install/verifier.cpp - android_bootable_recovery - Gitiles

 /*
  * Copyright (C) 2008 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 "install/verifier.h"

 #include <errno.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>

 #include <algorithm>
 #include <functional>
 #include <memory>
 #include <vector>

 #include <android-base/logging.h>
 #include <openssl/bio.h>
 #include <openssl/bn.h>
 #include <openssl/ecdsa.h>
 #include <openssl/evp.h>
 #include <openssl/obj_mac.h>
 #include <openssl/pem.h>
 #include <openssl/rsa.h>
 #include <ziparchive/zip_archive.h>

 #include "otautil/print_sha1.h"
 #include "private/asn1_decoder.h"

 /*
  * Simple version of PKCS#7 SignedData extraction. This extracts the
  * signature OCTET STRING to be used for signature verification.
  *
  * For full details, see http://www.ietf.org/rfc/rfc3852.txt
  *
  * The PKCS#7 structure looks like:
  *
  *   SEQUENCE (ContentInfo)
  *     OID (ContentType)
  *     [0] (content)
  *       SEQUENCE (SignedData)
  *         INTEGER (version CMSVersion)
  *         SET (DigestAlgorithmIdentifiers)
  *         SEQUENCE (EncapsulatedContentInfo)
  *         [0] (CertificateSet OPTIONAL)
  *         [1] (RevocationInfoChoices OPTIONAL)
  *         SET (SignerInfos)
  *           SEQUENCE (SignerInfo)
  *             INTEGER (CMSVersion)
  *             SEQUENCE (SignerIdentifier)
  *             SEQUENCE (DigestAlgorithmIdentifier)
  *             SEQUENCE (SignatureAlgorithmIdentifier)
  *             OCTET STRING (SignatureValue)
  */
 static bool read_pkcs7(const uint8_t* pkcs7_der, size_t pkcs7_der_len,
                        std::vector<uint8_t>* sig_der) {
   CHECK(sig_der != nullptr);
   sig_der->clear();

   asn1_context ctx(pkcs7_der, pkcs7_der_len);

   std::unique_ptr<asn1_context> pkcs7_seq(ctx.asn1_sequence_get());
   if (pkcs7_seq == nullptr || !pkcs7_seq->asn1_sequence_next()) {
     return false;
   }

   std::unique_ptr<asn1_context> signed_data_app(pkcs7_seq->asn1_constructed_get());
   if (signed_data_app == nullptr) {
     return false;
   }

   std::unique_ptr<asn1_context> signed_data_seq(signed_data_app->asn1_sequence_get());
   if (signed_data_seq == nullptr || !signed_data_seq->asn1_sequence_next() ||
       !signed_data_seq->asn1_sequence_next() || !signed_data_seq->asn1_sequence_next() ||
       !signed_data_seq->asn1_constructed_skip_all()) {
     return false;
   }

   std::unique_ptr<asn1_context> sig_set(signed_data_seq->asn1_set_get());
   if (sig_set == nullptr) {
     return false;
   }

   std::unique_ptr<asn1_context> sig_seq(sig_set->asn1_sequence_get());
   if (sig_seq == nullptr || !sig_seq->asn1_sequence_next() || !sig_seq->asn1_sequence_next() ||
       !sig_seq->asn1_sequence_next() || !sig_seq->asn1_sequence_next()) {
     return false;
   }

   const uint8_t* sig_der_ptr;
   size_t sig_der_length;
   if (!sig_seq->asn1_octet_string_get(&sig_der_ptr, &sig_der_length)) {
     return false;
   }

   sig_der->resize(sig_der_length);
   std::copy(sig_der_ptr, sig_der_ptr + sig_der_length, sig_der->begin());
   return true;
 }

 int verify_file(VerifierInterface* package, const std::vector<Certificate>& keys) {
   CHECK(package);
   package->SetProgress(0.0);

   // An archive with a whole-file signature will end in six bytes:
   //
   //   (2-byte signature start) $ff $ff (2-byte comment size)
   //
   // (As far as the ZIP format is concerned, these are part of the archive comment.) We start by
   // reading this footer, this tells us how far back from the end we have to start reading to find
   // the whole comment.

