#!/usr/bin/env python3 # # 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. """ Builds output_image from the given input_directory, properties_file, and writes the image to target_output_directory. Usage: build_image input_directory properties_file output_image \\ target_output_directory """ import datetime import argparse import glob import logging import os import os.path import re import shlex import shutil import sys import uuid import tempfile import common import verity_utils logger = logging.getLogger(__name__) OPTIONS = common.OPTIONS BLOCK_SIZE = common.BLOCK_SIZE BYTES_IN_MB = 1024 * 1024 # Use a fixed timestamp (01/01/2009 00:00:00 UTC) for files when packaging # images. (b/24377993, b/80600931) FIXED_FILE_TIMESTAMP = int(( datetime.datetime(2009, 1, 1, 0, 0, 0, 0, None) - datetime.datetime.utcfromtimestamp(0)).total_seconds()) class BuildImageError(Exception): """An Exception raised during image building.""" def __init__(self, message): Exception.__init__(self, message) def GetDiskUsage(path): """Returns the number of bytes that "path" occupies on host. Args: path: The directory or file to calculate size on. Returns: The number of bytes based on a 1K block_size. """ cmd = ["du", "-b", "-k", "-s", path] output = common.RunAndCheckOutput(cmd, verbose=False) return int(output.split()[0]) * 1024 def GetInodeUsage(path): """Returns the number of inodes that "path" occupies on host. Args: path: The directory or file to calculate inode number on. Returns: The number of inodes used. """ cmd = ["find", path, "-print"] output = common.RunAndCheckOutput(cmd, verbose=False) # increase by > 6% as number of files and directories is not whole picture. inodes = output.count('\n') spare_inodes = inodes * 6 // 100 min_spare_inodes = 12 if spare_inodes < min_spare_inodes: spare_inodes = min_spare_inodes return inodes + spare_inodes def GetFilesystemCharacteristics(fs_type, image_path, sparse_image=True): """Returns various filesystem characteristics of "image_path". Args: image_path: The file to analyze. sparse_image: Image is sparse Returns: The characteristics dictionary. """ unsparse_image_path = image_path if sparse_image: unsparse_image_path = UnsparseImage(image_path, replace=False) if fs_type.startswith("ext"): cmd = ["tune2fs", "-l", unsparse_image_path] elif fs_type.startswith("f2fs"): cmd = ["fsck.f2fs", "-l", unsparse_image_path] try: output = common.RunAndCheckOutput(cmd, verbose=False) finally: if sparse_image: os.remove(unsparse_image_path) fs_dict = {} for line in output.splitlines(): fields = line.split(":") if len(fields) == 2: fs_dict[fields[0].strip()] = fields[1].strip() return fs_dict 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 unsparse_image_path inflate_command = ["simg2img", sparse_image_path, unsparse_image_path] try: common.RunAndCheckOutput(inflate_command) except: os.remove(unsparse_image_path) raise return unsparse_image_path def ConvertBlockMapToBaseFs(block_map_file): base_fs_file = common.MakeTempFile(prefix="script_gen_", suffix=".base_fs") convert_command = ["blk_alloc_to_base_fs", block_map_file, base_fs_file] common.RunAndCheckOutput(convert_command) return base_fs_file def SetUpInDirAndFsConfig(origin_in, prop_dict): """Returns the in_dir and fs_config that should be used for image building. When building system.img for all targets, it creates and returns a staged dir that combines the contents of /system (i.e. in the given in_dir) and root. Args: origin_in: Path to the input directory. prop_dict: A property dict that contains info like partition size. Values may be updated. Returns: A tuple of in_dir and fs_config that should be used to build the image. """ fs_config = prop_dict.get("fs_config") if prop_dict["mount_point"] == "system_other": prop_dict["mount_point"] = "system" return origin_in, fs_config if prop_dict["mount_point"] != "system": return origin_in, fs_config if "first_pass" in prop_dict: prop_dict["mount_point"] = "/" return prop_dict["first_pass"] # Construct a