#!/usr/bin/env python # # Copyright (C) 2011 The Android Open Source Project # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """ Build image output_image_file from input_directory, properties_file, and target_out_dir Usage: build_image input_directory properties_file output_image_file target_out_dir """ import os import os.path import re import subprocess import sys import common import shlex import shutil import sparse_img import tempfile OPTIONS = common.OPTIONS FIXED_SALT = "aee087a5be3b982978c923f566a94613496b417f2af592639bc80d141e34dfe7" BLOCK_SIZE = 4096 def RunCommand(cmd, verbose=None): """Echo and run the given command. Args: cmd: the command represented as a list of strings. verbose: show commands being executed. Returns: A tuple of the output and the exit code. """ if verbose is None: verbose = OPTIONS.verbose if verbose: print("Running: " + " ".join(cmd)) p = subprocess.Popen(cmd, stdout=subprocess.PIPE, stderr=subprocess.STDOUT) output, _ = p.communicate() if verbose: print(output.rstrip()) return (output, p.returncode) def GetVerityFECSize(partition_size): cmd = ["fec", "-s", str(partition_size)] output, exit_code = RunCommand(cmd, False) if exit_code != 0: return False, 0 return True, int(output) def GetVerityTreeSize(partition_size): cmd = ["build_verity_tree", "-s", str(partition_size)] output, exit_code = RunCommand(cmd, False) if exit_code != 0: return False, 0 return True, int(output) def GetVerityMetadataSize(partition_size): cmd = ["system/extras/verity/build_verity_metadata.py", "size", str(partition_size)] output, exit_code = RunCommand(cmd, False) if exit_code != 0: return False, 0 return True, int(output) def GetVeritySize(partition_size, fec_supported): success, verity_tree_size = GetVerityTreeSize(partition_size) if not success: return 0 success, verity_metadata_size = GetVerityMetadataSize(partition_size) if not success: return 0 verity_size = verity_tree_size + verity_metadata_size if fec_supported: success, fec_size = GetVerityFECSize(partition_size + verity_size) if not success: return 0 return verity_size + fec_size return verity_size def GetSimgSize(image_file): simg = sparse_img.SparseImage(image_file, build_map=False) return simg.blocksize * simg.total_blocks def ZeroPadSimg(image_file, pad_size): blocks = pad_size // BLOCK_SIZE print("Padding %d blocks (%d bytes)" % (blocks, pad_size)) simg = sparse_img.SparseImage(image_file, mode="r+b", build_map=False) simg.AppendFillChunk(0, blocks) def AVBCalcMaxImageSize(avbtool, footer_type, partition_size, additional_args): """Calculates max image size for a given partition size. Args: avbtool: String with path to avbtool. footer_type: 'hash' or 'hashtree' for generating footer. partition_size: The size of the partition in question. additional_args: Additional arguments to pass to 'avbtool add_hashtree_image'. Returns: The maximum image size or 0 if an error occurred. """ cmd =[avbtool, "add_%s_footer" % footer_type, "--partition_size", partition_size, "--calc_max_image_size"] cmd.extend(shlex.split(additional_args)) (output, exit_code) = RunCommand(cmd) if exit_code != 0: return 0 else: return int(output) def AVBAddFooter(image_path, avbtool, footer_type, partition_size, partition_name, key_path, algorithm, salt, additional_args): """Adds dm-verity hashtree and AVB metadata to an image. Args: image_path: Path to image to modify. avbtool: String with path to avbtool. footer_type: 'hash' or 'hashtree' for generating footer. partition_size: The size of the partition in question. partition_name: The name of the partition - will be embedded in metadata. key_path: Path to key to use or None. algorithm: Name of algorithm to use or None. salt: The salt to use (a hexadecimal string) or None. additional_args: Additional arguments to pass to 'avbtool add_hashtree_image'. Returns: True if the operation succeeded. """ cmd =[avbtool, "add_%s_footer" % footer_type, "--partition_size", partition_size, "--partition_name", partition_name, "--image", image_path] if key_path and algorithm: cmd.extend(["--key", key_path, "--algorithm", algorithm]) if salt: cmd.extend(["--salt", salt]) cmd.extend(shlex.split(additional_args)) (_, exit_code) = RunCommand(cmd) return exit_code == 0 def AdjustPartitionSizeForVerity(partition_size, fec_supported): """Modifies the provided partition size to account for the verity metadata. This information is used to size the created image appropriately. Args: partition_size: the size of the partition to be verified. Returns: A tuple of the size of the partition adjusted for verity metadata, and the size of verity metadata. """ key = "%d %d" % (partition_size, fec_supported) if key in AdjustPartitionSizeForVerity.results: return AdjustPartitionSizeForVerity.results[key] hi = partition_size if hi % BLOCK_SIZE != 0: hi = (hi // BLOCK_SIZE) * BLOCK_SIZE # verity tree and fec sizes depend on the partition size, which # means this estimate is always going to be unnecessarily small verity_size = GetVeritySize(hi, fec_supported) lo = partition_size - verity_size result = lo # do a binary search for the optimal size while lo < hi: i = ((lo + hi) // (2 * BLOCK_SIZE)) * BLOCK_SIZE v = GetVeritySize(i, fec_supported) if i + v <= partition_size: if result < i: result = i verity_size = v lo = i + BLOCK_SIZE else: hi = i print("Adjusted partition size for verity, partition_size: {}," " verity_size: {}".format(result, verity_size)) AdjustPartitionSizeForVerity.results[key] = (result, verity_size) return (result, verity_size) AdjustPartitionSizeForVerity.results = {} def BuildVerityFEC(sparse_image_path, verity_path, verity_fec_path, padding_size): cmd = ["fec", "-e", "-p", str(padding_size), sparse_image_path, verity_path, verity_fec_path] output, exit_code = RunCommand(cmd) if exit_code != 0: print "Could not build FEC data! Error: %s" % output return False return True def BuildVerityTree(sparse_image_path, verity_image_path, prop_dict): cmd = ["build_verity_tree", "-A", FIXED_SALT, sparse_image_path, verity_image_path] output, exit_code = RunCommand(cmd) if exit_code != 0: print "Could not build verity tree! Error: %s" % output return False root, salt = output.split() prop_dict["verity_root_hash"] = root prop_dict["verity_salt"] = salt return True def BuildVerityMetadata(image_size, verity_metadata_path, root_hash, salt, block_device, signer_path, key, signer_args): cmd = ["system/extras/verity/build_verity_metadata.py", "build", str(image_size), verity_metadata_path, root_hash, salt, block_device, signer_path, key] if signer_args: cmd.append("--signer_args=\"%s\"" % (' '.join(signer_args),)) output, exit_code = RunCommand(cmd) if exit_code != 0: print "Could not build verity metadata! Error: %s" % output return False return True def Append2Simg(sparse_image_path, unsparse_image_path, error_message): """Appends the unsparse image to the given sparse image. Args: sparse_image_path: the path to the (sparse) image unsparse_image_path: the path to the (unsparse) image Returns: True on success, False on failure. """ cmd = ["append2simg", sparse_image_path, unsparse_image_path] output, exit_code = RunCommand(cmd) if exit_code != 0: print "%s: %s" % (error_message, output) return False return True def Append(target, file_to_append, error_message): print "appending %s to %s" % (file_to_append, target) with open(target, "a") as out_file: with open(file_to_append, "r") as input_file: for line in input_file: out_file.write(line) return True def