 #define FOOTER_SIZE 6
   uint64_t length = package->GetPackageSize();

   if (length < FOOTER_SIZE) {
     LOG(ERROR) << "not big enough to contain footer";
     return VERIFY_FAILURE;
   }

   uint8_t footer[FOOTER_SIZE];
   if (!package->ReadFullyAtOffset(footer, FOOTER_SIZE, length - FOOTER_SIZE)) {
     LOG(ERROR) << "Failed to read footer";
     return VERIFY_FAILURE;
   }

   if (footer[2] != 0xff || footer[3] != 0xff) {
     LOG(ERROR) << "footer is wrong";
     return VERIFY_FAILURE;
   }

   size_t comment_size = footer[4] + (footer[5] << 8);
   size_t signature_start = footer[0] + (footer[1] << 8);
   LOG(INFO) << "comment is " << comment_size << " bytes; signature is " << signature_start
             << " bytes from end";

   if (signature_start > comment_size) {
     LOG(ERROR) << "signature start: " << signature_start
                << " is larger than comment size: " << comment_size;
     return VERIFY_FAILURE;
   }

   if (signature_start <= FOOTER_SIZE) {
     LOG(ERROR) << "Signature start is in the footer";
     return VERIFY_FAILURE;
   }

 #define EOCD_HEADER_SIZE 22

   // The end-of-central-directory record is 22 bytes plus any comment length.
   size_t eocd_size = comment_size + EOCD_HEADER_SIZE;

   if (length < eocd_size) {
     LOG(ERROR) << "not big enough to contain EOCD";
     return VERIFY_FAILURE;
   }

   // Determine how much of the file is covered by the signature. This is everything except the
   // signature data and length, which includes all of the EOCD except for the comment length field
   // (2 bytes) and the comment data.
   uint64_t signed_len = length - eocd_size + EOCD_HEADER_SIZE - 2;

   uint8_t eocd[eocd_size];
   if (!package->ReadFullyAtOffset(eocd, eocd_size, length - eocd_size)) {
     LOG(ERROR) << "Failed to read EOCD of " << eocd_size << " bytes";
     return VERIFY_FAILURE;
   }

   // If this is really is the EOCD record, it will begin with the magic number $50 $4b $05 $06.
   if (eocd[0] != 0x50 || eocd[1] != 0x4b || eocd[2] != 0x05 || eocd[3] != 0x06) {
     LOG(ERROR) << "signature length doesn't match EOCD marker";
     return VERIFY_FAILURE;
   }

   for (size_t i = 4; i < eocd_size - 3; ++i) {
     if (eocd[i] == 0x50 && eocd[i + 1] == 0x4b && eocd[i + 2] == 0x05 && eocd[i + 3] == 0x06) {
       // If the sequence $50 $4b $05 $06 appears anywhere after the real one, libziparchive will
       // find the later (wrong) one, which could be exploitable. Fail the verification if this
       // sequence occurs anywhere after the real one.
       LOG(ERROR) << "EOCD marker occurs after start of EOCD";
       return VERIFY_FAILURE;
     }
   }

   bool need_sha1 = false;
   bool need_sha256 = false;
   for (const auto& key : keys) {
     switch (key.hash_len) {
       case SHA_DIGEST_LENGTH:
         need_sha1 = true;
         break;
       case SHA256_DIGEST_LENGTH:
         need_sha256 = true;
         break;
     }
   }

   SHA_CTX sha1_ctx;
   SHA256_CTX sha256_ctx;
   SHA1_Init(&sha1_ctx);
   SHA256_Init(&sha256_ctx);

   std::vector<HasherUpdateCallback> hashers;
   if (need_sha1) {
     hashers.emplace_back(
         std::bind(&SHA1_Update, &sha1_ctx, std::placeholders::_1, std::placeholders::_2));
   }
   if (need_sha256) {
     hashers.emplace_back(
         std::bind(&SHA256_Update, &sha256_ctx, std::placeholders::_1, std::placeholders::_2));
   }

   double frac = -1.0;
   uint64_t so_far = 0;
   while (so_far < signed_len) {
     // On a Nexus 5X, experiment showed 16MiB beat 1MiB by 6% faster for a 1196MiB full OTA and
     // 60% for an 89MiB incremental OTA. http://b/28135231.
     uint64_t read_size = std::min<uint64_t>(signed_len - so_far, 16 * MiB);
     package->UpdateHashAtOffset(hashers, so_far, read_size);
     so_far += read_size;

     double f = so_far / static_cast<double>(signed_len);
     if (f > frac + 0.02 || read_size == so_far) {
       package->SetProgress(f);
       frac = f;
     }
   }

   uint8_t sha1[SHA_DIGEST_LENGTH];
   SHA1_Final(sha1, &sha1_ctx);
   uint8_t sha256[SHA256_DIGEST_LENGTH];
   SHA256_Final(sha256, &sha256_ctx);

   const uint8_t* signature = eocd + eocd_size - signature_start;
   size_t signature_size = signature_start - FOOTER_SIZE;

