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fuchsia / third_party / android / platform / system / core / refs/tags/android-cts-8.0_r10 / . / fs_mgr / fs_mgr_avb.cpp
blob: 36883e67703474e9a398ff7d380e7754e1830a50 [file] [log] [blame]
/*
* Copyright (C) 2016 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.
*/
#include "fs_mgr_avb.h"
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <libgen.h>
#include <stdio.h>
#include <string.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <unistd.h>
#include <vector>
#include <android-base/file.h>
#include <android-base/parseint.h>
#include <android-base/properties.h>
#include <android-base/stringprintf.h>
#include <android-base/strings.h>
#include <android-base/unique_fd.h>
#include <cutils/properties.h>
#include <libavb/libavb.h>
#include <openssl/sha.h>
#include <sys/ioctl.h>
#include <utils/Compat.h>
#include "fs_mgr.h"
#include "fs_mgr_priv.h"
#include "fs_mgr_priv_avb_ops.h"
#include "fs_mgr_priv_dm_ioctl.h"
#include "fs_mgr_priv_sha.h"
/* The format of dm-verity construction parameters:
* <version> <dev> <hash_dev> <data_block_size> <hash_block_size>
* <num_data_blocks> <hash_start_block> <algorithm> <digest> <salt>
*/
#define VERITY_TABLE_FORMAT \
"%u %s %s %u %u " \
"%" PRIu64 " %" PRIu64 " %s %s %s "
#define VERITY_TABLE_PARAMS(hashtree_desc, blk_device, digest, salt) \
hashtree_desc.dm_verity_version, blk_device, blk_device, hashtree_desc.data_block_size, \
hashtree_desc.hash_block_size, \
hashtree_desc.image_size / hashtree_desc.data_block_size, /* num_data_blocks. */ \
hashtree_desc.tree_offset / hashtree_desc.hash_block_size, /* hash_start_block. */ \
(char*)hashtree_desc.hash_algorithm, digest, salt
#define VERITY_TABLE_OPT_RESTART "restart_on_corruption"
#define VERITY_TABLE_OPT_IGNZERO "ignore_zero_blocks"
/* The default format of dm-verity optional parameters:
* <#opt_params> ignore_zero_blocks restart_on_corruption
*/
#define VERITY_TABLE_OPT_DEFAULT_FORMAT "2 %s %s"
#define VERITY_TABLE_OPT_DEFAULT_PARAMS VERITY_TABLE_OPT_IGNZERO, VERITY_TABLE_OPT_RESTART
/* The FEC (forward error correction) format of dm-verity optional parameters:
* <#opt_params> use_fec_from_device <fec_dev>
* fec_roots <num> fec_blocks <num> fec_start <offset>
* ignore_zero_blocks restart_on_corruption
*/
#define VERITY_TABLE_OPT_FEC_FORMAT \
"10 use_fec_from_device %s fec_roots %u fec_blocks %" PRIu64 " fec_start %" PRIu64 " %s %s"
/* Note that fec_blocks is the size that FEC covers, *not* the
* size of the FEC data. Since we use FEC for everything up until
* the FEC data, it's the same as the offset (fec_start).
*/
#define VERITY_TABLE_OPT_FEC_PARAMS(hashtree_desc, blk_device) \
blk_device, hashtree_desc.fec_num_roots, \
hashtree_desc.fec_offset / hashtree_desc.data_block_size, /* fec_blocks */ \
hashtree_desc.fec_offset / hashtree_desc.data_block_size, /* fec_start */ \
VERITY_TABLE_OPT_IGNZERO, VERITY_TABLE_OPT_RESTART
static inline bool nibble_value(const char& c, uint8_t* value) {
FS_MGR_CHECK(value != nullptr);
switch (c) {
case '0' ... '9':
*value = c - '0';
break;
case 'a' ... 'f':
*value = c - 'a' + 10;
break;
case 'A' ... 'F':
*value = c - 'A' + 10;
break;
default:
return false;
}
return true;
}
static bool hex_to_bytes(uint8_t* bytes, size_t bytes_len, const std::string& hex) {
FS_MGR_CHECK(bytes != nullptr);
if (hex.size() % 2 != 0) {
return false;
