android4.3 解压、打包boot.img新脚本
2017-02-27 19:58
387 查看
android4.3 解压、打包boot.img新脚本
解压boot.img需要用到三个文件:mkbootfs、mkbootimg、split_bootimg.pl。前两个是编译完系统后生成的可执行程序,存在于out/host/Linux-x86/bin下面。split_bootimg.pl是一个Perl写的脚本。
现在编译一个android4.3的系统,因为要改boot.img中的某个小东西又不想去重新编译boot,就想通过解压boot.img的方式来进行改动。在网上下载了一个split_bootimg.pl(分割boot的工具)文件,然后把系统中编译出来的mkbootfs(解压ramdisk的工具)和mkbootimg(重新打包签名boot.img的工具)拿出来,准备解压。
执行步骤:1. split_bootimg.pl boot.img (解压boot.img,得到boot.img-kernel,boot.img-ramdisk.gz)
2. mkdir ramdisk (解压boot.img.ramdisk.gz)
cd ramdisk
gzip -dc ../boot.img-ramdisk.gz | cpio -i
cd ..
一般我们需要改动的东西都在这个ramdisk当中,比如开机log(开机动画显示前显示的图片)、init.rc(系统启动是开启的服务项)、default.prop(系统配置文件)等等。
3. ./mkbootfs ./ramdisk | gzip > ramdisk-new.gz (使用mkbootfs工具将修改后的ramdisk重新打包)
4. ./mkbootimg --cmdline 'console=115200,n8 androidboot.console=ttyHSL0 androidboot.hardware=qcom user_debug=31 msm_rtb.filter=0x37' --base 0x00000000 --kernel boot.img-kernel --ramdisk ramdisk-new.gz -o bootnew.img
第四步是使用mkbootimg工具对整个boot.img重新打包,其中的--cmdline后面的引用号里的值是执行第一步就会打印出来的信息。 --base 0x0000000是基址,用于告诉手机从哪个地址开始,是准备给内存盘的入口,哪个地址是给kernel的入口。在boardconfig.h中存在地址偏移的define,一般是这个值,或者是0x00200000、0x20000000。
问题来了,整个过程执行下来也没有报任何错误,但是升级到机器里系统就启动不起来了。原因是在android4.x的boot里面加入了一个叫dt.img(device tree)的东西,少了这个东西boot是启动不起来的。原因也可以在split_bootimg.pl中看到,下面是split_bootimg.pl的代码:
#!/usr/bin/perl
######################################################################
#
# File : split_bootimg.pl
# Author(s) : William Enck <enck@cse.psu.edu>
# Description : Split appart an Android boot image created
# with mkbootimg. The format can be found in
# android-src/system/core/mkbootimg/bootimg.h
#
# Thanks to alansj on xda-developers.com for
# identifying the format in bootimg.h and
# describing initial instructions for splitting
# the boot.img file.
#
# Last Modified : Tue Dec 2 23:36:25 EST 2008
# By : William Enck <enck@cse.psu.edu>
#
# Copyright (c) 2008 William Enck
#
######################################################################
use strict;
use warnings;
# Turn on print flushing
$|++;
######################################################################
## Global Variables and Constants
my $SCRIPT = __FILE__;
my $IMAGE_FN = undef;
# Constants (from bootimg.h)
use constant BOOT_MAGIC => 'ANDROID!';
use constant BOOT_MAGIC_SIZE => 8;
use constant BOOT_NAME_SIZE => 16;
use constant BOOT_ARGS_SIZE => 512;
# Unsigned integers are 4 bytes
use constant UNSIGNED_SIZE => 4;
# Parsed Values
my $PAGE_SIZE = undef; #page 大小
my $KERNEL_SIZE = undef; #kernel 大小
my $RAMDISK_SIZE = undef; #ramdisk 大小
my $SECOND_SIZE = undef; #second 大小
######################################################################
## Main Code
&parse_cmdline();
&parse_header($IMAGE_FN);
=format (from bootimg.h)
** +-----------------+
** | boot header | 1 page
** +-----------------+
** | kernel | n pages
** +-----------------+
** | ramdisk | m pages
** +-----------------+
** | second stage | o pages
** +-----------------+
**
** n = (kernel_size + page_size - 1) / page_size
** m = (ramdisk_size + page_size - 1) / page_size
** o = (second_size + page_size - 1) / page_size
=cut
my $n = int(($KERNEL_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $m = int(($RAMDISK_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $o = int(($SECOND_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $k_offset = $PAGE_SIZE; # kernel的偏移量
my $r_offset = $k_offset + ($n * $PAGE_SIZE); # ramdisk的偏移量
my $s_offset = $r_offset + ($m * $PAGE_SIZE); # second的偏移量
(my $base = $IMAGE_FN) =~ s/.*\/(.*)$/$1/;
my $k_file = $base . "-kernel"; #解压出kernel后添加的名称后缀
my $r_file = $base . "-ramdisk.gz"; # 解压出ramdisk.gz后添加的名称后缀
