/* * 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "fs_mgr.h" #include "fs_mgr_priv.h" #include "fs_mgr_priv_avb_ops.h" #include "fs_mgr_priv_sha.h" 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 static std::pair 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.hash_alg // - androidboot.vbmeta.size // - androidboot.vbmeta.digest class FsManagerAvbVerifier { public: // The factory method to return a unique_ptr static std::unique_ptr Create(); bool VerifyVbmetaImages(const AvbSlotVerifyData& verify_data); 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_; }; std::unique_ptr FsManagerAvbVerifier::Create() { std::unique_ptr avb_verifier(new FsManagerAvbVerifier()); if (!avb_verifier) { LERROR << "Failed to create unique_ptr"; return nullptr; } std::string value; if (!fs_mgr_get_boot_config("vbmeta.size", &value) || !android::base::ParseUint(value.c_str(), &avb_verifier->vbmeta_size_)) { LERROR << "Invalid hash size: " << value.c_str(); return nullptr; } // Reads hash algorithm. size_t expected_digest_size = 0; std::string hash_alg; fs_mgr_get_boot_config("vbmeta.hash_alg", &hash_alg); 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. std::string digest; fs_mgr_get_boot_config("vbmeta.digest", &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(verify_data, digest_); } else if (hash_alg_ == kSHA512) { std::tie(total_size, digest_matched) = verify_vbmeta_digest(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; } // Constructs dm-verity arguments for sending DM_TABLE_LOAD ioctl to kernel. // See the following link for more details: // https://gitlab.com/cryptsetup/cryptsetup/wikis/DMVerity static bool construct_verity_table(const AvbHashtreeDescriptor& hashtree_desc, const std::string& salt, const std::string& root_digest, const std::string& blk_device, android::dm::DmTable* table) { // Loads androidboot.veritymode from kernel cmdline. std::string verity_mode; if (!fs_mgr_get_boot_config("veritymode", &verity_mode)) { verity_mode = "enforcing"; // Defaults to enforcing when it's absent. } // Converts veritymode to the format used in kernel. std::string dm_verity_mode; if (verity_mode == "enforcing") { dm_verity_mode = "restart_on_corruption"; } else if (verity_mode == "logging") { dm_verity_mode = "ignore_corruption"; } else if (verity_mode != "eio") { // Default dm_verity_mode is eio. LERROR << "Unknown androidboot.veritymode: " << verity_mode; return false; } std::ostringstream hash_algorithm; hash_algorithm << hashtree_desc.hash_algorithm; android::dm::DmTargetVerity target(0, hashtree_desc.image_size / 512, 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, hashtree_desc.tree_offset / hashtree_desc.hash_block_size, hash_algorithm.str(), root_digest, salt); if (hashtree_desc.fec_size > 0) { target.UseFec(blk_device, hashtree_desc.fec_num_roots, hashtree_desc.fec_offset / hashtree_desc.data_block_size, hashtree_desc.fec_offset / hashtree_desc.data_block_size); } if (!dm_verity_mode.empty()) { target.SetVerityMode(dm_verity_mode); } // Always use ignore_zero_blocks. target.IgnoreZeroBlocks(); LINFO << "Built verity table: '" << target.GetParameterString() << "'"; return table->AddTarget(std::make_unique(target)); } 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) { android::dm::DmTable table; if (!construct_verity_table(hashtree_desc, salt, root_digest, fstab_entry->blk_device, &table) || !table.valid()) { LERROR << "Failed to construct verity table."; return false; } table.set_readonly(true); const std::string mount_point(basename(fstab_entry->mount_point)); android::dm::DeviceMapper& dm = android::dm::DeviceMapper::Instance(); if (!dm.CreateDevice(mount_point, table)) { LERROR << "Couldn't create verity device!"; return false; } std::string dev_path; if (!dm.GetDmDevicePathByName(mount_point, &dev_path)) { LERROR << "Couldn't get verity device path!"; 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(dev_path.c_str()); // Makes sure we've set everything up properly. if (wait_for_verity_dev && !fs_mgr_wait_for_file(dev_path, 1s)) { 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 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) { bool is_device_unlocked = fs_mgr_is_device_unlocked(); FsManagerAvbUniquePtr avb_handle(new FsManagerAvbHandle()); if (!avb_handle) { LERROR << "Failed to allocate FsManagerAvbHandle"; return nullptr; } AvbSlotVerifyFlags flags = is_device_unlocked ? AVB_SLOT_VERIFY_FLAGS_ALLOW_VERIFICATION_ERROR : AVB_SLOT_VERIFY_FLAGS_NONE; AvbSlotVerifyResult verify_result = avb_ops->AvbSlotVerify(fs_mgr_get_slot_suffix(), flags, &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_ = kAvbHandleSuccess; break; case AVB_SLOT_VERIFY_RESULT_ERROR_VERIFICATION: if (!is_device_unlocked) { LERROR << "ERROR_VERIFICATION isn't allowed when the device is LOCKED"; return nullptr; } avb_handle->status_ = kAvbHandleVerificationError; break; default: LERROR << "avb_slot_verify failed, result: " << verify_result; 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_VERIFICATION_DISABLED is set: // - Only the top-level vbmeta struct is read. // - vbmeta struct in other partitions are NOT processed, including AVB HASH descriptor(s) // and AVB HASHTREE descriptor(s). 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 verification_disabled = ((AvbVBMetaImageFlags)vbmeta_header.flags & AVB_VBMETA_IMAGE_FLAGS_VERIFICATION_DISABLED); if (verification_disabled) { avb_handle->status_ = kAvbHandleVerificationDisabled; } else { // Verifies vbmeta structs against the digest passed from bootloader in kernel cmdline. std::unique_ptr avb_verifier = FsManagerAvbVerifier::Create(); if (!avb_verifier) { LERROR << "Failed to create FsManagerAvbVerifier"; return nullptr; } if (!avb_verifier->VerifyVbmetaImages(*avb_handle->avb_slot_data_)) { LERROR << "VerifyVbmetaImages failed"; return nullptr; } // Checks whether FLAGS_HASHTREE_DISABLED is set. bool hashtree_disabled = ((AvbVBMetaImageFlags)vbmeta_header.flags & AVB_VBMETA_IMAGE_FLAGS_HASHTREE_DISABLED); if (hashtree_disabled) { avb_handle->status_ = kAvbHandleHashtreeDisabled; } } LINFO << "Returning avb_handle with status: " << avb_handle->status_; return avb_handle; } SetUpAvbHashtreeResult FsManagerAvbHandle::SetUpAvbHashtree(struct fstab_rec* fstab_entry, bool wait_for_verity_dev) { if (!fstab_entry || status_ == kAvbHandleUninitialized || !avb_slot_data_ || avb_slot_data_->num_vbmeta_images < 1) { return SetUpAvbHashtreeResult::kFail; } if (status_ == kAvbHandleHashtreeDisabled || status_ == kAvbHandleVerificationDisabled) { LINFO << "AVB HASHTREE disabled on: " << fstab_entry->mount_point; return SetUpAvbHashtreeResult::kDisabled; } // Derives partition_name from blk_device to query the corresponding AVB HASHTREE descriptor // to setup dm-verity. The partition_names in AVB descriptors are without A/B suffix. std::string partition_name; if (fstab_entry->fs_mgr_flags & MF_LOGICAL) { partition_name = fstab_entry->logical_partition_name; } else { partition_name = basename(fstab_entry->blk_device); } if (fstab_entry->fs_mgr_flags & MF_SLOTSELECT) { auto ab_suffix = partition_name.rfind(fs_mgr_get_slot_suffix()); if (ab_suffix != std::string::npos) { partition_name.erase(ab_suffix); } } 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 SetUpAvbHashtreeResult::kFail; } // Converts HASHTREE descriptor to verity_table_params. if (!hashtree_dm_verity_setup(fstab_entry, hashtree_descriptor, salt, root_digest, wait_for_verity_dev)) { return SetUpAvbHashtreeResult::kFail; } return SetUpAvbHashtreeResult::kSuccess; }