}
if (hex.size() / 2 > bytes_len) {
return false;
}
for (size_t i = 0, j = 0, n = hex.size(); i < n; i += 2, ++j) {
uint8_t high;
if (!nibble_value(hex[i], &high)) {
return false;
}
uint8_t low;
if (!nibble_value(hex[i + 1], &low)) {
return false;
}
bytes[j] = (high << 4) | low;
}
return true;
}
static std::string bytes_to_hex(const uint8_t* bytes, size_t bytes_len) {
FS_MGR_CHECK(bytes != nullptr);
static const char* hex_digits = "0123456789abcdef";
std::string hex;
for (size_t i = 0; i < bytes_len; i++) {
hex.push_back(hex_digits[(bytes[i] & 0xF0) >> 4]);
hex.push_back(hex_digits[bytes[i] & 0x0F]);
}
return hex;
}
template <typename Hasher>
static std::pair<size_t, bool> verify_vbmeta_digest(const AvbSlotVerifyData& verify_data,
const uint8_t* expected_digest) {
size_t total_size = 0;
Hasher hasher;
for (size_t n = 0; n < verify_data.num_vbmeta_images; n++) {
hasher.update(verify_data.vbmeta_images[n].vbmeta_data,
verify_data.vbmeta_images[n].vbmeta_size);
total_size += verify_data.vbmeta_images[n].vbmeta_size;
}
bool matched = (memcmp(hasher.finalize(), expected_digest, Hasher::DIGEST_SIZE) == 0);
return std::make_pair(total_size, matched);
}
// Reads the following values from kernel cmdline and provides the
// VerifyVbmetaImages() to verify AvbSlotVerifyData.
// - androidboot.vbmeta.device_state
// - androidboot.vbmeta.hash_alg
// - androidboot.vbmeta.size
// - androidboot.vbmeta.digest
class FsManagerAvbVerifier {
public:
// The factory method to return a unique_ptr<FsManagerAvbVerifier>
static std::unique_ptr<FsManagerAvbVerifier> Create();
bool VerifyVbmetaImages(const AvbSlotVerifyData& verify_data);
bool IsDeviceUnlocked() { return is_device_unlocked_; }
protected:
FsManagerAvbVerifier() = default;
private:
enum HashAlgorithm {
kInvalid = 0,
kSHA256 = 1,
kSHA512 = 2,
};
HashAlgorithm hash_alg_;
uint8_t digest_[SHA512_DIGEST_LENGTH];
size_t vbmeta_size_;
bool is_device_unlocked_;
};
std::unique_ptr<FsManagerAvbVerifier> FsManagerAvbVerifier::Create() {
std::string cmdline;
if (!android::base::ReadFileToString("/proc/cmdline", &cmdline)) {
LERROR << "Failed to read /proc/cmdline";
return nullptr;
}
std::unique_ptr<FsManagerAvbVerifier> avb_verifier(new FsManagerAvbVerifier());
if (!avb_verifier) {
LERROR << "Failed to create unique_ptr<FsManagerAvbVerifier>";
return nullptr;
}
std::string digest;
std::string hash_alg;
for (const auto& entry : android::base::Split(android::base::Trim(cmdline), " ")) {
std::vector<std::string> pieces = android::base::Split(entry, "=");
const std::string& key = pieces[0];
const std::string& value = pieces[1];
if (key == "androidboot.vbmeta.device_state") {
avb_verifier->is_device_unlocked_ = (value == "unlocked");
} else if (key == "androidboot.vbmeta.hash_alg") {
hash_alg = value;
} else if (key == "androidboot.vbmeta.size") {
if (!android::base::ParseUint(value.c_str(), &avb_verifier->vbmeta_size_)) {
return nullptr;
}
} else if (key == "androidboot.vbmeta.digest") {
digest = value;
}
}
// Reads hash algorithm.
size_t expected_digest_size = 0;
if (hash_alg == "sha256") {
expected_digest_size = SHA256_DIGEST_LENGTH * 2;
avb_verifier->hash_alg_ = kSHA256;
} else if (hash_alg == "sha512") {
expected_digest_size = SHA512_DIGEST_LENGTH * 2;
avb_verifier->hash_alg_ = kSHA512;
} else {
LERROR << "Unknown hash algorithm: " << hash_alg.c_str();
return nullptr;
}
// Reads digest.