my $s_file = $base . "-second.gz"; #解压出second.gz后添加的名称后缀
#调用dump_file方法根据kernel的偏移量截取出kernel
# The kernel is always there
print "Writing $k_file ...";
&dump_file($IMAGE_FN, $k_file, $k_offset, $KERNEL_SIZE);
print " complete.\n";
#调用dump_file方法根据ramdisk的偏移量截取出ramdisk
# The ramdisk is always there
print "Writing $r_file ...";
&dump_file($IMAGE_FN, $r_file, $r_offset, $RAMDISK_SIZE);
print " complete.\n";
#调用dump_file方法根据second的偏移量截取出second
# The Second stage bootloader is optional
unless ($SECOND_SIZE == 0) {
print "Writing $s_file ...";
&dump_file($IMAGE_FN, $s_file, $s_offset, $SECOND_SIZE);
print " complete.\n";
}
######################################################################
## Supporting Subroutines
=header_format (from bootimg.h)
struct boot_img_hdr
{
unsigned char magic[BOOT_MAGIC_SIZE];
unsigned kernel_size; /* size in bytes */
unsigned kernel_addr; /* physical load addr */
unsigned ramdisk_size; /* size in bytes */
unsigned ramdisk_addr; /* physical load addr */
unsigned second_size; /* size in bytes */
unsigned second_addr; /* physical load addr */
unsigned tags_addr; /* physical addr for kernel tags */
unsigned page_size; /* flash page size we assume */
unsigned unused[2]; /* future expansion: should be 0 */
unsigned char name[BOOT_NAME_SIZE]; /* asciiz product name */
unsigned char cmdline[BOOT_ARGS_SIZE];
unsigned id[8]; /* timestamp / checksum / sha1 / etc */
};
=cut
sub parse_header {
my ($fn) = @_;
my $buf = undef;
open INF, $fn or die "Could not open $fn: $!\n";
binmode INF;
# Read the Magic
read(INF, $buf, BOOT_MAGIC_SIZE);
unless ($buf eq BOOT_MAGIC) {
die "Android Magic not found in $fn. Giving up.\n";
}
# Read kernel size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($k_size, $k_addr) = unpack("VV", $buf);
# Read ramdisk size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($r_size, $r_addr) = unpack("VV", $buf);
# Read second size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($s_size, $s_addr) = unpack("VV", $buf);
# Ignore tags_addr
read(INF, $buf, UNSIGNED_SIZE);
# get the page size (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE);
my ($p_size) = unpack("V", $buf);
# Ignore unused
read(INF, $buf, UNSIGNED_SIZE * 2);
# Read the name (board name)
read(INF, $buf, BOOT_NAME_SIZE);
my $name = $buf;
# Read the command line
read(INF, $buf, BOOT_ARGS_SIZE);
my $cmdline = $buf;
# Ignore the id
read(INF, $buf, UNSIGNED_SIZE * 8);
# Close the file
close INF;
#打印一些基本信息,包括Command line,就是打包boot.img的时候需要的参数
# Print important values
printf "Page size: %d (0x%08x)\n", $p_size, $p_size;
printf "Kernel size: %d (0x%08x)\n", $k_size, $k_size;
printf "Ramdisk size: %d (0x%08x)\n", $r_size, $r_size;
printf "Second size: %d (0x%08x)\n", $s_size, $s_size;
printf "Board name: $name\n";
printf "Command line: $cmdline\n";
# Save the values
$PAGE_SIZE = $p_size;
$KERNEL_SIZE = $k_size;
$RAMDISK_SIZE = $r_size;
$SECOND_SIZE = $s_size;
}
sub dump_file {
my ($infn, $outfn, $offset, $size) = @_;
my $buf = undef;
open INF, $infn or die "Could not open $infn: $!\n";
open OUTF, ">$outfn" or die "Could not open $outfn: $!\n";
binmode INF;
binmode OUTF;
seek(INF, $offset, 0) or die "Could not seek in $infn: $!\n";
read(INF, $buf, $size) or die "Could not read $infn: $!\n";
print OUTF $buf or die "Could not write $outfn: $!\n";
close INF;
close OUTF;
}
######################################################################
## Configuration Subroutines
sub parse_cmdline {
unless ($#ARGV == 0) {
die "Usage: $SCRIPT boot.img\n";
}
$IMAGE_FN = $ARGV[0];
}
以上文件做了点简单的注释,很明显,里面的代码只实现了解压kernel、ramdisk、second这几个文件出来,没有解压出dt.img,所以这个文件过时了,在新系统上不能适应。