   LOG(INFO) << "signature (offset: " << std::hex << (length - signature_start)
             << ", length: " << signature_size << "): " << print_hex(signature, signature_size);

   std::vector<uint8_t> sig_der;
   if (!read_pkcs7(signature, signature_size, &sig_der)) {
     LOG(ERROR) << "Could not find signature DER block";
     return VERIFY_FAILURE;
   }

   // Check to make sure at least one of the keys matches the signature. Since any key can match,
   // we need to try each before determining a verification failure has happened.
   size_t i = 0;
   for (const auto& key : keys) {
     const uint8_t* hash;
     int hash_nid;
     switch (key.hash_len) {
       case SHA_DIGEST_LENGTH:
         hash = sha1;
         hash_nid = NID_sha1;
         break;
       case SHA256_DIGEST_LENGTH:
         hash = sha256;
         hash_nid = NID_sha256;
         break;
       default:
         continue;
     }

     // The 6 bytes is the "(signature_start) $ff $ff (comment_size)" that the signing tool appends
     // after the signature itself.
     if (key.key_type == Certificate::KEY_TYPE_RSA) {
       if (!RSA_verify(hash_nid, hash, key.hash_len, sig_der.data(), sig_der.size(),
                       key.rsa.get())) {
         LOG(INFO) << "failed to verify against RSA key " << i;
         continue;
       }

       LOG(INFO) << "whole-file signature verified against RSA key " << i;
       return VERIFY_SUCCESS;
     } else if (key.key_type == Certificate::KEY_TYPE_EC && key.hash_len == SHA256_DIGEST_LENGTH) {
       if (!ECDSA_verify(0, hash, key.hash_len, sig_der.data(), sig_der.size(), key.ec.get())) {
         LOG(INFO) << "failed to verify against EC key " << i;
         continue;
       }

       LOG(INFO) << "whole-file signature verified against EC key " << i;
       return VERIFY_SUCCESS;
     } else {
       LOG(INFO) << "Unknown key type " << key.key_type;
     }
     i++;
   }

   if (need_sha1) {
     LOG(INFO) << "SHA-1 digest: " << print_hex(sha1, SHA_DIGEST_LENGTH);
   }
   if (need_sha256) {
     LOG(INFO) << "SHA-256 digest: " << print_hex(sha256, SHA256_DIGEST_LENGTH);
   }
   LOG(ERROR) << "failed to verify whole-file signature";
   return VERIFY_FAILURE;
 }

 static std::vector<Certificate> IterateZipEntriesAndSearchForKeys(const ZipArchiveHandle& handle) {
   void* cookie;
   int32_t iter_status = StartIteration(handle, &cookie, "", "x509.pem");
   if (iter_status != 0) {
     LOG(ERROR) << "Failed to iterate over entries in the certificate zipfile: "
                << ErrorCodeString(iter_status);
     return {};
   }

   std::vector<Certificate> result;

   std::string_view name;
   ZipEntry entry;
   while ((iter_status = Next(cookie, &entry, &name)) == 0) {
     std::vector<uint8_t> pem_content(entry.uncompressed_length);
     if (int32_t extract_status =
             ExtractToMemory(handle, &entry, pem_content.data(), pem_content.size());
         extract_status != 0) {
       LOG(ERROR) << "Failed to extract " << name;
       return {};
     }

     Certificate cert(0, Certificate::KEY_TYPE_RSA, nullptr, nullptr);
     // Aborts the parsing if we fail to load one of the key file.
     if (!LoadCertificateFromBuffer(pem_content, &cert)) {
       LOG(ERROR) << "Failed to load keys from " << name;
       return {};
     }

     result.emplace_back(std::move(cert));
   }

   if (iter_status != -1) {
     LOG(ERROR) << "Error while iterating over zip entries: " << ErrorCodeString(iter_status);
     return {};
   }

   return result;
 }

 std::vector<Certificate> LoadKeysFromZipfile(const std::string& zip_name) {
   ZipArchiveHandle handle;
   if (int32_t open_status = OpenArchive(zip_name.c_str(), &handle); open_status != 0) {
     LOG(ERROR) << "Failed to open " << zip_name << ": " << ErrorCodeString(open_status);
     return {};
   }