staging directory of the root file system. in_dir = common.MakeTempDir() root_dir = prop_dict.get("root_dir") if root_dir: shutil.rmtree(in_dir) shutil.copytree(root_dir, in_dir, symlinks=True) in_dir_system = os.path.join(in_dir, "system") shutil.rmtree(in_dir_system, ignore_errors=True) shutil.copytree(origin_in, in_dir_system, symlinks=True) # Change the mount point to "/". prop_dict["mount_point"] = "/" if fs_config: # We need to merge the fs_config files of system and root. merged_fs_config = common.MakeTempFile( prefix="merged_fs_config", suffix=".txt") with open(merged_fs_config, "w") as fw: if "root_fs_config" in prop_dict: with open(prop_dict["root_fs_config"]) as fr: fw.writelines(fr.readlines()) with open(fs_config) as fr: fw.writelines(fr.readlines()) fs_config = merged_fs_config prop_dict["first_pass"] = (in_dir, fs_config) return in_dir, fs_config def CheckHeadroom(ext4fs_output, prop_dict): """Checks if there's enough headroom space available. Headroom is the reserved space on system image (via PRODUCT_SYSTEM_HEADROOM), which is useful for devices with low disk space that have system image variation between builds. The 'partition_headroom' in prop_dict is the size in bytes, while the numbers in 'ext4fs_output' are for 4K-blocks. Args: ext4fs_output: The output string from mke2fs command. prop_dict: The property dict. Raises: AssertionError: On invalid input. BuildImageError: On check failure. """ assert ext4fs_output is not None assert prop_dict.get('fs_type', '').startswith('ext4') assert 'partition_headroom' in prop_dict assert 'mount_point' in prop_dict ext4fs_stats = re.compile( r'Created filesystem with .* (?P[0-9]+)/' r'(?P[0-9]+) blocks') last_line = ext4fs_output.strip().split('\n')[-1] m = ext4fs_stats.match(last_line) used_blocks = int(m.groupdict().get('used_blocks')) total_blocks = int(m.groupdict().get('total_blocks')) headroom_blocks = int(prop_dict['partition_headroom']) // BLOCK_SIZE adjusted_blocks = total_blocks - headroom_blocks if used_blocks > adjusted_blocks: mount_point = prop_dict["mount_point"] raise BuildImageError( "Error: Not enough room on {} (total: {} blocks, used: {} blocks, " "headroom: {} blocks, available: {} blocks)".format( mount_point, total_blocks, used_blocks, headroom_blocks, adjusted_blocks)) def CalculateSizeAndReserved(prop_dict, size): fs_type = prop_dict.get("fs_type", "") partition_headroom = int(prop_dict.get("partition_headroom", 0)) # If not specified, give us 16MB margin for GetDiskUsage error ... reserved_size = int(prop_dict.get( "partition_reserved_size", BYTES_IN_MB * 16)) if fs_type == "erofs": reserved_size = int(prop_dict.get("partition_reserved_size", 0)) if reserved_size == 0: # give .3% margin or a minimum size for AVB footer return max(size * 1003 // 1000, 256 * 1024) if fs_type.startswith("ext4") and partition_headroom > reserved_size: reserved_size = partition_headroom return int(size * 1.1) + reserved_size def BuildImageMkfs(in_dir, prop_dict, out_file, target_out, fs_config): """Builds a pure image for the files under in_dir and writes it to out_file. Args: in_dir: Path to input directory. prop_dict: A property dict that contains info like partition size. Values will be updated with computed values. out_file: The output image file. target_out: Path to the TARGET_OUT directory as in Makefile. It actually points to the /system directory under PRODUCT_OUT. fs_config (the one under system/core/libcutils) reads device specific FS config files from there. fs_config: The fs_config file that drives the prototype Raises: BuildImageError: On build image failures. """ build_command = [] fs_type = prop_dict.get("fs_type", "") run_fsck = None needs_projid = prop_dict.get("needs_projid", 0) needs_casefold = prop_dict.get("needs_casefold", 0) needs_compress = prop_dict.get("needs_compress", 0) disable_sparse = "disable_sparse" in prop_dict manual_sparse = False if fs_type.startswith("ext"): build_command = [prop_dict["ext_mkuserimg"]] if "extfs_sparse_flag" in