通过研究测试,终于把这个文件改好了,我就直接上改好的文件吧,懒得写注释了,文笔又不好,写的乱七八糟。
#!/usr/bin/perl
######################################################################
#
# File : split_bootimg.pl
# Author(s) : William Enck <enck@cse.psu.edu>
# Description : Split appart an Android boot image created
# with mkbootimg. The format can be found in
# android-src/system/core/mkbootimg/bootimg.h
#
# Thanks to alansj on xda-developers.com for
# identifying the format in bootimg.h and
# describing initial instructions for splitting
# the boot.img file.
#
# Last Modified : Tue Dec 2 23:36:25 EST 2008
# By : William Enck <enck@cse.psu.edu>
#
# Copyright (c) 2008 William Enck
#
######################################################################
use strict;
use warnings;
# Turn on print flushing
$|++;
######################################################################
## Global Variables and Constants
my $SCRIPT = __FILE__;
my $IMAGE_FN = undef;
# Constants (from bootimg.h)
use constant BOOT_MAGIC => 'ANDROID!';
use constant BOOT_MAGIC_SIZE => 8;
use constant BOOT_NAME_SIZE => 16;
use constant BOOT_ARGS_SIZE => 512;
# Unsigned integers are 4 bytes
use constant UNSIGNED_SIZE => 4;
# Parsed Values
my $PAGE_SIZE = undef;
my $KERNEL_SIZE = undef;
my $RAMDISK_SIZE = undef;
my $SECOND_SIZE = undef;
my $DT_SIZE = undef;
######################################################################
## Main Code
&parse_cmdline();
&parse_header($IMAGE_FN);
=format (from bootimg.h)
** +-----------------+
** | boot header | 1 page
** +-----------------+
** | kernel | n pages
** +-----------------+
** | ramdisk | m pages
** +-----------------+
** | second stage | o pages
** +-----------------+
** | device tree | p pages
** +-----------------+
**
** n = (kernel_size + page_size - 1) / page_size
** m = (ramdisk_size + page_size - 1) / page_size
** o = (second_size + page_size - 1) / page_size
** p = (dt_size + page_size - 1) / page_size
=cut
my $n = int(($KERNEL_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $m = int(($RAMDISK_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $o = int(($SECOND_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $p = int(($DT_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $k_offset = $PAGE_SIZE;
my $r_offset = $k_offset + ($n * $PAGE_SIZE);
my $s_offset = $r_offset + ($m * $PAGE_SIZE);
my $d_offset = $s_offset + ($o * $PAGE_SIZE);
(my $base = $IMAGE_FN) =~ s/.*\/(.*)$/$1/;
my $k_file = $base . "-kernel";
my $r_file = $base . "-ramdisk.gz";
my $s_file = $base . "-second.gz";
my $d_file = $base . "-dt.img";
# The kernel is always there
print "Writing $k_file ...";
&dump_file($IMAGE_FN, $k_file, $k_offset, $KERNEL_SIZE);
print " complete.\n";
# The ramdisk is always there
print "Writing $r_file ...";
&dump_file($IMAGE_FN, $r_file, $r_offset, $RAMDISK_SIZE);
print " complete.\n";
# The Second stage bootloader is optional
unless ($SECOND_SIZE == 0) {
print "Writing $s_file ...";
&dump_file($IMAGE_FN, $s_file, $s_offset, $SECOND_SIZE);
print " complete.\n";
}
# The dt is always there
print "Writing $d_file ...";
&dump_file($IMAGE_FN, $d_file, $d_offset, $DT_SIZE);
print " complete.\n";
######################################################################
## Supporting Subroutines
=header_format (from bootimg.h)
struct boot_img_hdr
{
unsigned char magic[BOOT_MAGIC_SIZE];
unsigned kernel_size; /* size in bytes */
unsigned kernel_addr; /* physical load addr */
unsigned ramdisk_size; /* size in bytes */
unsigned ramdisk_addr; /* physical load addr */