   std::vector<Certificate> result = IterateZipEntriesAndSearchForKeys(handle);
   CloseArchive(handle);
   return result;
 }

 bool CheckRSAKey(const std::unique_ptr<RSA, RSADeleter>& rsa) {
   if (!rsa) {
     return false;
   }

   const BIGNUM* out_n;
   const BIGNUM* out_e;
   RSA_get0_key(rsa.get(), &out_n, &out_e, nullptr /* private exponent */);
   auto modulus_bits = BN_num_bits(out_n);
   if (modulus_bits != 2048 && modulus_bits != 4096) {
     LOG(ERROR) << "Modulus should be 2048 or 4096 bits long, actual: " << modulus_bits;
     return false;
   }

   BN_ULONG exponent = BN_get_word(out_e);
   if (exponent != 3 && exponent != 65537) {
     LOG(ERROR) << "Public exponent should be 3 or 65537, actual: " << exponent;
     return false;
   }

   return true;
 }

 bool CheckECKey(const std::unique_ptr<EC_KEY, ECKEYDeleter>& ec_key) {
   if (!ec_key) {
     return false;
   }

   const EC_GROUP* ec_group = EC_KEY_get0_group(ec_key.get());
   if (!ec_group) {
     LOG(ERROR) << "Failed to get the ec_group from the ec_key";
     return false;
   }
   auto degree = EC_GROUP_get_degree(ec_group);
   if (degree != 256) {
     LOG(ERROR) << "Field size of the ec key should be 256 bits long, actual: " << degree;
     return false;
   }

   return true;
 }

 bool LoadCertificateFromBuffer(const std::vector<uint8_t>& pem_content, Certificate* cert) {
   std::unique_ptr<BIO, decltype(&BIO_free)> content(
       BIO_new_mem_buf(pem_content.data(), pem_content.size()), BIO_free);

   std::unique_ptr<X509, decltype(&X509_free)> x509(
       PEM_read_bio_X509(content.get(), nullptr, nullptr, nullptr), X509_free);
   if (!x509) {
     LOG(ERROR) << "Failed to read x509 certificate";
     return false;
   }

   int nid = X509_get_signature_nid(x509.get());
   switch (nid) {
     // SignApk has historically accepted md5WithRSA certificates, but treated them as
     // sha1WithRSA anyway. Continue to do so for backwards compatibility.
     case NID_md5WithRSA:
     case NID_md5WithRSAEncryption:
     case NID_sha1WithRSA:
     case NID_sha1WithRSAEncryption:
       cert->hash_len = SHA_DIGEST_LENGTH;
       break;
     case NID_sha256WithRSAEncryption:
     case NID_ecdsa_with_SHA256:
       cert->hash_len = SHA256_DIGEST_LENGTH;
       break;
     default:
       LOG(ERROR) << "Unrecognized signature nid " << OBJ_nid2ln(nid);
       return false;
   }

   std::unique_ptr<EVP_PKEY, decltype(&EVP_PKEY_free)> public_key(X509_get_pubkey(x509.get()),
                                                                  EVP_PKEY_free);
   if (!public_key) {
     LOG(ERROR) << "Failed to extract the public key from x509 certificate";
     return false;
   }

   int key_type = EVP_PKEY_id(public_key.get());
   if (key_type == EVP_PKEY_RSA) {
     cert->key_type = Certificate::KEY_TYPE_RSA;
     cert->ec.reset();
     cert->rsa.reset(EVP_PKEY_get1_RSA(public_key.get()));
     if (!cert->rsa || !CheckRSAKey(cert->rsa)) {
       LOG(ERROR) << "Failed to validate the rsa key info from public key";
       return false;
     }
   } else if (key_type == EVP_PKEY_EC) {
     cert->key_type = Certificate::KEY_TYPE_EC;
     cert->rsa.reset();
     cert->ec.reset(EVP_PKEY_get1_EC_KEY(public_key.get()));
     if (!cert->ec || !CheckECKey(cert->ec)) {
       LOG(ERROR) << "Failed to validate the ec key info from the public key";
       return false;
     }
   } else {
     LOG(ERROR) << "Unrecognized public key type " << OBJ_nid2ln(key_type);
     return false;
   }

   return true;
 }
	/*
	* Copyright (C) 2008 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 "install/verifier.h"

