blob: 2d8559abb2b2895e4993eb41470eb1e8cba3b4de [file] [log] [blame]
# SPDX-License-Identifier: GPL-2.0+
# Copyright 2022 Google LLC
#
"""Bintool implementation for cbfstool
cfstool provides a number of features useful with Coreboot Filesystem binaries.
Documentation is at https://www.coreboot.org/CBFS
Source code is at https://github.com/coreboot/coreboot/blob/master/util/cbfstool/cbfstool.c
Here is the help:
cbfstool: Management utility for CBFS formatted ROM images
USAGE:
cbfstool [-h]
cbfstool FILE COMMAND [-v] [PARAMETERS]...
OPTIONs:
-H header_offset Do not search for header; use this offset*
-T Output top-aligned memory address
-u Accept short data; fill upward/from bottom
-d Accept short data; fill downward/from top
-F Force action
-g Generate position and alignment arguments
-U Unprocessed; don't decompress or make ELF
-v Provide verbose output
-h Display this help message
COMMANDs:
add [-r image,regions] -f FILE -n NAME -t TYPE [-A hash] \
[-c compression] [-b base-address | -a alignment] \
[-p padding size] [-y|--xip if TYPE is FSP] \
[-j topswap-size] (Intel CPUs only) [--ibb]
Add a component
-j valid size: 0x10000 0x20000 0x40000 0x80000 0x100000
add-payload [-r image,regions] -f FILE -n NAME [-A hash] \
[-c compression] [-b base-address] \
(linux specific: [-C cmdline] [-I initrd])
Add a payload to the ROM
add-stage [-r image,regions] -f FILE -n NAME [-A hash] \
[-c compression] [-b base] [-S section-to-ignore] \
[-a alignment] [-y|--xip] [-P page-size] [--ibb]
Add a stage to the ROM
add-flat-binary [-r image,regions] -f FILE -n NAME \
[-A hash] -l load-address -e entry-point \
[-c compression] [-b base]
Add a 32bit flat mode binary
add-int [-r image,regions] -i INTEGER -n NAME [-b base]
Add a raw 64-bit integer value
add-master-header [-r image,regions] \
[-j topswap-size] (Intel CPUs only)
Add a legacy CBFS master header
remove [-r image,regions] -n NAME
Remove a component
compact -r image,regions
Defragment CBFS image.
copy -r image,regions -R source-region
Create a copy (duplicate) cbfs instance in fmap
create -m ARCH -s size [-b bootblock offset] \
[-o CBFS offset] [-H header offset] [-B bootblock]
Create a legacy ROM file with CBFS master header*
create -M flashmap [-r list,of,regions,containing,cbfses]
Create a new-style partitioned firmware image
locate [-r image,regions] -f FILE -n NAME [-P page-size] \
[-a align] [-T]
Find a place for a file of that size
layout [-w]
List mutable (or, with -w, readable) image regions
print [-r image,regions]
Show the contents of the ROM
extract [-r image,regions] [-m ARCH] -n NAME -f FILE [-U]
Extracts a file from ROM
write [-F] -r image,regions -f file [-u | -d] [-i int]
Write file into same-size [or larger] raw region
read [-r fmap-region] -f file
Extract raw region contents into binary file
truncate [-r fmap-region]
Truncate CBFS and print new size on stdout
expand [-r fmap-region]
Expand CBFS to span entire region
OFFSETs:
Numbers accompanying -b, -H, and -o switches* may be provided
in two possible formats: if their value is greater than
0x80000000, they are interpreted as a top-aligned x86 memory
address; otherwise, they are treated as an offset into flash.
ARCHes:
arm64, arm, mips, ppc64, power8, riscv, x86, unknown
TYPEs:
bootblock, cbfs header, stage, simple elf, fit, optionrom, bootsplash, raw,
vsa, mbi, microcode, fsp, mrc, cmos_default, cmos_layout, spd,
mrc_cache, mma, efi, struct, deleted, null
* Note that these actions and switches are only valid when
working with legacy images whose structure is described
primarily by a CBFS master header. New-style images, in
contrast, exclusively make use of an FMAP to describe their
layout: this must minimally contain an 'FMAP' section
specifying the location of this FMAP itself and a 'COREBOOT'
section describing the primary CBFS. It should also be noted
that, when working with such images, the -F and -r switches
default to 'COREBOOT' for convenience, and both the -b switch to
CBFS operations and the output of the locate action become
relative to the selected CBFS region's lowest address.
The one exception to this rule is the top-aligned address,
which is always relative to the end of the entire image
rather than relative to the local region; this is true for
for both input (sufficiently large) and output (-T) data.
Since binman has a native implementation of CBFS (see cbfs_util.py), we don't
actually need this tool, except for sanity checks in the tests.
"""
from binman import bintool
class Bintoolcbfstool(bintool.Bintool):
"""Coreboot filesystem (CBFS) tool
This bintool supports creating new CBFS images and adding files to an
existing image, i.e. the features needed by binman.
It also supports fetching a binary cbfstool, since building it from source
is fairly slow.
Documentation about CBFS is at https://www.coreboot.org/CBFS
"""
def __init__(self, name):
super().__init__(name, 'Manipulate CBFS files')
def create_new(self, cbfs_fname, size, arch='x86'):
"""Create a new CBFS
Args:
cbfs_fname (str): Filename of CBFS to create
size (int): Size of CBFS in bytes
arch (str): Architecture for which this CBFS is intended
Returns:
str: Tool output
"""
args = [cbfs_fname, 'create', '-s', f'{size:#x}', '-m', arch]
return self.run_cmd(*args)
# pylint: disable=R0913
def add_raw(self, cbfs_fname, name, fname, compress=None, base=None):
"""Add a raw file to the CBFS
Args:
cbfs_fname (str): Filename of CBFS to create
name (str): Name to use inside the CBFS
fname (str): Filename of file to add
compress (str): Compression to use (cbfs_util.COMPRESS_NAMES) or
None for None
base (int): Address to place the file, or None for anywhere
Returns:
str: Tool output
"""
args = [cbfs_fname,
'add',
'-n', name,
'-t', 'raw',
'-f', fname,
'-c', compress or 'none']
if base:
args += ['-b', f'{base:#x}']
return self.run_cmd(*args)
def add_stage(self, cbfs_fname, name, fname):
"""Add a stage file to the CBFS
Args:
cbfs_fname (str): Filename of CBFS to create
name (str): Name to use inside the CBFS
fname (str): Filename of file to add
Returns:
str: Tool output
"""
args = [cbfs_fname,
'add-stage',
'-n', name,
'-f', fname
]
return self.run_cmd(*args)
def fail(self):
"""Run cbfstool with invalid arguments to check it reports failure
This is really just a sanity check
Returns:
CommandResult: Result from running the bad command
"""
args = ['missing-file', 'bad-command']
return self.run_cmd_result(*args)
def fetch(self, method):
"""Fetch handler for cbfstool
This installs cbfstool by downloading from Google Drive.
Args:
method (FETCH_...): Method to use
Returns:
True if the file was fetched and now installed, None if a method
other than FETCH_BIN was requested
Raises:
Valuerror: Fetching could not be completed
"""
if method != bintool.FETCH_BIN:
return None
# Version 4.22.01
fname, tmpdir = self.fetch_from_drive(
'1gxNxRuJgD0Iiy9LAPCSB_0959eJCp98g')
return fname, tmpdir