unsigned second_size; /* size in bytes */
unsigned second_addr; /* physical load addr */
unsigned tags_addr; /* physical addr for kernel tags */
unsigned page_size; /* flash page size we assume */
unsigned dt size; /* flash device tree size we assume */
unsigned unused; /* future expansion: should be 0 */
unsigned char name[BOOT_NAME_SIZE]; /* asciiz product name *
unsigned char cmdline[BOOT_ARGS_SIZE];
unsigned id[8]; /* timestamp / checksum / sha1 / etc */
};
=cut
sub parse_header {
my ($fn) = @_;
my $buf = undef;
open INF, $fn or die "Could not open $fn: $!\n";
binmode INF;
# Read the Magic
read(INF, $buf, BOOT_MAGIC_SIZE);
unless ($buf eq BOOT_MAGIC) {
die "Android Magic not found in $fn. Giving up.\n";
}
# Read kernel size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($k_size, $k_addr) = unpack("VV", $buf);
# Read ramdisk size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($r_size, $r_addr) = unpack("VV", $buf);
# Read second size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($s_size, $s_addr) = unpack("VV", $buf);
# Ignore tags_addr
read(INF, $buf, UNSIGNED_SIZE);
# get the page size (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE);
my ($p_size) = unpack("V", $buf);
# Read device tree size (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE);
my ($d_size) = unpack("V", $buf);
# Ignore unused
read(INF, $buf, UNSIGNED_SIZE);
# Read the name (board name)
read(INF, $buf, BOOT_NAME_SIZE);
my $name = $buf;
# Read the command line
read(INF, $buf, BOOT_ARGS_SIZE);
my $cmdline = $buf;
# Ignore the id
read(INF, $buf, UNSIGNED_SIZE * 8);
# Close the file
close INF;
# Print important values
printf "Page size: %d (0x%08x)\n", $p_size, $p_size;
printf "Kernel size: %d (0x%08x)\n", $k_size, $k_size;
printf "Ramdisk size: %d (0x%08x)\n", $r_size, $r_size;
printf "Second size: %d (0x%08x)\n", $s_size, $s_size;
printf "DT size: %d (0x%08x)\n", $d_size, $d_size;
printf "Board name: $name\n";
printf "Command line: $cmdline\n";
open(FD,">/tmp/command");
my $position = index($cmdline,"\0");
printf "==================== $position \n";
my $subs = substr($cmdline, 0, $position);
printf "==================== $subs \n";
$subs = $subs."\n";
print FD "$subs";
close FD;
# Save the values
$PAGE_SIZE = $p_size;
$KERNEL_SIZE = $k_size;
$RAMDISK_SIZE = $r_size;
$SECOND_SIZE = $s_size;
$DT_SIZE = $d_size;
}
sub dump_file {
my ($infn, $outfn, $offset, $size) = @_;
my $buf = undef;
open INF, $infn or die "Could not open $infn: $!\n";
open OUTF, ">$outfn" or die "Could not open $outfn: $!\n";
binmode INF;
binmode OUTF;
seek(INF, $offset, 0) or die "Could not seek in $infn: $!\n";
read(INF, $buf, $size) or die "Could not read $infn: $!\n";
print OUTF $buf or die "Could not write $outfn: $!\n";
close INF;
close OUTF;
}
######################################################################
## Configuration Subroutines
sub parse_cmdline {
unless ($#ARGV == 0) {
die "Usage: $SCRIPT boot.img\n";
}
$IMAGE_FN = $ARGV[0];
}
对比一下就会发现,下面的文件中加上了dt.img的相关信息,解压打包后的boot.img升级OK,验证通过。
解压boot.img需要用到三个文件:mkbootfs、mkbootimg、split_bootimg.pl。前两个是编译完系统后生成的可执行程序,存在于out/host/Linux-x86/bin下面。split_bootimg.pl是一个Perl写的脚本。
现在编译一个android4.3的系统,因为要改boot.img中的某个小东西又不想去重新编译boot,就想通过解压boot.img的方式来进行改动。在网上下载了一个split_bootimg.pl(分割boot的工具)文件,然后把系统中编译出来的mkbootfs(解压ramdisk的工具)和mkbootimg(重新打包签名boot.img的工具)拿出来,准备解压。
执行步骤:1. split_bootimg.pl boot.img (解压boot.img,得到boot.img-kernel,boot.img-ramdisk.gz)
2. mkdir ramdisk (解压boot.img.ramdisk.gz)
cd ramdisk
gzip -dc ../boot.img-ramdisk.gz | cpio -i
cd ..