prop_dict and not disable_sparse: build_command.append(prop_dict["extfs_sparse_flag"]) run_fsck = RunE2fsck build_command.extend([in_dir, out_file, fs_type, prop_dict["mount_point"]]) build_command.append(prop_dict["image_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"]) 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 "extfs_rsv_pct" in prop_dict: build_command.extend(["-M", prop_dict["extfs_rsv_pct"]]) 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 os.path.basename(prop_dict["ext_mkuserimg"]) == "mkuserimg_mke2fs": 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 prop_dict.get("ext4_share_dup_blocks") == "true": build_command.append("-c") if (needs_projid): build_command.extend(["--inode_size", "512"]) else: build_command.extend(["--inode_size", "256"]) if "selinux_fc" in prop_dict: build_command.append(prop_dict["selinux_fc"]) elif fs_type.startswith("erofs"): build_command = ["mkfs.erofs"] compressor = None if "erofs_default_compressor" in prop_dict: compressor = prop_dict["erofs_default_compressor"] if "erofs_compressor" in prop_dict: compressor = prop_dict["erofs_compressor"] if compressor and compressor != "none": build_command.extend(["-z", compressor]) compress_hints = None if "erofs_default_compress_hints" in prop_dict: compress_hints = prop_dict["erofs_default_compress_hints"] if "erofs_compress_hints" in prop_dict: compress_hints = prop_dict["erofs_compress_hints"] if compress_hints: build_command.extend(["--compress-hints", compress_hints]) build_command.extend(["-b", prop_dict.get("erofs_blocksize", "4096")]) build_command.extend(["--mount-point", prop_dict["mount_point"]]) if target_out: build_command.extend(["--product-out", target_out]) if fs_config: build_command.extend(["--fs-config-file", fs_config]) if "selinux_fc" in prop_dict: build_command.extend(["--file-contexts", prop_dict["selinux_fc"]]) if "timestamp" in prop_dict: build_command.extend(["-T", str(prop_dict["timestamp"])]) if "uuid" in prop_dict: build_command.extend(["-U", prop_dict["uuid"]]) if "block_list" in prop_dict: build_command.extend(["--block-list-file", prop_dict["block_list"]]) if "erofs_pcluster_size" in prop_dict: build_command.extend(["-C", prop_dict["erofs_pcluster_size"]]) if "erofs_share_dup_blocks" in prop_dict: build_command.extend(["--chunksize", "4096"]) if "erofs_use_legacy_compression" in prop_dict: build_command.extend(["-E", "legacy-compress"]) build_command.extend([out_file, in_dir]) if "erofs_sparse_flag" in prop_dict and not disable_sparse: manual_sparse = True run_fsck = RunErofsFsck elif fs_type.startswith("squash"): build_command = ["mksquashfsimage"] build_command.extend([in_dir, out_file]) if "squashfs_sparse_flag" in prop_dict and not disable_sparse: 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_block_size" in prop_dict: build_command.extend(["-b", prop_dict["squashfs_block_size"]]) 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 prop_dict.get("squashfs_disable_4k_align") == "true": build_command.extend(["-a"]) elif fs_type.startswith("f2fs"): build_command = ["mkf2fsuserimg"] build_command.extend([out_file, prop_dict["image_size"]]) if "f2fs_sparse_flag" in prop_dict and not disable_sparse: build_command.extend([prop_dict["f2fs_sparse_flag"]]) if fs_config: build_command.extend(["-C", fs_config]) build_command.extend(["-f", in_dir]) if target_out: build_command.extend(["-D", target_out]) if "selinux_fc" in prop_dict: build_command.extend(["-s", prop_dict["selinux_fc"]]) build_command.extend(["-t", prop_dict["mount_point"]]) if "timestamp" in prop_dict: build_command.extend(["-T", str(prop_dict["timestamp"])]) if "block_list" in prop_dict: build_command.extend(["-B", prop_dict["block_list"]]) build_command.extend(["-L", prop_dict["mount_point"]]) if (needs_projid): build_command.append("--prjquota") if (needs_casefold): build_command.append("--casefold") if (needs_compress or prop_dict.get("f2fs_compress") == "true"): build_command.append("--compression") if "ro_mount_point" in