BuildVerifiedImage(data_image_path, verity_image_path, verity_metadata_path, verity_fec_path, padding_size, fec_supported): if not Append(verity_image_path, verity_metadata_path, "Could not append verity metadata!"): return False if fec_supported: # build FEC for the entire partition, including metadata if not BuildVerityFEC(data_image_path, verity_image_path, verity_fec_path, padding_size): return False if not Append(verity_image_path, verity_fec_path, "Could not append FEC!"): return False if not Append2Simg(data_image_path, verity_image_path, "Could not append verity data!"): return False return True def UnsparseImage(sparse_image_path, replace=True): img_dir = os.path.dirname(sparse_image_path) unsparse_image_path = "unsparse_" + os.path.basename(sparse_image_path) unsparse_image_path = os.path.join(img_dir, unsparse_image_path) if os.path.exists(unsparse_image_path): if replace: os.unlink(unsparse_image_path) else: return True, unsparse_image_path inflate_command = ["simg2img", sparse_image_path, unsparse_image_path] (_, exit_code) = RunCommand(inflate_command) if exit_code != 0: os.remove(unsparse_image_path) return False, None return True, unsparse_image_path def MakeVerityEnabledImage(out_file, fec_supported, prop_dict): """Creates an image that is verifiable using dm-verity. Args: out_file: the location to write the verifiable image at prop_dict: a dictionary of properties required for image creation and verification Returns: True on success, False otherwise. """ # get properties image_size = int(prop_dict["partition_size"]) block_dev = prop_dict["verity_block_device"] signer_key = prop_dict["verity_key"] + ".pk8" if OPTIONS.verity_signer_path is not None: signer_path = OPTIONS.verity_signer_path else: signer_path = prop_dict["verity_signer_cmd"] signer_args = OPTIONS.verity_signer_args # make a tempdir tempdir_name = tempfile.mkdtemp(suffix="_verity_images") # get partial image paths verity_image_path = os.path.join(tempdir_name, "verity.img") verity_metadata_path = os.path.join(tempdir_name, "verity_metadata.img") verity_fec_path = os.path.join(tempdir_name, "verity_fec.img") # build the verity tree and get the root hash and salt if not BuildVerityTree(out_file, verity_image_path, prop_dict): shutil.rmtree(tempdir_name, ignore_errors=True) return False # build the metadata blocks root_hash = prop_dict["verity_root_hash"] salt = prop_dict["verity_salt"] if not BuildVerityMetadata(image_size, verity_metadata_path, root_hash, salt, block_dev, signer_path, signer_key, signer_args): shutil.rmtree(tempdir_name, ignore_errors=True) return False # build the full verified image target_size = int(prop_dict["original_partition_size"]) verity_size = int(prop_dict["verity_size"]) padding_size = target_size - image_size - verity_size assert padding_size >= 0 if not BuildVerifiedImage(out_file, verity_image_path, verity_metadata_path, verity_fec_path, padding_size, fec_supported): shutil.rmtree(tempdir_name, ignore_errors=True) return False shutil.rmtree(tempdir_name, ignore_errors=True) return True def ConvertBlockMapToBaseFs(block_map_file): fd, base_fs_file = tempfile.mkstemp(prefix="script_gen_", suffix=".base_fs") os.close(fd) convert_command = ["blk_alloc_to_base_fs", block_map_file, base_fs_file] (_, exit_code) = RunCommand(convert_command) if exit_code != 0: os.remove(base_fs_file) return None return base_fs_file def BuildImage(in_dir, prop_dict, out_file, target_out=None): """Build an image to out_file from in_dir with property prop_dict. Args: in_dir: path of input directory. prop_dict: property dictionary. out_file: path of the output image file. target_out: path of the product out directory to read device specific FS config files. Returns: True iff the image is built successfully. """ # system_root_image=true: build a system.img that combines