一般我们需要改动的东西都在这个ramdisk当中,比如开机log(开机动画显示前显示的图片)、init.rc(系统启动是开启的服务项)、default.prop(系统配置文件)等等。
3. ./mkbootfs ./ramdisk | gzip > ramdisk-new.gz (使用mkbootfs工具将修改后的ramdisk重新打包)
4. ./mkbootimg --cmdline 'console=115200,n8 androidboot.console=ttyHSL0 androidboot.hardware=qcom user_debug=31 msm_rtb.filter=0x37' --base 0x00000000 --kernel boot.img-kernel --ramdisk ramdisk-new.gz -o bootnew.img
第四步是使用mkbootimg工具对整个boot.img重新打包,其中的--cmdline后面的引用号里的值是执行第一步就会打印出来的信息。 --base 0x0000000是基址,用于告诉手机从哪个地址开始,是准备给内存盘的入口,哪个地址是给kernel的入口。在boardconfig.h中存在地址偏移的define,一般是这个值,或者是0x00200000、0x20000000。
问题来了,整个过程执行下来也没有报任何错误,但是升级到机器里系统就启动不起来了。原因是在android4.x的boot里面加入了一个叫dt.img(device tree)的东西,少了这个东西boot是启动不起来的。原因也可以在split_bootimg.pl中看到,下面是split_bootimg.pl的代码:
#!/usr/bin/perl
######################################################################
#
# File : split_bootimg.pl
# Author(s) : William Enck <enck@cse.psu.edu>
# Description : Split appart an Android boot image created
# with mkbootimg. The format can be found in
# android-src/system/core/mkbootimg/bootimg.h
#
# Thanks to alansj on xda-developers.com for
# identifying the format in bootimg.h and
# describing initial instructions for splitting
# the boot.img file.
#
# Last Modified : Tue Dec 2 23:36:25 EST 2008
# By : William Enck <enck@cse.psu.edu>
#
# Copyright (c) 2008 William Enck
#
######################################################################
use strict;
use warnings;
# Turn on print flushing
$|++;
######################################################################
## Global Variables and Constants
my $SCRIPT = __FILE__;
my $IMAGE_FN = undef;
# Constants (from bootimg.h)
use constant BOOT_MAGIC => 'ANDROID!';
use constant BOOT_MAGIC_SIZE => 8;
use constant BOOT_NAME_SIZE => 16;
use constant BOOT_ARGS_SIZE => 512;
# Unsigned integers are 4 bytes
use constant UNSIGNED_SIZE => 4;
# Parsed Values
my $PAGE_SIZE = undef; #page 大小
my $KERNEL_SIZE = undef; #kernel 大小
my $RAMDISK_SIZE = undef; #ramdisk 大小
my $SECOND_SIZE = undef; #second 大小
######################################################################
## Main Code
&parse_cmdline();
&parse_header($IMAGE_FN);
=format (from bootimg.h)
** +-----------------+
** | boot header | 1 page
** +-----------------+
** | kernel | n pages
** +-----------------+
** | ramdisk | m pages
** +-----------------+
** | second stage | o pages
** +-----------------+
**
** n = (kernel_size + page_size - 1) / page_size
** m = (ramdisk_size + page_size - 1) / page_size
** o = (second_size + page_size - 1) / page_size
=cut
my $n = int(($KERNEL_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $m = int(($RAMDISK_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $o = int(($SECOND_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $k_offset = $PAGE_SIZE; # kernel的偏移量
my $r_offset = $k_offset + ($n * $PAGE_SIZE); # ramdisk的偏移量
my $s_offset = $r_offset + ($m * $PAGE_SIZE); # second的偏移量
(my $base = $IMAGE_FN) =~ s/.*\/(.*)$/$1/;
my $k_file = $base . "-kernel"; #解压出kernel后添加的名称后缀
my $r_file = $base . "-ramdisk.gz"; # 解压出ramdisk.gz后添加的名称后缀
my $s_file = $base . "-second.gz"; #解压出second.gz后添加的名称后缀
#调用dump_file方法根据kernel的偏移量截取出kernel
# The kernel is always there
print "Writing $k_file ...";
&dump_file($IMAGE_FN, $k_file, $k_offset, $KERNEL_SIZE);
print " complete.\n";
#调用dump_file方法根据ramdisk的偏移量截取出ramdisk