prop_dict: build_command.append("--readonly") if (prop_dict.get("f2fs_compress") == "true"): build_command.append("--sldc") if (prop_dict.get("f2fs_sldc_flags") == None): build_command.append(str(0)) else: sldc_flags_str = prop_dict.get("f2fs_sldc_flags") sldc_flags = sldc_flags_str.split() build_command.append(str(len(sldc_flags))) build_command.extend(sldc_flags) f2fs_blocksize = prop_dict.get("f2fs_blocksize", "4096") build_command.extend(["-b", f2fs_blocksize]) else: raise BuildImageError( "Error: unknown filesystem type: {}".format(fs_type)) try: mkfs_output = common.RunAndCheckOutput(build_command) except: try: du = GetDiskUsage(in_dir) du_str = "{} bytes ({} MB)".format(du, du // BYTES_IN_MB) # Suppress any errors from GetDiskUsage() to avoid hiding the real errors # from common.RunAndCheckOutput(). except Exception: # pylint: disable=broad-except logger.exception("Failed to compute disk usage with du") du_str = "unknown" print( "Out of space? Out of inodes? The tree size of {} is {}, " "with reserved space of {} bytes ({} MB).".format( in_dir, du_str, int(prop_dict.get("partition_reserved_size", 0)), int(prop_dict.get("partition_reserved_size", 0)) // BYTES_IN_MB)) if ("image_size" in prop_dict and "partition_size" in prop_dict): print( "The max image size for filesystem files is {} bytes ({} MB), " "out of a total partition size of {} bytes ({} MB).".format( int(prop_dict["image_size"]), int(prop_dict["image_size"]) // BYTES_IN_MB, int(prop_dict["partition_size"]), int(prop_dict["partition_size"]) // BYTES_IN_MB)) raise if run_fsck and prop_dict.get("skip_fsck") != "true": run_fsck(out_file) if manual_sparse: temp_file = out_file + ".sparse" img2simg_argv = ["img2simg", out_file, temp_file] common.RunAndCheckOutput(img2simg_argv) os.rename(temp_file, out_file) return mkfs_output def RunE2fsck(out_file): unsparse_image = UnsparseImage(out_file, replace=False) # Run e2fsck on the inflated image file e2fsck_command = ["e2fsck", "-f", "-n", unsparse_image] try: common.RunAndCheckOutput(e2fsck_command) finally: os.remove(unsparse_image) def RunErofsFsck(out_file): fsck_command = ["fsck.erofs", "--extract", out_file] try: common.RunAndCheckOutput(fsck_command) except: print("Check failed for EROFS image {}".format(out_file)) raise def SetUUIDIfNotExist(image_props): # Use repeatable ext4 FS UUID and hash_seed UUID (based on partition name and # build fingerprint). Also use the legacy build id, because the vbmeta digest # isn't available at this point. what = image_props["mount_point"] fingerprint = image_props.get("fingerprint", "") uuid_seed = what + "-" + fingerprint logger.info("Using fingerprint %s for partition %s", fingerprint, what) image_props["uuid"] = str(uuid.uuid5(uuid.NAMESPACE_URL, uuid_seed)) hash_seed = "hash_seed-" + uuid_seed image_props["hash_seed"] = str(uuid.uuid5(uuid.NAMESPACE_URL, hash_seed)) def BuildImage(in_dir, prop_dict, out_file, target_out=None): """Builds an image for the files under in_dir and writes it to out_file. Args: in_dir: Path to input directory. prop_dict: A property dict that contains info like partition size. Values will be updated with computed values. out_file: The output image file. target_out: Path to the TARGET_OUT directory as in Makefile. It actually points to the /system directory under PRODUCT_OUT. fs_config (the one under system/core/libcutils) reads device specific FS config files from there. Raises: BuildImageError: On build image failures. """ in_dir, fs_config = SetUpInDirAndFsConfig(in_dir, prop_dict) SetUUIDIfNotExist(prop_dict) build_command = [] fs_type = prop_dict.get("fs_type", "") fs_spans_partition = True if fs_type.startswith("squash") or fs_type.startswith("erofs"): fs_spans_partition = False elif fs_type.startswith("f2fs") and prop_dict.get("f2fs_compress") == "true": fs_spans_partition = False # Get a builder for creating an image that's to be verified by Verified Boot, # or None if not applicable. verity_image_builder = verity_utils.CreateVerityImageBuilder(prop_dict) disable_sparse = "disable_sparse" in prop_dict mkfs_output = None if (prop_dict.get("use_dynamic_partition_size") == "true" and "partition_size" not in prop_dict): # If partition_size is not defined, use output of `du' + reserved_size. # For compressed file system, it's better to use the compressed size to avoid wasting space. if fs_type.startswith("erofs"): mkfs_output = BuildImageMkfs( in_dir, prop_dict, out_file, target_out, fs_config) if "erofs_sparse_flag" in prop_dict and not disable_sparse: image_path = UnsparseImage(out_file, replace=False) size = GetDiskUsage(image_path) os.remove(image_path) else: size = GetDiskUsage(out_file) else: size = GetDiskUsage(in_dir) logger.info( "The tree size of %s is %d MB.", in_dir, size // BYTES_IN_MB) size = CalculateSizeAndReserved(prop_dict, size) # Round this up to a multiple of 4K so that avbtool works size = common.RoundUpTo4K(size) if fs_type.startswith("ext"): prop_dict["partition_size"] = str(size) prop_dict["image_size"] = str(size) if "extfs_inode_count" not in prop_dict: prop_dict["extfs_inode_count"] = str(GetInodeUsage(in_dir)) logger.info( "First Pass based on estimates of %d MB and %s inodes.", size // BYTES_IN_MB, prop_dict["extfs_inode_count"]) BuildImageMkfs(in_dir, prop_dict, out_file, target_out, fs_config) sparse_image = False if "extfs_sparse_flag" in prop_dict and not disable_sparse: sparse_image = True fs_dict = GetFilesystemCharacteristics(fs_type, out_file, sparse_image) os.remove(out_file) block_size = int(fs_dict.get("Block size", "4096")) free_size = int(fs_dict.get("Free blocks", "0")) * block_size reserved_size = int(prop_dict.get("partition_reserved_size", 0)) partition_headroom = int(fs_dict.get("partition_headroom", 0)) if fs_type.startswith("ext4") and partition_headroom > reserved_size: reserved_size = partition_headroom if free_size <= reserved_size: logger.info( "Not worth reducing image %d <= %d.", free_size, reserved_size) else: size -= free_size size += reserved_size if reserved_size == 0: # add .3% margin size = size * 1003 // 1000 # Use a minimum size, otherwise we will fail to calculate an AVB footer # or fail to construct an ext4 image. size = max(size, 256 * 1024) if block_size <= 4096: size = common.RoundUpTo4K(size) else: size = ((size + block_size - 1) // block_size) * block_size extfs_inode_count = prop_dict["extfs_inode_count"] inodes = int(fs_dict.get("Inode count", extfs_inode_count)) inodes -= int(fs_dict.get("Free inodes", "0")) # add .2% margin or 1 inode, whichever is greater spare_inodes = inodes * 2 // 1000 min_spare_inodes = 1 if spare_inodes < min_spare_inodes: spare_inodes = min_spare_inodes inodes += spare_inodes prop_dict["extfs_inode_count"] = str(inodes) prop_dict["partition_size"] = str(size) logger.info( "Allocating %d Inodes for %s.", inodes, out_file) elif fs_type.startswith("f2fs") and prop_dict.get("f2fs_compress") == "true": prop_dict["partition_size"] = str(size) prop_dict["image_size"] = str(size) BuildImageMkfs(in_dir, prop_dict, out_file, target_out, fs_config) sparse_image = False if "f2fs_sparse_flag" in prop_dict and not disable_sparse: sparse_image = True fs_dict = GetFilesystemCharacteristics(fs_type, out_file, sparse_image) os.remove(out_file) block_count = int(fs_dict.get("block_count", "0")) log_blocksize = int(fs_dict.get("log_blocksize", "12")) size = block_count << log_blocksize prop_dict["partition_size"] = str(size) if verity_image_builder: size = verity_image_builder.CalculateDynamicPartitionSize(size) prop_dict["partition_size"] = str(size) logger.info( "Allocating %d MB for %s", size // BYTES_IN_MB, out_file) prop_dict["image_size"] = prop_dict["partition_size"] # Adjust the image size to make room for the hashes if this is to be verified. if verity_image_builder: max_image_size = verity_image_builder.CalculateMaxImageSize() prop_dict["image_size"] = str(max_image_size) if not mkfs_output: mkfs_output = BuildImageMkfs( in_dir, prop_dict, out_file, target_out, fs_config) # Update