	#include <errno.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>

	#include <algorithm>
	#include <functional>
	#include <memory>
	#include <vector>

	#include <android-base/logging.h>
	#include <openssl/bio.h>
	#include <openssl/bn.h>
	#include <openssl/ecdsa.h>
	#include <openssl/evp.h>
	#include <openssl/obj_mac.h>
	#include <openssl/pem.h>
	#include <openssl/rsa.h>
	#include <ziparchive/zip_archive.h>

	#include "otautil/print_sha1.h"
	#include "private/asn1_decoder.h"

	/*
	* Simple version of PKCS#7 SignedData extraction. This extracts the
	* signature OCTET STRING to be used for signature verification.
	*
	* For full details, see http://www.ietf.org/rfc/rfc3852.txt
	*
	* The PKCS#7 structure looks like:
	*
	* SEQUENCE (ContentInfo)
	* OID (ContentType)
	* [0] (content)
	* SEQUENCE (SignedData)
	* INTEGER (version CMSVersion)
	* SET (DigestAlgorithmIdentifiers)
	* SEQUENCE (EncapsulatedContentInfo)
	* [0] (CertificateSet OPTIONAL)
	* [1] (RevocationInfoChoices OPTIONAL)
	* SET (SignerInfos)
	* SEQUENCE (SignerInfo)
	* INTEGER (CMSVersion)
	* SEQUENCE (SignerIdentifier)
	* SEQUENCE (DigestAlgorithmIdentifier)
	* SEQUENCE (SignatureAlgorithmIdentifier)
	* OCTET STRING (SignatureValue)
	*/
	static bool read_pkcs7(const uint8_t* pkcs7_der, size_t pkcs7_der_len,
	std::vector<uint8_t>* sig_der) {
	CHECK(sig_der != nullptr);
	sig_der->clear();

	asn1_context ctx(pkcs7_der, pkcs7_der_len);

	std::unique_ptr<asn1_context> pkcs7_seq(ctx.asn1_sequence_get());
	if (pkcs7_seq == nullptr \|\| !pkcs7_seq->asn1_sequence_next()) {
	return false;
	}

	std::unique_ptr<asn1_context> signed_data_app(pkcs7_seq->asn1_constructed_get());
	if (signed_data_app == nullptr) {
	return false;
	}

	std::unique_ptr<asn1_context> signed_data_seq(signed_data_app->asn1_sequence_get());
	if (signed_data_seq == nullptr \|\| !signed_data_seq->asn1_sequence_next() \|\|
	!signed_data_seq->asn1_sequence_next() \|\| !signed_data_seq->asn1_sequence_next() \|\|
	!signed_data_seq->asn1_constructed_skip_all()) {
	return false;
	}

	std::unique_ptr<asn1_context> sig_set(signed_data_seq->asn1_set_get());
	if (sig_set == nullptr) {
	return false;
	}

	std::unique_ptr<asn1_context> sig_seq(sig_set->asn1_sequence_get());
	if (sig_seq == nullptr \|\| !sig_seq->asn1_sequence_next() \|\| !sig_seq->asn1_sequence_next() \|\|
	!sig_seq->asn1_sequence_next() \|\| !sig_seq->asn1_sequence_next()) {
	return false;
	}

	const uint8_t* sig_der_ptr;
	size_t sig_der_length;
	if (!sig_seq->asn1_octet_string_get(&sig_der_ptr, &sig_der_length)) {
	return false;
	}

	sig_der->resize(sig_der_length);
	std::copy(sig_der_ptr, sig_der_ptr + sig_der_length, sig_der->begin());
	return true;
	}

	int verify_file(VerifierInterface* package, const std::vector<Certificate>& keys) {
	CHECK(package);
	package->SetProgress(0.0);

	// An archive with a whole-file signature will end in six bytes:
	//
	// (2-byte signature start) $ff $ff (2-byte comment size)
	//
	// (As far as the ZIP format is concerned, these are part of the archive comment.) We start by
	// reading this footer, this tells us how far back from the end we have to start reading to find
	// the whole comment.