# The ramdisk is always there
print "Writing $r_file ...";
&dump_file($IMAGE_FN, $r_file, $r_offset, $RAMDISK_SIZE);
print " complete.\n";
#调用dump_file方法根据second的偏移量截取出second
# The Second stage bootloader is optional
unless ($SECOND_SIZE == 0) {
print "Writing $s_file ...";
&dump_file($IMAGE_FN, $s_file, $s_offset, $SECOND_SIZE);
print " complete.\n";
}
######################################################################
## Supporting Subroutines
=header_format (from bootimg.h)
struct boot_img_hdr
{
unsigned char magic[BOOT_MAGIC_SIZE];
unsigned kernel_size; /* size in bytes */
unsigned kernel_addr; /* physical load addr */
unsigned ramdisk_size; /* size in bytes */
unsigned ramdisk_addr; /* physical load addr */
unsigned second_size; /* size in bytes */
unsigned second_addr; /* physical load addr */
unsigned tags_addr; /* physical addr for kernel tags */
unsigned page_size; /* flash page size we assume */
unsigned unused[2]; /* future expansion: should be 0 */
unsigned char name[BOOT_NAME_SIZE]; /* asciiz product name */
unsigned char cmdline[BOOT_ARGS_SIZE];
unsigned id[8]; /* timestamp / checksum / sha1 / etc */
};
=cut
sub parse_header {
my ($fn) = @_;
my $buf = undef;
open INF, $fn or die "Could not open $fn: $!\n";
binmode INF;
# Read the Magic
read(INF, $buf, BOOT_MAGIC_SIZE);
unless ($buf eq BOOT_MAGIC) {
die "Android Magic not found in $fn. Giving up.\n";
}
# Read kernel size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($k_size, $k_addr) = unpack("VV", $buf);
# Read ramdisk size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($r_size, $r_addr) = unpack("VV", $buf);
# Read second size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($s_size, $s_addr) = unpack("VV", $buf);
# Ignore tags_addr
read(INF, $buf, UNSIGNED_SIZE);
# get the page size (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE);
my ($p_size) = unpack("V", $buf);
# Ignore unused
read(INF, $buf, UNSIGNED_SIZE * 2);
# Read the name (board name)
read(INF, $buf, BOOT_NAME_SIZE);
my $name = $buf;
# Read the command line
read(INF, $buf, BOOT_ARGS_SIZE);
my $cmdline = $buf;
# Ignore the id
read(INF, $buf, UNSIGNED_SIZE * 8);
# Close the file
close INF;
#打印一些基本信息,包括Command line,就是打包boot.img的时候需要的参数
# Print important values
printf "Page size: %d (0x%08x)\n", $p_size, $p_size;
printf "Kernel size: %d (0x%08x)\n", $k_size, $k_size;
printf "Ramdisk size: %d (0x%08x)\n", $r_size, $r_size;
printf "Second size: %d (0x%08x)\n", $s_size, $s_size;
printf "Board name: $name\n";
printf "Command line: $cmdline\n";
# Save the values
$PAGE_SIZE = $p_size;
$KERNEL_SIZE = $k_size;
$RAMDISK_SIZE = $r_size;
$SECOND_SIZE = $s_size;
}
sub dump_file {
my ($infn, $outfn, $offset, $size) = @_;
my $buf = undef;
open INF, $infn or die "Could not open $infn: $!\n";
open OUTF, ">$outfn" or die "Could not open $outfn: $!\n";
binmode INF;
binmode OUTF;
seek(INF, $offset, 0) or die "Could not seek in $infn: $!\n";
read(INF, $buf, $size) or die "Could not read $infn: $!\n";
print OUTF $buf or die "Could not write $outfn: $!\n";
close INF;
close OUTF;
}
######################################################################
## Configuration Subroutines
sub parse_cmdline {
unless ($#ARGV == 0) {
die "Usage: $SCRIPT boot.img\n";
}
$IMAGE_FN = $ARGV[0];
}
以上文件做了点简单的注释,很明显,里面的代码只实现了解压kernel、ramdisk、second这几个文件出来,没有解压出dt.img,所以这个文件过时了,在新系统上不能适应。