if (digest.size() != expected_digest_size) {
LERROR << "Unexpected digest size: " << digest.size()
<< " (expected: " << expected_digest_size << ")";
return nullptr;
}
if (!hex_to_bytes(avb_verifier->digest_, sizeof(avb_verifier->digest_), digest)) {
LERROR << "Hash digest contains non-hexidecimal character: " << digest.c_str();
return nullptr;
}
return avb_verifier;
}
bool FsManagerAvbVerifier::VerifyVbmetaImages(const AvbSlotVerifyData& verify_data) {
if (verify_data.num_vbmeta_images == 0) {
LERROR << "No vbmeta images";
return false;
}
size_t total_size = 0;
bool digest_matched = false;
if (hash_alg_ == kSHA256) {
std::tie(total_size, digest_matched) =
verify_vbmeta_digest<SHA256Hasher>(verify_data, digest_);
} else if (hash_alg_ == kSHA512) {
std::tie(total_size, digest_matched) =
verify_vbmeta_digest<SHA512Hasher>(verify_data, digest_);
}
if (total_size != vbmeta_size_) {
LERROR << "total vbmeta size mismatch: " << total_size << " (expected: " << vbmeta_size_
<< ")";
return false;
}
if (!digest_matched) {
LERROR << "vbmeta digest mismatch";
return false;
}
return true;
}
static bool hashtree_load_verity_table(struct dm_ioctl* io, const std::string& dm_device_name,
int fd, const std::string& blk_device,
const AvbHashtreeDescriptor& hashtree_desc,
const std::string& salt, const std::string& root_digest) {
fs_mgr_verity_ioctl_init(io, dm_device_name, DM_STATUS_TABLE_FLAG);
// The buffer consists of [dm_ioctl][dm_target_spec][verity_params].
char* buffer = (char*)io;
// Builds the dm_target_spec arguments.
struct dm_target_spec* dm_target = (struct dm_target_spec*)&buffer[sizeof(struct dm_ioctl)];
io->target_count = 1;
dm_target->status = 0;
dm_target->sector_start = 0;
dm_target->length = hashtree_desc.image_size / 512;
strcpy(dm_target->target_type, "verity");
// Builds the verity params.
char* verity_params = buffer + sizeof(struct dm_ioctl) + sizeof(struct dm_target_spec);
size_t bufsize = DM_BUF_SIZE - (verity_params - buffer);
int res = 0;
if (hashtree_desc.fec_size > 0) {
res = snprintf(verity_params, bufsize, VERITY_TABLE_FORMAT VERITY_TABLE_OPT_FEC_FORMAT,
VERITY_TABLE_PARAMS(hashtree_desc, blk_device.c_str(), root_digest.c_str(),
salt.c_str()),
VERITY_TABLE_OPT_FEC_PARAMS(hashtree_desc, blk_device.c_str()));
} else {
res = snprintf(verity_params, bufsize, VERITY_TABLE_FORMAT VERITY_TABLE_OPT_DEFAULT_FORMAT,
VERITY_TABLE_PARAMS(hashtree_desc, blk_device.c_str(), root_digest.c_str(),
salt.c_str()),
VERITY_TABLE_OPT_DEFAULT_PARAMS);
}
if (res < 0 || (size_t)res >= bufsize) {
LERROR << "Error building verity table; insufficient buffer size?";
return false;
}
LINFO << "Loading verity table: '" << verity_params << "'";
// Sets ext target boundary.
verity_params += strlen(verity_params) + 1;
verity_params = (char*)(((unsigned long)verity_params + 7) & ~7);
dm_target->next = verity_params - buffer;
// Sends the ioctl to load the verity table.
if (ioctl(fd, DM_TABLE_LOAD, io)) {
PERROR << "Error loading verity table";
return false;
}
return true;
}
static bool hashtree_dm_verity_setup(struct fstab_rec* fstab_entry,
const AvbHashtreeDescriptor& hashtree_desc,
const std::string& salt, const std::string& root_digest,
bool wait_for_verity_dev) {
// Gets the device mapper fd.
android::base::unique_fd fd(open("/dev/device-mapper", O_RDWR));
if (fd < 0) {
PERROR << "Error opening device mapper";
return false;
}
// Creates the device.
alignas(dm_ioctl) char buffer[DM_BUF_SIZE];
struct dm_ioctl* io = (struct dm_ioctl*)buffer;
const std::string mount_point(basename(fstab_entry->mount_point));
if (!fs_mgr_create_verity_device(io, mount_point, fd)) {
LERROR << "Couldn't create verity device!";
return false;
}
// Gets the name of the device file.
std::string verity_blk_name;
if (!fs_mgr_get_verity_device_name(io, mount_point, fd, &verity_blk_name)) {
LERROR << "Couldn't get verity device number!";
return false;
}
// Loads the verity mapping table.