	#define FOOTER_SIZE 6
	uint64_t length = package->GetPackageSize();

	if (length < FOOTER_SIZE) {
	LOG(ERROR) << "not big enough to contain footer";
	return VERIFY_FAILURE;
	}

	uint8_t footer[FOOTER_SIZE];
	if (!package->ReadFullyAtOffset(footer, FOOTER_SIZE, length - FOOTER_SIZE)) {
	LOG(ERROR) << "Failed to read footer";
	return VERIFY_FAILURE;
	}

	if (footer[2] != 0xff \|\| footer[3] != 0xff) {
	LOG(ERROR) << "footer is wrong";
	return VERIFY_FAILURE;
	}

	size_t comment_size = footer[4] + (footer[5] << 8);
	size_t signature_start = footer[0] + (footer[1] << 8);
	LOG(INFO) << "comment is " << comment_size << " bytes; signature is " << signature_start
	<< " bytes from end";

	if (signature_start > comment_size) {
	LOG(ERROR) << "signature start: " << signature_start
	<< " is larger than comment size: " << comment_size;
	return VERIFY_FAILURE;
	}

	if (signature_start <= FOOTER_SIZE) {
	LOG(ERROR) << "Signature start is in the footer";
	return VERIFY_FAILURE;
	}

	#define EOCD_HEADER_SIZE 22

	// The end-of-central-directory record is 22 bytes plus any comment length.
	size_t eocd_size = comment_size + EOCD_HEADER_SIZE;

	if (length < eocd_size) {
	LOG(ERROR) << "not big enough to contain EOCD";
	return VERIFY_FAILURE;
	}

	// Determine how much of the file is covered by the signature. This is everything except the
	// signature data and length, which includes all of the EOCD except for the comment length field
	// (2 bytes) and the comment data.
	uint64_t signed_len = length - eocd_size + EOCD_HEADER_SIZE - 2;

	uint8_t eocd[eocd_size];
	if (!package->ReadFullyAtOffset(eocd, eocd_size, length - eocd_size)) {
	LOG(ERROR) << "Failed to read EOCD of " << eocd_size << " bytes";
	return VERIFY_FAILURE;
	}

	// If this is really is the EOCD record, it will begin with the magic number $50 $4b $05 $06.
	if (eocd[0] != 0x50 \|\| eocd[1] != 0x4b \|\| eocd[2] != 0x05 \|\| eocd[3] != 0x06) {
	LOG(ERROR) << "signature length doesn't match EOCD marker";
	return VERIFY_FAILURE;
	}

	for (size_t i = 4; i < eocd_size - 3; ++i) {
	if (eocd[i] == 0x50 && eocd[i + 1] == 0x4b && eocd[i + 2] == 0x05 && eocd[i + 3] == 0x06) {
	// If the sequence $50 $4b $05 $06 appears anywhere after the real one, libziparchive will
	// find the later (wrong) one, which could be exploitable. Fail the verification if this
	// sequence occurs anywhere after the real one.
	LOG(ERROR) << "EOCD marker occurs after start of EOCD";
	return VERIFY_FAILURE;
	}
	}

	bool need_sha1 = false;
	bool need_sha256 = false;
	for (const auto& key : keys) {
	switch (key.hash_len) {
	case SHA_DIGEST_LENGTH:
	need_sha1 = true;
	break;
	case SHA256_DIGEST_LENGTH:
	need_sha256 = true;
	break;
	}
	}

	SHA_CTX sha1_ctx;
	SHA256_CTX sha256_ctx;
	SHA1_Init(&sha1_ctx);
	SHA256_Init(&sha256_ctx);

	std::vector<HasherUpdateCallback> hashers;
	if (need_sha1) {
	hashers.emplace_back(
	std::bind(&SHA1_Update, &sha1_ctx, std::placeholders::_1, std::placeholders::_2));
	}
	if (need_sha256) {
	hashers.emplace_back(
	std::bind(&SHA256_Update, &sha256_ctx, std::placeholders::_1, std::placeholders::_2));
	}

	double frac = -1.0;
	uint64_t so_far = 0;
	while (so_far < signed_len) {
	// On a Nexus 5X, experiment showed 16MiB beat 1MiB by 6% faster for a 1196MiB full OTA and
	// 60% for an 89MiB incremental OTA. http://b/28135231.
	uint64_t read_size = std::min<uint64_t>(signed_len - so_far, 16 * MiB);
	package->UpdateHashAtOffset(hashers, so_far, read_size);
	so_far += read_size;

	double f = so_far / static_cast<double>(signed_len);
	if (f > frac + 0.02 \|\| read_size == so_far) {
	package->SetProgress(f);
	frac = f;
	}
	}

	uint8_t sha1[SHA_DIGEST_LENGTH];
	SHA1_Final(sha1, &sha1_ctx);
	uint8_t sha256[SHA256_DIGEST_LENGTH];
	SHA256_Final(sha256, &sha256_ctx);

	const uint8_t* signature = eocd + eocd_size - signature_start;
	size_t signature_size = signature_start - FOOTER_SIZE;