通过研究测试,终于把这个文件改好了,我就直接上改好的文件吧,懒得写注释了,文笔又不好,写的乱七八糟。
#!/usr/bin/perl
######################################################################
#
# File : split_bootimg.pl
# Author(s) : William Enck <enck@cse.psu.edu>
# Description : Split appart an Android boot image created
# with mkbootimg. The format can be found in
# android-src/system/core/mkbootimg/bootimg.h
#
# Thanks to alansj on xda-developers.com for
# identifying the format in bootimg.h and
# describing initial instructions for splitting
# the boot.img file.
#
# Last Modified : Tue Dec 2 23:36:25 EST 2008
# By : William Enck <enck@cse.psu.edu>
#
# Copyright (c) 2008 William Enck
#
######################################################################
use strict;
use warnings;
# Turn on print flushing
$|++;
######################################################################
## Global Variables and Constants
my $SCRIPT = __FILE__;
my $IMAGE_FN = undef;
# Constants (from bootimg.h)
use constant BOOT_MAGIC => 'ANDROID!';
use constant BOOT_MAGIC_SIZE => 8;
use constant BOOT_NAME_SIZE => 16;
use constant BOOT_ARGS_SIZE => 512;
# Unsigned integers are 4 bytes
use constant UNSIGNED_SIZE => 4;
# Parsed Values
my $PAGE_SIZE = undef;
my $KERNEL_SIZE = undef;
my $RAMDISK_SIZE = undef;
my $SECOND_SIZE = undef;
my $DT_SIZE = undef;
######################################################################
## Main Code
&parse_cmdline();
&parse_header($IMAGE_FN);
=format (from bootimg.h)
** +-----------------+
** | boot header | 1 page
** +-----------------+
** | kernel | n pages
** +-----------------+
** | ramdisk | m pages
** +-----------------+
** | second stage | o pages
** +-----------------+
** | device tree | p pages
** +-----------------+
**
** n = (kernel_size + page_size - 1) / page_size
** m = (ramdisk_size + page_size - 1) / page_size
** o = (second_size + page_size - 1) / page_size
** p = (dt_size + page_size - 1) / page_size
=cut
my $n = int(($KERNEL_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $m = int(($RAMDISK_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $o = int(($SECOND_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $p = int(($DT_SIZE + $PAGE_SIZE - 1) / $PAGE_SIZE);
my $k_offset = $PAGE_SIZE;
my $r_offset = $k_offset + ($n * $PAGE_SIZE);
my $s_offset = $r_offset + ($m * $PAGE_SIZE);
my $d_offset = $s_offset + ($o * $PAGE_SIZE);
(my $base = $IMAGE_FN) =~ s/.*\/(.*)$/$1/;
my $k_file = $base . "-kernel";
my $r_file = $base . "-ramdisk.gz";
my $s_file = $base . "-second.gz";
my $d_file = $base . "-dt.img";
# The kernel is always there
print "Writing $k_file ...";
&dump_file($IMAGE_FN, $k_file, $k_offset, $KERNEL_SIZE);
print " complete.\n";
# The ramdisk is always there
print "Writing $r_file ...";
&dump_file($IMAGE_FN, $r_file, $r_offset, $RAMDISK_SIZE);
print " complete.\n";
# The Second stage bootloader is optional
unless ($SECOND_SIZE == 0) {
print "Writing $s_file ...";
&dump_file($IMAGE_FN, $s_file, $s_offset, $SECOND_SIZE);
print " complete.\n";
}
# The dt is always there
print "Writing $d_file ...";
&dump_file($IMAGE_FN, $d_file, $d_offset, $DT_SIZE);
print " complete.\n";
######################################################################
## Supporting Subroutines
=header_format (from bootimg.h)
struct boot_img_hdr
{
unsigned char magic[BOOT_MAGIC_SIZE];
unsigned kernel_size; /* size in bytes */
unsigned kernel_addr; /* physical load addr */
unsigned ramdisk_size; /* size in bytes */
unsigned ramdisk_addr; /* physical load addr */
unsigned second_size; /* size in bytes */
unsigned second_addr; /* physical load addr */
unsigned tags_addr; /* physical addr for kernel tags */
unsigned page_size; /* flash page size we assume */
unsigned dt size; /* flash device tree size we assume */