the contents of # /system and the ramdisk, and can be mounted at the root of the file system. origin_in = in_dir fs_config = prop_dict.get("fs_config") base_fs_file = None if (prop_dict.get("system_root_image") == "true" and prop_dict["mount_point"] == "system"): in_dir = tempfile.mkdtemp() # Change the mount point to "/" prop_dict["mount_point"] = "/" if fs_config: # We need to merge the fs_config files of system and ramdisk. fd, merged_fs_config = tempfile.mkstemp(prefix="root_fs_config", suffix=".txt") os.close(fd) with open(merged_fs_config, "w") as fw: if "ramdisk_fs_config" in prop_dict: with open(prop_dict["ramdisk_fs_config"]) as fr: fw.writelines(fr.readlines()) with open(fs_config) as fr: fw.writelines(fr.readlines()) fs_config = merged_fs_config build_command = [] fs_type = prop_dict.get("fs_type", "") run_fsck = False fs_spans_partition = True if fs_type.startswith("squash"): fs_spans_partition = False is_verity_partition = "verity_block_device" in prop_dict verity_supported = prop_dict.get("verity") == "true" verity_fec_supported = prop_dict.get("verity_fec") == "true" # Adjust the partition size to make room for the hashes if this is to be # verified. if verity_supported and is_verity_partition: partition_size = int(prop_dict.get("partition_size")) (adjusted_size, verity_size) = AdjustPartitionSizeForVerity(partition_size, verity_fec_supported) if not adjusted_size: return False prop_dict["partition_size"] = str(adjusted_size) prop_dict["original_partition_size"] = str(partition_size) prop_dict["verity_size"] = str(verity_size) # Adjust partition size for AVB hash footer or AVB hashtree footer. avb_footer_type = '' if prop_dict.get("avb_hash_enable") == "true": avb_footer_type = 'hash' elif prop_dict.get("avb_hashtree_enable") == "true": avb_footer_type = 'hashtree' if avb_footer_type: avbtool = prop_dict["avb_avbtool"] partition_size = prop_dict["partition_size"] # avb_add_hash_footer_args or avb_add_hashtree_footer_args. additional_args = prop_dict["avb_add_" + avb_footer_type + "_footer_args"] max_image_size = AVBCalcMaxImageSize(avbtool, avb_footer_type, partition_size, additional_args) if max_image_size == 0: return False prop_dict["partition_size"] = str(max_image_size) prop_dict["original_partition_size"] = partition_size if fs_type.startswith("ext"): build_command = [prop_dict["ext_mkuserimg"]] if "extfs_sparse_flag" in prop_dict: build_command.append(prop_dict["extfs_sparse_flag"]) run_fsck = True build_command.extend([in_dir, out_file, fs_type, prop_dict["mount_point"]]) build_command.append(prop_dict["partition_size"]) if "journal_size" in prop_dict: build_command.extend(["-j", prop_dict["journal_size"]]) if "timestamp" in prop_dict: build_command.extend(["-T", str(prop_dict["timestamp"])]) if fs_config: build_command.extend(["-C", fs_config]) if target_out: build_command.extend(["-D", target_out]) if "block_list" in prop_dict: build_command.extend(["-B", prop_dict["block_list"]]) if "base_fs_file" in prop_dict: base_fs_file = ConvertBlockMapToBaseFs(prop_dict["base_fs_file"]) if base_fs_file is None: return False build_command.extend(["-d", base_fs_file]) build_command.extend(["-L", prop_dict["mount_point"]]) if "extfs_inode_count" in prop_dict: build_command.extend(["-i", prop_dict["extfs_inode_count"]]) if "flash_erase_block_size" in prop_dict: build_command.extend(["-e", prop_dict["flash_erase_block_size"]]) if "flash_logical_block_size" in prop_dict: build_command.extend(["-o", prop_dict["flash_logical_block_size"]]) # Specify UUID and hash_seed if using mke2fs. if prop_dict["ext_mkuserimg"] == "mkuserimg_mke2fs.sh": if "uuid" in prop_dict: build_command.extend(["-U", prop_dict["uuid"]]) if "hash_seed" in prop_dict: build_command.extend(["-S", prop_dict["hash_seed"]]) if "selinux_fc" in prop_dict: build_command.append(prop_dict["selinux_fc"]) elif fs_type.startswith("squash"): build_command = ["mksquashfsimage.sh"] build_command.extend([in_dir, out_file]) if "squashfs_sparse_flag" in prop_dict: build_command.extend([prop_dict["squashfs_sparse_flag"]]) build_command.extend(["-m", prop_dict["mount_point"]]) if target_out: build_command.extend(["-d", target_out]) if fs_config: build_command.extend(["-C", fs_config]) if "selinux_fc" in prop_dict: build_command.extend(["-c", prop_dict["selinux_fc"]]) if "block_list" in prop_dict: build_command.extend(["-B", prop_dict["block_list"]]) if "squashfs_compressor" in prop_dict: build_command.extend(["-z", prop_dict["squashfs_compressor"]]) if "squashfs_compressor_opt" in prop_dict: build_command.extend(["-zo", prop_dict["squashfs_compressor_opt"]]) if "squashfs_block_size" in prop_dict: build_command.extend(["-b", prop_dict["squashfs_block_size"]]) if "squashfs_disable_4k_align" in prop_dict and prop_dict.get("squashfs_disable_4k_align") == "true": build_command.extend(["-a"]) elif fs_type.startswith("f2fs"): build_command = ["mkf2fsuserimg.sh"] build_command.extend([out_file, prop_dict["partition_size"]]) else: print("Error: unknown filesystem type '%s'" % (fs_type)) return False if in_dir != origin_in: # Construct a staging directory of the root file system. ramdisk_dir = prop_dict.get("ramdisk_dir") if ramdisk_dir: shutil.rmtree(in_dir) shutil.copytree(ramdisk_dir, in_dir, symlinks=True) staging_system = os.path.join(in_dir, "system") shutil.rmtree(staging_system, ignore_errors=True) shutil.copytree(origin_in, staging_system, symlinks=True) has_reserved_blocks = prop_dict.get("has_ext4_reserved_blocks") == "true" ext4fs_output = None try: if fs_type.startswith("ext4"): (ext4fs_output, exit_code) = RunCommand(build_command, True) else: (_, exit_code) = RunCommand(build_command, True) finally: if in_dir != origin_in: # Clean up temporary directories and files. shutil.rmtree(in_dir, ignore_errors=True) if fs_config: os.remove(fs_config) if base_fs_file is not None: os.remove(base_fs_file) if exit_code != 0: return False # Bug: 21522719, 22023465 # There are some reserved blocks on ext4 FS (lesser of 4096 blocks and 2%). # We need to deduct those blocks from the available space, since they are # not writable even with root privilege. It only affects devices using # file-based OTA and a kernel version of 3.10 or greater (currently just # sprout). # Separately, check if there's enough headroom space available. This is useful for # devices with low disk space that have system image variation between builds. if (has_reserved_blocks or "partition_headroom" in prop_dict) and fs_type.startswith("ext4"): assert ext4fs_output is not None ext4fs_stats = re.compile( r'Created filesystem with .* (?P[0-9]+)/' r'(?P[0-9]+) blocks') m = ext4fs_stats.match(ext4fs_output.strip().split('\n')[-1]) used_blocks = int(m.groupdict().get('used_blocks')) total_blocks = int(m.groupdict().get('total_blocks')) reserved_blocks = 0 headroom_blocks = 0 adjusted_blocks = total_blocks if has_reserved_blocks: reserved_blocks = min(4096, int(total_blocks * 0.02)) adjusted_blocks -= reserved_blocks if "partition_headroom" in prop_dict: headroom_blocks = int(prop_dict.get('partition_headroom')) / BLOCK_SIZE adjusted_blocks -= headroom_blocks if used_blocks > adjusted_blocks: mount_point = prop_dict.get("mount_point") print("Error: Not enough room on %s (total: %d blocks, used: %d blocks, " "reserved: %d blocks, headroom: %d blocks, available: %d blocks)" % ( mount_point, total_blocks, used_blocks, reserved_blocks, headroom_blocks, adjusted_blocks)) return False if not fs_spans_partition: mount_point = prop_dict.get("mount_point") partition_size = int(prop_dict.get("partition_size")) image_size = GetSimgSize(out_file) if image_size > partition_size: print("Error: %s image size of %d is larger than partition size of " "%d" % (mount_point, image_size, partition_size)) return False if verity_supported and is_verity_partition: ZeroPadSimg(out_file, partition_size - image_size) # create the verified image if this is to be verified if verity_supported and is_verity_partition: if not MakeVerityEnabledImage(out_file, verity_fec_supported, prop_dict): return False # Add AVB HASH or HASHTREE footer (metadata). if avb_footer_type: avbtool = prop_dict["avb_avbtool"] original_partition_size = prop_dict["original_partition_size"] partition_name = prop_dict["partition_name"] # key_path and algorithm are only available when chain partition is used. key_path = prop_dict.get("avb_key_path") algorithm = prop_dict.get("avb_algorithm") salt = prop_dict.get("avb_salt") # avb_add_hash_footer_args or avb_add_hashtree_footer_args additional_args = prop_dict["avb_add_" + avb_footer_type + "_footer_args"] if not AVBAddFooter(out_file, avbtool, avb_footer_type, original_partition_size, partition_name, key_path, algorithm, salt, additional_args): return False if run_fsck and prop_dict.get("skip_fsck") != "true": success, unsparse_image = UnsparseImage(out_file, replace=False) if not success: return False # Run e2fsck on the inflated image file e2fsck_command = ["e2fsck", "-f", "-n", unsparse_image] (_, exit_code) = RunCommand(e2fsck_command) os.remove(unsparse_image) return exit_code == 0 def ImagePropFromGlobalDict(glob_dict, mount_point): """Build an image property dictionary from the global dictionary. Args: glob_dict: the global dictionary from the build system. mount_point: such as "system", "data" etc. """ d = {} if "build.prop" in glob_dict: bp = glob_dict["build.prop"] if "ro.build.date.utc" in bp: d["timestamp"] = bp["ro.build.date.utc"] def copy_prop(src_p, dest_p): if src_p in glob_dict: d[dest_p] = str(glob_dict[src_p]) common_props = ( "extfs_sparse_flag", "squashfs_sparse_flag", "selinux_fc", "skip_fsck", "ext_mkuserimg", "verity", "verity_key", "verity_signer_cmd", "verity_fec", "avb_enable", "avb_avbtool", "avb_salt", ) for p in common_props: copy_prop(p, p) d["mount_point"] = mount_point if mount_point == "system": copy_prop("avb_system_hashtree_enable", "avb_hashtree_enable") copy_prop("avb_system_add_hashtree_footer_args", "avb_add_hashtree_footer_args") copy_prop("avb_system_key_path", "avb_key_path") copy_prop("avb_system_algorithm", "avb_algorithm") copy_prop("fs_type", "fs_type") # Copy the generic system fs type first, override with specific one if # available. copy_prop("system_fs_type", "fs_type") copy_prop("system_headroom", "partition_headroom") copy_prop("system_size", "partition_size") copy_prop("system_journal_size", "journal_size") copy_prop("system_verity_block_device", "verity_block_device") copy_prop("system_root_image", "system_root_image") copy_prop("ramdisk_dir", "ramdisk_dir") copy_prop("ramdisk_fs_config", "ramdisk_fs_config") copy_prop("has_ext4_reserved_blocks", "has_ext4_reserved_blocks") copy_prop("system_squashfs_compressor", "squashfs_compressor") copy_prop("system_squashfs_compressor_opt", "squashfs_compressor_opt") copy_prop("system_squashfs_block_size", "squashfs_block_size") copy_prop("system_squashfs_disable_4k_align", "squashfs_disable_4k_align") copy_prop("system_base_fs_file", "base_fs_file") copy_prop("system_extfs_inode_count", "extfs_inode_count") elif mount_point == "system_other": # We inherit the selinux policies of /system since we contain some of its