blob: 3c931d9aeb63290222f645561fa1214b8f8abc81 [file] [log] [blame]
# SPDX-License-Identifier: GPL-2.0+
# Copyright (c) 2016 Google, Inc
# Written by Simon Glass <sjg@chromium.org>
#
# Creates binary images from input files controlled by a description
#
from collections import OrderedDict
import os
import re
import sys
import tools
import command
import elf
from image import Image
import tout
# List of images we plan to create
# Make this global so that it can be referenced from tests
images = OrderedDict()
# Records the device-tree files known to binman, keyed by filename (e.g.
# 'u-boot-spl.dtb')
fdt_files = {}
# Arguments passed to binman to provide arguments to entries
entry_args = {}
def _ReadImageDesc(binman_node):
"""Read the image descriptions from the /binman node
This normally produces a single Image object called 'image'. But if
multiple images are present, they will all be returned.
Args:
binman_node: Node object of the /binman node
Returns:
OrderedDict of Image objects, each of which describes an image
"""
images = OrderedDict()
if 'multiple-images' in binman_node.props:
for node in binman_node.subnodes:
images[node.name] = Image(node.name, node)
else:
images['image'] = Image('image', binman_node)
return images
def _FindBinmanNode(dtb):
"""Find the 'binman' node in the device tree
Args:
dtb: Fdt object to scan
Returns:
Node object of /binman node, or None if not found
"""
for node in dtb.GetRoot().subnodes:
if node.name == 'binman':
return node
return None
def GetFdt(fname):
"""Get the Fdt object for a particular device-tree filename
Binman keeps track of at least one device-tree file called u-boot.dtb but
can also have others (e.g. for SPL). This function looks up the given
filename and returns the associated Fdt object.
Args:
fname: Filename to look up (e.g. 'u-boot.dtb').
Returns:
Fdt object associated with the filename
"""
return fdt_files[fname]
def GetFdtPath(fname):
return fdt_files[fname]._fname
def SetEntryArgs(args):
global entry_args
entry_args = {}
if args:
for arg in args:
m = re.match('([^=]*)=(.*)', arg)
if not m:
raise ValueError("Invalid entry arguemnt '%s'" % arg)
entry_args[m.group(1)] = m.group(2)
def GetEntryArg(name):
return entry_args.get(name)
def Binman(options, args):
"""The main control code for binman
This assumes that help and test options have already been dealt with. It
deals with the core task of building images.
Args:
options: Command line options object
args: Command line arguments (list of strings)
"""
global images
if options.full_help:
pager = os.getenv('PAGER')
if not pager:
pager = 'more'
fname = os.path.join(os.path.dirname(os.path.realpath(sys.argv[0])),
'README')
command.Run(pager, fname)
return 0
# Try to figure out which device tree contains our image description
if options.dt:
dtb_fname = options.dt
else:
board = options.board
if not board:
raise ValueError('Must provide a board to process (use -b <board>)')
board_pathname = os.path.join(options.build_dir, board)
dtb_fname = os.path.join(board_pathname, 'u-boot.dtb')
if not options.indir:
options.indir = ['.']
options.indir.append(board_pathname)
try:
# Import these here in case libfdt.py is not available, in which case
# the above help option still works.
import fdt
import fdt_util
tout.Init(options.verbosity)
elf.debug = options.debug
try:
tools.SetInputDirs(options.indir)
tools.PrepareOutputDir(options.outdir, options.preserve)
SetEntryArgs(options.entry_arg)
# Get the device tree ready by compiling it and copying the compiled
# output into a file in our output directly. Then scan it for use
# in binman.
dtb_fname = fdt_util.EnsureCompiled(dtb_fname)
fname = tools.GetOutputFilename('u-boot-out.dtb')
with open(dtb_fname) as infd:
with open(fname, 'wb') as outfd:
outfd.write(infd.read())
dtb = fdt.FdtScan(fname)
# Note the file so that GetFdt() can find it
fdt_files['u-boot.dtb'] = dtb
node = _FindBinmanNode(dtb)
if not node:
raise ValueError("Device tree '%s' does not have a 'binman' "
"node" % dtb_fname)
images = _ReadImageDesc(node)
# Prepare the device tree by making sure that any missing
# properties are added (e.g. 'pos' and 'size'). The values of these
# may not be correct yet, but we add placeholders so that the
# size of the device tree is correct. Later, in
# SetCalculatedProperties() we will insert the correct values
# without changing the device-tree size, thus ensuring that our
# entry offsets remain the same.
for image in images.values():
if options.update_fdt:
image.AddMissingProperties()
image.ProcessFdt(dtb)
dtb.Pack()
dtb.Flush()
for image in images.values():
# Perform all steps for this image, including checking and
# writing it. This means that errors found with a later
# image will be reported after earlier images are already
# completed and written, but that does not seem important.
image.GetEntryContents()
image.GetEntryOffsets()
image.PackEntries()
image.CheckSize()
image.CheckEntries()
image.SetImagePos()
if options.update_fdt:
image.SetCalculatedProperties()
image.ProcessEntryContents()
image.WriteSymbols()
image.BuildImage()
if options.map:
image.WriteMap()
with open(fname, 'wb') as outfd:
outfd.write(dtb.GetContents())
finally:
tools.FinaliseOutputDir()
finally:
tout.Uninit()
return 0