must sync all changes before eject the microsd card.

We will insert our microSD card into the IGEP board, connect the serial debug cable and open the serial terminal

Putty Serial Configuration.png
Power UP the board.
IGEP-X-Loader Boot.png


Configure the IGEP-X-Loader

You can use a file like this:

[kernel]
; Kernel load address, NOT Modify
kaddress=0x80008000
; RAM disk load Address, NOT Modify
;rdaddress=0x84000000
; Board Serial ID
serial.low=00000001
serial.high=00000000
; Board Revision
revision=0003
; Kernel Image Name
kImageName=zImage
; Kernel RAM Disk Image Name
;kRdImageName=initrd.img-2.6.35-1010-linaro-omap
MachineID=xxxx Where Machine ID = 2344 for IGEPv2,  ID = 2717 for IGEP COM Module, ID = 3203 for IGEP COM PROTON
; Mode can be: kernel (boot linux kernel) or binary (boot u-boot, QNX kernel or other binary ARM executable)
Mode=kernel
 
[kparams]
; buddy parameter selects your expansion board
; buddy = igep0022 (IGEPv2 Expansion board)
; buddy = base0010 (IGEP PARIS or IGEP BERLIN Expansion Board)
; buddy.revision = A or B (Selects Expansion board Revision IGEP Paris or IGEP Berlin only, if you dubt select B)
;buddy=igep0022
;buddy=base0010
;buddy.revision=B
; Setup the Kernel console params
; console= Configure the kernel console (ttyS2 kernel <= 2.6.35 ttyO2 if kernel >= 2.6.37)
;console=ttyS2,115200n8
console=ttyO2,115200n8
; Enable early printk
;earlyprintk=serial,ttyS2,115200
; Setup the Board Memory Configuration
mem=430M
;mem=512M
; Setup the Boot Delay
boot_delay=0
; Setup the ARM Processor Speed
;mpurate=800
; Setup the loglevel
;loglevel=7
; Enable Kernel Debug Output
;debug=1
; Fix RTC Variable
;fixrtc=1
; Configure nocompcache variable
nocompcache=1
; Configure Frame Buffer Configuration
;omapfb.mode=dvi:1280x720MR-16@60
omapfb.mode=dvi:hd720-16@60
; Configure Video Ram assigned
vram=40M
; Configure Video RAM assigned to every frame buffer
omapfb.vram=0:12M,1:16M,2:12M
; Configure frame buffer debug output
;omapfb.debug=1
; Configure DSS Video Debug option
;omapdss.debug=1
; Configure the Board Ethernet Mac Address
smsc911x.mac=0xb2,0xb0,0x14,0xb5,0xcd,0xde
;  --- Configure UBI FS boot --- 
;ubi.mtd=2 
;root=ubi0:igep0020-rootfs 
;rootfstype=ubifs
;  --- Configure NFS boot --- 
;ip=192.168.2.123:192.168.2.129:192.168.2.1:255.255.255.0::eth0:
;root=/dev/nfs
;nfsroot=192.168.2.129:/srv/nfs/igep_rootfs
;  --- Configure MMC boot --- 
root=/dev/mmcblk0p2 rw rootwait
; Assign Init program
;init=/bin/bash

Create a new file into the boot partition named igep.ini with these content and save the file.

Kernel

You can follow this other howto about how compile and install the Linux Kernel.

We will get from our git repository the kernel sources and build it:

a) Clone the Kernel git repository

$/home/jdoe/> git clone git://git.igep.es/pub/scm/linux-omap-2.6.git

$/home/jdoe> cd linux-omap-2.6

b) Checkout your desired branch (we used for this howto 2.6.37.y)

$/home/jdoe/linux-omap-2.6> git checkout origin/linux-2.6.37.y -b linux-2-6-37.y

c) Configure the kernel

$/home/jdoe/linux-omap-2.6> make ARCH=arm CROSS_COMPILE=arm-linux-gnueabi- igep00x0_defconfig

d) Build the kernel and Modules

$/home/jdoe/linux-omap-2.6> make ARCH=arm CROSS_COMPILE=arm-linux-gnueabi- zImage modules

Notes: The kernel binary resides inside the directory: $/home/jdoe/linux-omap-2.6/arch/arm/boot/zImage
Alternatively you can download the kernel binary from this link and modules from this.

Root File System

In this tutorial we will use the linaro headless image as rootfs but you can use your favorite rootfs also.


Information.jpg Here there are many articles about how to get many other software distributions.


Here you've the linaro nano 11.09 available for download from the ISEE server.


Create the Rootfs mount point

Go to /media directory and create one sub-folder called "binary"

$ cd /media

$ sudo mkdir binary


Mount the RootFS partition

Mount the rootfs partition using the 'binary' directory

$ media > sudo mount /dev/mmcblkp2 /media/binary


Untar the rootfs package

Copy "linaro-m-headless-tar-20101108-2.tar.gz" file inside the /media directory and untar the file

$ media > sudo tar xvfz linaro-m-headless-tar-20101108-2.tar.gz


Now you should see inside your rootfs partition a similar structure like this.

Linaro RootFS.png
Install the kernel modules

Now you should install your kernel modules inside your root file system.

$ media > cd /home/jdoe/linux-omap-2.6

$ /home/jdoe/linux-omap-2.6> sudo make ARCH=arm CROSS_COMPILE=arm-linux-gnueabi- modules_install INSTALL_MOD_PATH=/media/binary


Install the kernel Image

Just copy the zImage inside your boot partition, remember before that you must mount your mmc boot partition.

$ /home/jdoe/linux-omap-2.6> sudo cp arch/arm/boot/zImage /media/boot/

After that you can unmount the boot & rootfs partitions.

Now we're ready for test our new microsd card

Test your new MicroSD

You can test your new microSD card with a Serial client such as PuTTy. Here is an explanation about how to configure it.

(Note that speed should be configured to 115200 bauds).

If you already have configured it or you are using another Serial client and you have connected the Serial cable to the IGEPv2 board, then you are ready to test your microSD.

Insert the microSD in your IGEPv2 board and power up the board.

Linaro Boot1.png
Linaro Boot2.png


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