the image (eg filesystem size). This can be different eg if mkfs # rounds the requested size down due to alignment. prop_dict["image_size"] = common.sparse_img.GetImagePartitionSize(out_file) # Check if there's enough headroom space available for ext4 image. if "partition_headroom" in prop_dict and fs_type.startswith("ext4"): CheckHeadroom(mkfs_output, prop_dict) if not fs_spans_partition and verity_image_builder: verity_image_builder.PadSparseImage(out_file) # Create the verified image if this is to be verified. if verity_image_builder: verity_image_builder.Build(out_file) def TryParseFingerprint(glob_dict: dict): for (key, val) in glob_dict.items(): if not key.endswith("_add_hashtree_footer_args") and not key.endswith("_add_hash_footer_args"): continue for arg in shlex.split(val): m = re.match(r"^com\.android\.build\.\w+\.fingerprint:", arg) if m is None: continue fingerprint = arg[len(m.group()):] glob_dict["fingerprint"] = fingerprint return 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 = {} TryParseFingerprint(glob_dict) # Set fixed timestamp for building the OTA package. if "use_fixed_timestamp" in glob_dict: d["timestamp"] = FIXED_FILE_TIMESTAMP if "build.prop" in glob_dict: timestamp = glob_dict["build.prop"].GetProp("ro.build.date.utc") if timestamp: d["timestamp"] = timestamp def copy_prop(src_p, dest_p): """Copy a property from the global dictionary. Args: src_p: The source property in the global dictionary. dest_p: The destination property. Returns: True if property was found and copied, False otherwise. """ if src_p in glob_dict: d[dest_p] = str(glob_dict[src_p]) return True return False common_props = ( "extfs_sparse_flag", "erofs_default_compressor", "erofs_default_compress_hints", "erofs_pcluster_size", "erofs_blocksize", "erofs_share_dup_blocks", "erofs_sparse_flag", "erofs_use_legacy_compression", "squashfs_sparse_flag", "system_f2fs_compress", "system_f2fs_sldc_flags", "f2fs_sparse_flag", "f2fs_blocksize", "skip_fsck", "ext_mkuserimg", "avb_enable", "avb_avbtool", "use_dynamic_partition_size", "fingerprint", ) for p in common_props: copy_prop(p, p) ro_mount_points = set([ "odm", "odm_dlkm", "oem", "product", "system", "system_dlkm", "system_ext", "system_other", "vendor", "vendor_dlkm", ]) # Tuple layout: (readonly, specific prop, general prop) fmt_props = ( # Generic first, then specific file type. (False, "fs_type", "fs_type"), (False, "{}_fs_type", "fs_type"), # Ordering for these doesn't matter. (False, "{}_selinux_fc", "selinux_fc"), (False, "{}_size", "partition_size"), (True, "avb_{}_add_hashtree_footer_args", "avb_add_hashtree_footer_args"), (True, "avb_{}_algorithm", "avb_algorithm"), (True, "avb_{}_hashtree_enable", "avb_hashtree_enable"), (True, "avb_{}_key_path", "avb_key_path"), (True, "avb_{}_salt", "avb_salt"), (True, "erofs_use_legacy_compression", "erofs_use_legacy_compression"), (True, "ext4_share_dup_blocks", "ext4_share_dup_blocks"), (True, "{}_base_fs_file", "base_fs_file"), (True, "{}_disable_sparse", "disable_sparse"), (True, "{}_erofs_compressor", "erofs_compressor"), (True, "{}_erofs_compress_hints", "erofs_compress_hints"), (True, "{}_erofs_pcluster_size", "erofs_pcluster_size"), (True, "{}_erofs_blocksize", "erofs_blocksize"), (True, "{}_erofs_share_dup_blocks", "erofs_share_dup_blocks"), (True, "{}_extfs_inode_count", "extfs_inode_count"), (True, "{}_f2fs_compress", "f2fs_compress"), (True, "{}_f2fs_sldc_flags", "f2fs_sldc_flags"), (True, "{}_f2fs_blocksize", "f2fs_block_size"), (True, "{}_reserved_size", "partition_reserved_size"), (True, "{}_squashfs_block_size", "squashfs_block_size"), (True, "{}_squashfs_compressor", "squashfs_compressor"), (True, "{}_squashfs_compressor_opt", "squashfs_compressor_opt"), (True, "{}_squashfs_disable_4k_align", "squashfs_disable_4k_align"), (True, "{}_verity_block_device", "verity_block_device"), ) # Translate prefixed properties into generic ones. if mount_point == "data": prefix = "userdata" else: prefix = mount_point for