	LOG(INFO) << "signature (offset: " << std::hex << (length - signature_start)
	<< ", length: " << signature_size << "): " << print_hex(signature, signature_size);

	std::vector<uint8_t> sig_der;
	if (!read_pkcs7(signature, signature_size, &sig_der)) {
	LOG(ERROR) << "Could not find signature DER block";
	return VERIFY_FAILURE;
	}

	// Check to make sure at least one of the keys matches the signature. Since any key can match,
	// we need to try each before determining a verification failure has happened.
	size_t i = 0;
	for (const auto& key : keys) {
	const uint8_t* hash;
	int hash_nid;
	switch (key.hash_len) {
	case SHA_DIGEST_LENGTH:
	hash = sha1;
	hash_nid = NID_sha1;
	break;
	case SHA256_DIGEST_LENGTH:
	hash = sha256;
	hash_nid = NID_sha256;
	break;
	default:
	continue;
	}

	// The 6 bytes is the "(signature_start) $ff $ff (comment_size)" that the signing tool appends
	// after the signature itself.
	if (key.key_type == Certificate::KEY_TYPE_RSA) {
	if (!RSA_verify(hash_nid, hash, key.hash_len, sig_der.data(), sig_der.size(),
	key.rsa.get())) {
	LOG(INFO) << "failed to verify against RSA key " << i;
	continue;
	}

	LOG(INFO) << "whole-file signature verified against RSA key " << i;
	return VERIFY_SUCCESS;
	} else if (key.key_type == Certificate::KEY_TYPE_EC && key.hash_len == SHA256_DIGEST_LENGTH) {
	if (!ECDSA_verify(0, hash, key.hash_len, sig_der.data(), sig_der.size(), key.ec.get())) {
	LOG(INFO) << "failed to verify against EC key " << i;
	continue;
	}

	LOG(INFO) << "whole-file signature verified against EC key " << i;
	return VERIFY_SUCCESS;
	} else {
	LOG(INFO) << "Unknown key type " << key.key_type;
	}
	i++;
	}

	if (need_sha1) {
	LOG(INFO) << "SHA-1 digest: " << print_hex(sha1, SHA_DIGEST_LENGTH);
	}
	if (need_sha256) {
	LOG(INFO) << "SHA-256 digest: " << print_hex(sha256, SHA256_DIGEST_LENGTH);
	}
	LOG(ERROR) << "failed to verify whole-file signature";
	return VERIFY_FAILURE;
	}

	static std::vector<Certificate> IterateZipEntriesAndSearchForKeys(const ZipArchiveHandle& handle) {
	void* cookie;
	int32_t iter_status = StartIteration(handle, &cookie, "", "x509.pem");
	if (iter_status != 0) {
	LOG(ERROR) << "Failed to iterate over entries in the certificate zipfile: "
	<< ErrorCodeString(iter_status);
	return {};
	}

	std::vector<Certificate> result;

	std::string_view name;
	ZipEntry entry;
	while ((iter_status = Next(cookie, &entry, &name)) == 0) {
	std::vector<uint8_t> pem_content(entry.uncompressed_length);
	if (int32_t extract_status =
	ExtractToMemory(handle, &entry, pem_content.data(), pem_content.size());
	extract_status != 0) {
	LOG(ERROR) << "Failed to extract " << name;
	return {};
	}

	Certificate cert(0, Certificate::KEY_TYPE_RSA, nullptr, nullptr);
	// Aborts the parsing if we fail to load one of the key file.
	if (!LoadCertificateFromBuffer(pem_content, &cert)) {
	LOG(ERROR) << "Failed to load keys from " << name;
	return {};
	}

	result.emplace_back(std::move(cert));
	}

	if (iter_status != -1) {
	LOG(ERROR) << "Error while iterating over zip entries: " << ErrorCodeString(iter_status);
	return {};
	}

	return result;
	}

	std::vector<Certificate> LoadKeysFromZipfile(const std::string& zip_name) {
	ZipArchiveHandle handle;
	if (int32_t open_status = OpenArchive(zip_name.c_str(), &handle); open_status != 0) {
	LOG(ERROR) << "Failed to open " << zip_name << ": " << ErrorCodeString(open_status);
	return {};
	}