unsigned unused; /* future expansion: should be 0 */
unsigned char name[BOOT_NAME_SIZE]; /* asciiz product name *
unsigned char cmdline[BOOT_ARGS_SIZE];
unsigned id[8]; /* timestamp / checksum / sha1 / etc */
};
=cut
sub parse_header {
my ($fn) = @_;
my $buf = undef;
open INF, $fn or die "Could not open $fn: $!\n";
binmode INF;
# Read the Magic
read(INF, $buf, BOOT_MAGIC_SIZE);
unless ($buf eq BOOT_MAGIC) {
die "Android Magic not found in $fn. Giving up.\n";
}
# Read kernel size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($k_size, $k_addr) = unpack("VV", $buf);
# Read ramdisk size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($r_size, $r_addr) = unpack("VV", $buf);
# Read second size and address (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE * 2);
my ($s_size, $s_addr) = unpack("VV", $buf);
# Ignore tags_addr
read(INF, $buf, UNSIGNED_SIZE);
# get the page size (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE);
my ($p_size) = unpack("V", $buf);
# Read device tree size (assume little-endian)
read(INF, $buf, UNSIGNED_SIZE);
my ($d_size) = unpack("V", $buf);
# Ignore unused
read(INF, $buf, UNSIGNED_SIZE);
# Read the name (board name)
read(INF, $buf, BOOT_NAME_SIZE);
my $name = $buf;
# Read the command line
read(INF, $buf, BOOT_ARGS_SIZE);
my $cmdline = $buf;
# Ignore the id
read(INF, $buf, UNSIGNED_SIZE * 8);
# Close the file
close INF;
# Print important values
printf "Page size: %d (0x%08x)\n", $p_size, $p_size;
printf "Kernel size: %d (0x%08x)\n", $k_size, $k_size;
printf "Ramdisk size: %d (0x%08x)\n", $r_size, $r_size;
printf "Second size: %d (0x%08x)\n", $s_size, $s_size;
printf "DT size: %d (0x%08x)\n", $d_size, $d_size;
printf "Board name: $name\n";
printf "Command line: $cmdline\n";
open(FD,">/tmp/command");
my $position = index($cmdline,"\0");
printf "==================== $position \n";
my $subs = substr($cmdline, 0, $position);
printf "==================== $subs \n";
$subs = $subs."\n";
print FD "$subs";
close FD;
# Save the values
$PAGE_SIZE = $p_size;
$KERNEL_SIZE = $k_size;
$RAMDISK_SIZE = $r_size;
$SECOND_SIZE = $s_size;
$DT_SIZE = $d_size;
}
sub dump_file {
my ($infn, $outfn, $offset, $size) = @_;
my $buf = undef;
open INF, $infn or die "Could not open $infn: $!\n";
open OUTF, ">$outfn" or die "Could not open $outfn: $!\n";
binmode INF;
binmode OUTF;
seek(INF, $offset, 0) or die "Could not seek in $infn: $!\n";
read(INF, $buf, $size) or die "Could not read $infn: $!\n";
print OUTF $buf or die "Could not write $outfn: $!\n";
close INF;
close OUTF;
}
######################################################################
## Configuration Subroutines
sub parse_cmdline {
unless ($#ARGV == 0) {
die "Usage: $SCRIPT boot.img\n";
}
$IMAGE_FN = $ARGV[0];
}
对比一下就会发现,下面的文件中加上了dt.img的相关信息,解压打包后的boot.img升级OK,验证通过。
内容来自用户分享和网络整理,不保证内容的准确性,如有侵权内容,可联系管理员处理 
相关文章推荐
- android4.3 解压、打包boot.img新脚本
- 〖Android〗(CM10.2)Android4.2/4.3中的boot.img打包方法(合适三星exynos4 CPU)
- 〖Linux〗联想K860/i Android 4.2及以上的Bootimg解压与打包工具
- [教程] 如何解包/编辑/打包android系统的boot.img文件 ..
- Android解压及打包system.img
- Android 解压和重新打包system.img
- android文件系统制作教程(4) —- makefile脚本,制作各种单独的分区文件ramdisk.img,system.img,boot.img
- Android 解压boot.img
- [Android]构建boot.img(二):kernel的拷贝与打包
- 解压打包android system.img (2)
- Android 解压boot.img
- 重新解压打包android 根文件系统 ramdisk.img
- 6410开发版烧录Android映像 && IMG说明 && MTK平台解包和打包 boot.img/system.img
- Android构建boot.img(二):kernel的拷贝与打包
- splitimg脚本解析bootimg及打包bootimg
- Android 解压和重新打包system.img
- android文件系统制作教程(4) —- makefile脚本,制作各种单独的分区文件ramdisk.img,system.img,boot.img
- Android 解压boot.img
- Linux下 解包/打包 Android 映像文件 system.img, boot.img, ramdisk.img, userdata.img.
- 安卓Android ROM定制、移植,安卓软件反编译、汉化实战教程第六篇:boot.img、recovery.img的解包、打包!