if (!hashtree_load_verity_table(io, mount_point, fd, std::string(fstab_entry->blk_device),
hashtree_desc, salt, root_digest)) {
LERROR << "Couldn't load verity table!";
return false;
}
// Activates the device.
if (!fs_mgr_resume_verity_table(io, mount_point, fd)) {
return false;
}
// Marks the underlying block device as read-only.
fs_mgr_set_blk_ro(fstab_entry->blk_device);
// Updates fstab_rec->blk_device to verity device name.
free(fstab_entry->blk_device);
fstab_entry->blk_device = strdup(verity_blk_name.c_str());
// Makes sure we've set everything up properly.
if (wait_for_verity_dev && fs_mgr_test_access(verity_blk_name.c_str()) < 0) {
return false;
}
return true;
}
static bool get_hashtree_descriptor(const std::string& partition_name,
const AvbSlotVerifyData& verify_data,
AvbHashtreeDescriptor* out_hashtree_desc, std::string* out_salt,
std::string* out_digest) {
bool found = false;
const uint8_t* desc_partition_name;
for (size_t i = 0; i < verify_data.num_vbmeta_images && !found; i++) {
// Get descriptors from vbmeta_images[i].
size_t num_descriptors;
std::unique_ptr<const AvbDescriptor* [], decltype(&avb_free)> descriptors(
avb_descriptor_get_all(verify_data.vbmeta_images[i].vbmeta_data,
verify_data.vbmeta_images[i].vbmeta_size, &num_descriptors),
avb_free);
if (!descriptors || num_descriptors < 1) {
continue;
}
// Ensures that hashtree descriptor is in /vbmeta or /boot or in
// the same partition for verity setup.
std::string vbmeta_partition_name(verify_data.vbmeta_images[i].partition_name);
if (vbmeta_partition_name != "vbmeta" &&
vbmeta_partition_name != "boot" && // for legacy device to append top-level vbmeta
vbmeta_partition_name != partition_name) {
LWARNING << "Skip vbmeta image at " << verify_data.vbmeta_images[i].partition_name
<< " for partition: " << partition_name.c_str();
continue;
}
for (size_t j = 0; j < num_descriptors && !found; j++) {
AvbDescriptor desc;
if (!avb_descriptor_validate_and_byteswap(descriptors[j], &desc)) {
LWARNING << "Descriptor[" << j << "] is invalid";
continue;
}
if (desc.tag == AVB_DESCRIPTOR_TAG_HASHTREE) {
desc_partition_name = (const uint8_t*)descriptors[j] + sizeof(AvbHashtreeDescriptor);
if (!avb_hashtree_descriptor_validate_and_byteswap(
(AvbHashtreeDescriptor*)descriptors[j], out_hashtree_desc)) {
continue;
}
if (out_hashtree_desc->partition_name_len != partition_name.length()) {
continue;
}
// Notes that desc_partition_name is not NUL-terminated.
std::string hashtree_partition_name((const char*)desc_partition_name,
out_hashtree_desc->partition_name_len);
if (hashtree_partition_name == partition_name) {
found = true;
}
}
}
}
if (!found) {
LERROR << "Partition descriptor not found: " << partition_name.c_str();
return false;
}
const uint8_t* desc_salt = desc_partition_name + out_hashtree_desc->partition_name_len;
*out_salt = bytes_to_hex(desc_salt, out_hashtree_desc->salt_len);
const uint8_t* desc_digest = desc_salt + out_hashtree_desc->salt_len;
*out_digest = bytes_to_hex(desc_digest, out_hashtree_desc->root_digest_len);
return true;
}
FsManagerAvbUniquePtr FsManagerAvbHandle::Open(const fstab& fstab) {
FsManagerAvbOps avb_ops(fstab);
return DoOpen(&avb_ops);
}
FsManagerAvbUniquePtr FsManagerAvbHandle::Open(ByNameSymlinkMap&& by_name_symlink_map) {
if (by_name_symlink_map.empty()) {
LERROR << "Empty by_name_symlink_map when opening FsManagerAvbHandle";
return nullptr;
}
FsManagerAvbOps avb_ops(std::move(by_name_symlink_map));
return DoOpen(&avb_ops);
}
FsManagerAvbUniquePtr FsManagerAvbHandle::DoOpen(FsManagerAvbOps* avb_ops) {
// Gets the expected hash value of vbmeta images from kernel cmdline.
std::unique_ptr<FsManagerAvbVerifier> avb_verifier = FsManagerAvbVerifier::Create();
if (!avb_verifier) {
LERROR << "Failed to create FsManagerAvbVerifier";
return nullptr;
}
FsManagerAvbUniquePtr avb_handle(new FsManagerAvbHandle());
if (!avb_handle) {
LERROR << "Failed to allocate FsManagerAvbHandle";
return nullptr;
}
AvbSlotVerifyResult verify_result = avb_ops->AvbSlotVerify(
fs_mgr_get_slot_suffix(), avb_verifier->IsDeviceUnlocked(), &avb_handle->avb_slot_data_);
// Only allow two verify results:
// - AVB_SLOT_VERIFY_RESULT_OK.