readonly, src_prop, dest_prop in fmt_props: if readonly and mount_point not in ro_mount_points: continue if src_prop == "fs_type": # This property is legacy and only used on a few partitions. b/202600377 allowed_partitions = set(["system", "system_other", "data", "oem"]) if mount_point not in allowed_partitions: continue if (mount_point == "system_other") and (dest_prop != "partition_size"): # Propagate system properties to system_other. They'll get overridden # after as needed. copy_prop(src_prop.format("system"), dest_prop) copy_prop(src_prop.format(prefix), dest_prop) # Set prefixed properties that need a default value. if mount_point in ro_mount_points: prop = "{}_journal_size".format(prefix) if not copy_prop(prop, "journal_size"): d["journal_size"] = "0" prop = "{}_extfs_rsv_pct".format(prefix) if not copy_prop(prop, "extfs_rsv_pct"): d["extfs_rsv_pct"] = "0" d["ro_mount_point"] = "1" # Copy partition-specific properties. d["mount_point"] = mount_point if mount_point == "system": copy_prop("system_headroom", "partition_headroom") copy_prop("root_dir", "root_dir") copy_prop("root_fs_config", "root_fs_config") elif mount_point == "data": # Copy the generic fs type first, override with specific one if available. copy_prop("flash_logical_block_size", "flash_logical_block_size") copy_prop("flash_erase_block_size", "flash_erase_block_size") copy_prop("needs_casefold", "needs_casefold") copy_prop("needs_projid", "needs_projid") copy_prop("needs_compress", "needs_compress") 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 GlobalDictFromImageProp(image_prop, mount_point): d = {} def copy_prop(src_p, dest_p): if src_p in image_prop: d[dest_p] = image_prop[src_p] return True return False if mount_point == "system": copy_prop("partition_size", "system_size") elif mount_point == "system_other": copy_prop("partition_size", "system_other_size") elif mount_point == "vendor": copy_prop("partition_size", "vendor_size") elif mount_point == "odm": copy_prop("partition_size", "odm_size") elif mount_point == "vendor_dlkm": copy_prop("partition_size", "vendor_dlkm_size") elif mount_point == "odm_dlkm": copy_prop("partition_size", "odm_dlkm_size") elif mount_point == "system_dlkm": copy_prop("partition_size", "system_dlkm_size") elif mount_point == "product": copy_prop("partition_size", "product_size") elif mount_point == "system_ext": copy_prop("partition_size", "system_ext_size") return d def BuildVBMeta(in_dir, glob_dict, output_path): """Creates a VBMeta image. It generates the requested VBMeta image. The requested image could be for top-level or chained VBMeta image, which is determined based on the name. Args: output_path: Path to generated vbmeta.img partitions: A dict that's keyed by partition names with image paths as values. Only valid partition names are accepted, as partitions listed in common.AVB_PARTITIONS and custom partitions listed in OPTIONS.info_dict.get("avb_custom_images_partition_list") name: Name of the VBMeta partition, e.g. 'vbmeta', 'vbmeta_system'. needed_partitions: Partitions whose descriptors should be included into the generated VBMeta image. Returns: Path to the created image. Raises: AssertionError: On invalid input args. """ vbmeta_partitions = common.AVB_PARTITIONS[:] name = os.path.basename(output_path).rstrip(".img") vbmeta_system = glob_dict.get("avb_vbmeta_system", "").strip() vbmeta_vendor = glob_dict.get("avb_vbmeta_vendor", "").strip() if "vbmeta_system" in name: vbmeta_partitions = vbmeta_system.split() elif "vbmeta_vendor" in name: vbmeta_partitions = vbmeta_vendor.split() else: if vbmeta_system: vbmeta_partitions = [ item for item in vbmeta_partitions if item not in vbmeta_system.split()] vbmeta_partitions.append("vbmeta_system") if vbmeta_vendor: vbmeta_partitions = [ item for item in vbmeta_partitions if item not in vbmeta_vendor.split()] vbmeta_partitions.append("vbmeta_vendor") partitions = {part: os.path.join(in_dir, part + ".img") for part in vbmeta_partitions} partitions = {part: path for (part, path) in partitions.items() if os.path.exists(path)} common.BuildVBMeta(output_path, partitions, name, vbmeta_partitions) def BuildImageOrVBMeta(input_directory, target_out, glob_dict, image_properties, out_file): try: if "vbmeta" in os.path.basename(out_file): OPTIONS.info_dict = glob_dict BuildVBMeta(input_directory, glob_dict, out_file) else: BuildImage(input_directory, image_properties, out_file, target_out) except: logger.error("Failed to build %s from %s", out_file, input_directory) raise def CopyInputDirectory(src, dst, filter_file): with open(filter_file, 'r') as f: for line in f: line = line.strip() if not line: return if line != os.path.normpath(line): sys.exit(f"{line}: not normalized") if line.startswith("../") or line.startswith('/'): sys.exit(f"{line}: escapes staging directory by starting with ../ or /") full_src = os.path.join(src, line) full_dst = os.path.join(dst, line) if os.path.isdir(full_src): os.makedirs(full_dst, exist_ok=True) else: os.makedirs(os.path.dirname(full_dst), exist_ok=True) os.link(full_src, full_dst, follow_symlinks=False) def main(argv): parser = argparse.ArgumentParser( description="Builds output_image from the given input_directory and properties_file, and " "writes the image to target_output_directory.") parser.add_argument("--input-directory-filter-file", help="the path to a file that contains a list of all files in the input_directory. If this " "option is provided, all files under the input_directory that are not listed in this file will " "be deleted before building the image. This is to work around the fact that building a module " "will install in by default, so there could be files in the input_directory that are not " "actually supposed to be part of the partition. The paths in this file must be relative to " "input_directory.") parser.add_argument("input_directory", help="the staging directory to be converted to an image file") parser.add_argument("properties_file", help="a file containing the 'global dictionary' of properties that affect how the image is " "built") parser.add_argument("out_file", help="the output file to write") parser.add_argument("target_out", help="the path to $(TARGET_OUT). Certain tools will use this to look through multiple staging " "directories for fs config files.") parser.add_argument("-v", action="store_true", help="Enable verbose logging", dest="verbose") args = parser.parse_args() if args.verbose: OPTIONS.verbose = True common.InitLogging() glob_dict = LoadGlobalDict(args.properties_file) if "mount_point" in glob_dict: # The caller knows the mount point and provides a dictionary needed by # BuildImage(). image_properties = glob_dict else: image_filename = os.path.basename(args.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 == "odm.img": mount_point = "odm" elif image_filename == "vendor_dlkm.img": mount_point = "vendor_dlkm" elif image_filename == "odm_dlkm.img": mount_point = "odm_dlkm" elif image_filename == "system_dlkm.img": mount_point = "system_dlkm" elif image_filename == "oem.img": mount_point = "oem" elif image_filename == "product.img": mount_point = "product" elif image_filename == "system_ext.img": mount_point = "system_ext" elif "vbmeta" in image_filename: mount_point = "vbmeta" else: logger.error("Unknown image file name %s", image_filename) sys.exit(1) if "vbmeta" != mount_point: image_properties = ImagePropFromGlobalDict(glob_dict, mount_point) if args.input_directory_filter_file and not os.environ.get("BUILD_BROKEN_INCORRECT_PARTITION_IMAGES"): with tempfile.TemporaryDirectory(dir=os.path.dirname(args.input_directory)) as new_input_directory: CopyInputDirectory(args.input_directory, new_input_directory, args.input_directory_filter_file) BuildImageOrVBMeta(new_input_directory, args.target_out, glob_dict, image_properties, args.out_file) else: BuildImageOrVBMeta(args.input_directory, args.target_out, glob_dict, image_properties, args.out_file) if __name__ == '__main__': try: main(sys.argv[1:]) finally: common.Cleanup()