	std::vector<Certificate> result = IterateZipEntriesAndSearchForKeys(handle);
	CloseArchive(handle);
	return result;
	}

	bool CheckRSAKey(const std::unique_ptr<RSA, RSADeleter>& rsa) {
	if (!rsa) {
	return false;
	}

	const BIGNUM* out_n;
	const BIGNUM* out_e;
	RSA_get0_key(rsa.get(), &out_n, &out_e, nullptr /* private exponent */);
	auto modulus_bits = BN_num_bits(out_n);
	if (modulus_bits != 2048 && modulus_bits != 4096) {
	LOG(ERROR) << "Modulus should be 2048 or 4096 bits long, actual: " << modulus_bits;
	return false;
	}

	BN_ULONG exponent = BN_get_word(out_e);
	if (exponent != 3 && exponent != 65537) {
	LOG(ERROR) << "Public exponent should be 3 or 65537, actual: " << exponent;
	return false;
	}

	return true;
	}

	bool CheckECKey(const std::unique_ptr<EC_KEY, ECKEYDeleter>& ec_key) {
	if (!ec_key) {
	return false;
	}

	const EC_GROUP* ec_group = EC_KEY_get0_group(ec_key.get());
	if (!ec_group) {
	LOG(ERROR) << "Failed to get the ec_group from the ec_key";
	return false;
	}
	auto degree = EC_GROUP_get_degree(ec_group);
	if (degree != 256) {
	LOG(ERROR) << "Field size of the ec key should be 256 bits long, actual: " << degree;
	return false;
	}

	return true;
	}

	bool LoadCertificateFromBuffer(const std::vector<uint8_t>& pem_content, Certificate* cert) {
	std::unique_ptr<BIO, decltype(&BIO_free)> content(
	BIO_new_mem_buf(pem_content.data(), pem_content.size()), BIO_free);

	std::unique_ptr<X509, decltype(&X509_free)> x509(
	PEM_read_bio_X509(content.get(), nullptr, nullptr, nullptr), X509_free);
	if (!x509) {
	LOG(ERROR) << "Failed to read x509 certificate";
	return false;
	}

	int nid = X509_get_signature_nid(x509.get());
	switch (nid) {
	// SignApk has historically accepted md5WithRSA certificates, but treated them as
	// sha1WithRSA anyway. Continue to do so for backwards compatibility.
	case NID_md5WithRSA:
	case NID_md5WithRSAEncryption:
	case NID_sha1WithRSA:
	case NID_sha1WithRSAEncryption:
	cert->hash_len = SHA_DIGEST_LENGTH;
	break;
	case NID_sha256WithRSAEncryption:
	case NID_ecdsa_with_SHA256:
	cert->hash_len = SHA256_DIGEST_LENGTH;
	break;
	default:
	LOG(ERROR) << "Unrecognized signature nid " << OBJ_nid2ln(nid);
	return false;
	}

	std::unique_ptr<EVP_PKEY, decltype(&EVP_PKEY_free)> public_key(X509_get_pubkey(x509.get()),
	EVP_PKEY_free);
	if (!public_key) {
	LOG(ERROR) << "Failed to extract the public key from x509 certificate";
	return false;
	}

	int key_type = EVP_PKEY_id(public_key.get());
	if (key_type == EVP_PKEY_RSA) {
	cert->key_type = Certificate::KEY_TYPE_RSA;
	cert->ec.reset();
	cert->rsa.reset(EVP_PKEY_get1_RSA(public_key.get()));
	if (!cert->rsa \|\| !CheckRSAKey(cert->rsa)) {
	LOG(ERROR) << "Failed to validate the rsa key info from public key";
	return false;
	}
	} else if (key_type == EVP_PKEY_EC) {
	cert->key_type = Certificate::KEY_TYPE_EC;
	cert->rsa.reset();
	cert->ec.reset(EVP_PKEY_get1_EC_KEY(public_key.get()));
	if (!cert->ec \|\| !CheckECKey(cert->ec)) {
	LOG(ERROR) << "Failed to validate the ec key info from the public key";
	return false;
	}
	} else {
	LOG(ERROR) << "Unrecognized public key type " << OBJ_nid2ln(key_type);
	return false;
	}

	return true;
	}