// - AVB_SLOT_VERIFY_RESULT_ERROR_VERIFICATION (for UNLOCKED state).
// If the device is UNLOCKED, i.e., |allow_verification_error| is true for
// AvbSlotVerify(), then the following return values are all non-fatal:
// * AVB_SLOT_VERIFY_RESULT_ERROR_VERIFICATION
// * AVB_SLOT_VERIFY_RESULT_ERROR_PUBLIC_KEY_REJECTED
// * AVB_SLOT_VERIFY_RESULT_ERROR_ROLLBACK_INDEX
// The latter two results were checked by bootloader prior to start fs_mgr so
// we just need to handle the first result here. See *dummy* operations in
// FsManagerAvbOps and the comments in external/avb/libavb/avb_slot_verify.h
// for more details.
switch (verify_result) {
case AVB_SLOT_VERIFY_RESULT_OK:
avb_handle->status_ = kFsManagerAvbHandleSuccess;
break;
case AVB_SLOT_VERIFY_RESULT_ERROR_VERIFICATION:
if (!avb_verifier->IsDeviceUnlocked()) {
LERROR << "ERROR_VERIFICATION isn't allowed when the device is LOCKED";
return nullptr;
}
avb_handle->status_ = kFsManagerAvbHandleErrorVerification;
break;
default:
LERROR << "avb_slot_verify failed, result: " << verify_result;
return nullptr;
}
// Verifies vbmeta images against the digest passed from bootloader.
if (!avb_verifier->VerifyVbmetaImages(*avb_handle->avb_slot_data_)) {
LERROR << "VerifyVbmetaImages failed";
return nullptr;
}
// Sets the MAJOR.MINOR for init to set it into "ro.boot.avb_version".
avb_handle->avb_version_ =
android::base::StringPrintf("%d.%d", AVB_VERSION_MAJOR, AVB_VERSION_MINOR);
// Checks whether FLAGS_HASHTREE_DISABLED is set.
AvbVBMetaImageHeader vbmeta_header;
avb_vbmeta_image_header_to_host_byte_order(
(AvbVBMetaImageHeader*)avb_handle->avb_slot_data_->vbmeta_images[0].vbmeta_data,
&vbmeta_header);
bool hashtree_disabled =
((AvbVBMetaImageFlags)vbmeta_header.flags & AVB_VBMETA_IMAGE_FLAGS_HASHTREE_DISABLED);
if (hashtree_disabled) {
avb_handle->status_ = kFsManagerAvbHandleHashtreeDisabled;
}
LINFO << "Returning avb_handle with status: " << avb_handle->status_;
return avb_handle;
}
bool FsManagerAvbHandle::SetUpAvb(struct fstab_rec* fstab_entry, bool wait_for_verity_dev) {
if (!fstab_entry) return false;
if (!avb_slot_data_ || avb_slot_data_->num_vbmeta_images < 1) {
return false;
}
if (status_ == kFsManagerAvbHandleUninitialized) return false;
if (status_ == kFsManagerAvbHandleHashtreeDisabled) {
LINFO << "AVB HASHTREE disabled on:" << fstab_entry->mount_point;
return true;
}
std::string partition_name(basename(fstab_entry->mount_point));
if (!avb_validate_utf8((const uint8_t*)partition_name.c_str(), partition_name.length())) {
LERROR << "Partition name: " << partition_name.c_str() << " is not valid UTF-8.";
return false;
}
AvbHashtreeDescriptor hashtree_descriptor;
std::string salt;
std::string root_digest;
if (!get_hashtree_descriptor(partition_name, *avb_slot_data_, &hashtree_descriptor, &salt,
&root_digest)) {
return false;
}
// Converts HASHTREE descriptor to verity_table_params.
if (!hashtree_dm_verity_setup(fstab_entry, hashtree_descriptor, salt, root_digest,
wait_for_verity_dev)) {
return false;
}
return true;
}