files. d["mount_point"] = "system" copy_prop("avb_system_hashtree_enable", "avb_hashtree_enable") copy_prop("avb_system_add_hashtree_footer_args", "avb_add_hashtree_footer_args") copy_prop("avb_system_key_path", "avb_key_path") copy_prop("avb_system_algorithm", "avb_algorithm") copy_prop("fs_type", "fs_type") copy_prop("system_fs_type", "fs_type") copy_prop("system_size", "partition_size") copy_prop("system_journal_size", "journal_size") copy_prop("system_verity_block_device", "verity_block_device") copy_prop("has_ext4_reserved_blocks", "has_ext4_reserved_blocks") copy_prop("system_squashfs_compressor", "squashfs_compressor") copy_prop("system_squashfs_compressor_opt", "squashfs_compressor_opt") copy_prop("system_squashfs_block_size", "squashfs_block_size") copy_prop("system_base_fs_file", "base_fs_file") copy_prop("system_extfs_inode_count", "extfs_inode_count") elif mount_point == "data": # Copy the generic fs type first, override with specific one if available. copy_prop("fs_type", "fs_type") copy_prop("userdata_fs_type", "fs_type") copy_prop("userdata_size", "partition_size") copy_prop("flash_logical_block_size","flash_logical_block_size") copy_prop("flash_erase_block_size", "flash_erase_block_size") elif mount_point == "cache": copy_prop("cache_fs_type", "fs_type") copy_prop("cache_size", "partition_size") elif mount_point == "vendor": copy_prop("avb_vendor_hashtree_enable", "avb_hashtree_enable") copy_prop("avb_vendor_add_hashtree_footer_args", "avb_add_hashtree_footer_args") copy_prop("avb_vendor_key_path", "avb_key_path") copy_prop("avb_vendor_algorithm", "avb_algorithm") copy_prop("vendor_fs_type", "fs_type") copy_prop("vendor_size", "partition_size") copy_prop("vendor_journal_size", "journal_size") copy_prop("vendor_verity_block_device", "verity_block_device") copy_prop("has_ext4_reserved_blocks", "has_ext4_reserved_blocks") copy_prop("vendor_squashfs_compressor", "squashfs_compressor") copy_prop("vendor_squashfs_compressor_opt", "squashfs_compressor_opt") copy_prop("vendor_squashfs_block_size", "squashfs_block_size") copy_prop("vendor_squashfs_disable_4k_align", "squashfs_disable_4k_align") copy_prop("vendor_base_fs_file", "base_fs_file") copy_prop("vendor_extfs_inode_count", "extfs_inode_count") elif mount_point == "oem": copy_prop("fs_type", "fs_type") copy_prop("oem_size", "partition_size") copy_prop("oem_journal_size", "journal_size") copy_prop("has_ext4_reserved_blocks", "has_ext4_reserved_blocks") copy_prop("oem_extfs_inode_count", "extfs_inode_count") d["partition_name"] = mount_point return d def LoadGlobalDict(filename): """Load "name=value" pairs from filename""" d = {} f = open(filename) for line in f: line = line.strip() if not line or line.startswith("#"): continue k, v = line.split("=", 1) d[k] = v f.close() return d def main(argv): if len(argv) != 4: print __doc__ sys.exit(1) in_dir = argv[0] glob_dict_file = argv[1] out_file = argv[2] target_out = argv[3] glob_dict = LoadGlobalDict(glob_dict_file) if "mount_point" in glob_dict: # The caller knows the mount point and provides a dictionay needed by # BuildImage(). image_properties = glob_dict else: image_filename = os.path.basename(out_file) mount_point = "" if image_filename == "system.img": mount_point = "system" elif image_filename == "system_other.img": mount_point = "system_other" elif image_filename == "userdata.img": mount_point = "data" elif image_filename == "cache.img": mount_point = "cache" elif image_filename == "vendor.img": mount_point = "vendor" elif image_filename == "oem.img": mount_point = "oem" else: print >> sys.stderr, "error: unknown image file name ", image_filename exit(1) image_properties = ImagePropFromGlobalDict(glob_dict, mount_point) if not BuildImage(in_dir, image_properties, out_file, target_out): print >> sys.stderr, "error: failed to build %s from %s" % (out_file, in_dir) exit(1) if __name__ == '__main__': main(sys.argv[1:])