/*
* 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 <errno.h>
#include <malloc.h>
#include <stdio.h>
#include <string.h>
#include <algorithm>
#include <memory>
#include <openssl/ecdsa.h>
#include <openssl/obj_mac.h>
#include "asn1_decoder.h"
#include "common.h"
#include "print_sha1.h"
#include "ui.h"
#include "verifier.h"
//extern RecoveryUI* ui;
#define PUBLIC_KEYS_FILE "/res/keys"
static constexpr size_t MiB = 1024 * 1024;
/*
* 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(uint8_t* pkcs7_der, size_t pkcs7_der_len, uint8_t** sig_der,
size_t* sig_der_length) {
asn1_context_t* ctx = asn1_context_new(pkcs7_der, pkcs7_der_len);
if (ctx == NULL) {
return false;
}
asn1_context_t* pkcs7_seq = asn1_sequence_get(ctx);
if (pkcs7_seq != NULL && asn1_sequence_next(pkcs7_seq)) {
asn1_context_t *signed_data_app = asn1_constructed_get(pkcs7_seq);
if (signed_data_app != NULL) {
asn1_context_t* signed_data_seq = asn1_sequence_get(signed_data_app);
if (signed_data_seq != NULL
&& asn1_sequence_next(signed_data_seq)
&& asn1_sequence_next(signed_data_seq)
&& asn1_sequence_next(signed_data_seq)
&& asn1_constructed_skip_all(signed_data_seq)) {
asn1_context_t *sig_set = asn1_set_get(signed_data_seq);
if (sig_set != NULL) {
asn1_context_t* sig_seq = asn1_sequence_get(sig_set);
if (sig_seq != NULL
&& asn1_sequence_next(sig_seq)
&& asn1_sequence_next(sig_seq)
&& asn1_sequence_next(sig_seq)
&& asn1_sequence_next(sig_seq)) {
uint8_t* sig_der_ptr;
if (asn1_octet_string_get(sig_seq, &sig_der_ptr, sig_der_length)) {
*sig_der = (uint8_t*) malloc(*sig_der_length);
if (*sig_der != NULL) {
memcpy(*sig_der, sig_der_ptr, *sig_der_length);
}
}
asn1_context_free(sig_seq);
}
asn1_context_free(sig_set);
}
asn1_context_free(signed_data_seq);
}
asn1_context_free(signed_data_app);
}
asn1_context_free(pkcs7_seq);
}
asn1_context_free(ctx);
return *sig_der != NULL;
}
// Look for an RSA signature embedded in the .ZIP file comment given
// the path to the zip. Verify it matches one of the given public
// keys.
//
// Return VERIFY_SUCCESS, VERIFY_FAILURE (if any error is encountered
// or no key matches the signature).
int verify_file(unsigned char* addr, size_t length) {
//ui->SetProgress(0.0);
std::vector<Certificate> keys;
if (!load_keys(PUBLIC_KEYS_FILE, keys)) {
LOGE("Failed to load keys\n");
return INSTALL_CORRUPT;
}
LOGI("%d key(s) loaded from %s\n", keys.size(), PUBLIC_KEYS_FILE);
// 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
if (length < FOOTER_SIZE) {
LOGE("not big enough to contain footer\n");
return VERIFY_FAILURE;
}
unsigned char* footer = addr + length - FOOTER_SIZE;
if (footer[2] != 0xff || footer[3] != 0xff) {
LOGE("footer is wrong\n");
return VERIFY_FAILURE;
}
size_t comment_size = footer[4] + (footer[5] << 8);
size_t signature_start = footer[0] + (footer[1] << 8);
LOGI("comment is %zu bytes; signature %zu bytes from end\n",
comment_size, signature_start);
if (signature_start > comment_size) {
LOGE("signature start: %zu is larger than comment size: %zu\n", signature_start,
comment_size);
return VERIFY_FAILURE;
}
if (signature_start <= FOOTER_SIZE) {
LOGE("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) {
LOGE("not big enough to contain EOCD\n");
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.
size_t signed_len = length - eocd_size + EOCD_HEADER_SIZE - 2;
unsigned char* eocd = addr + length - eocd_size;
// 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) {
LOGE("signature length doesn't match EOCD marker\n");
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, minzip will find the later (wrong) one,
// which could be exploitable. Fail verification if
// this sequence occurs anywhere after the real one.
LOGE("EOCD marker occurs after start of EOCD\n");
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);
double frac = -1.0;
size_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.
size_t size = std::min(signed_len - so_far, 16 * MiB);
if (need_sha1) SHA1_Update(&sha1_ctx, addr + so_far, size);
if (need_sha256) SHA256_Update(&sha256_ctx, addr + so_far, size);
so_far += size;
double f = so_far / (double)signed_len;
if (f > frac + 0.02 || size == so_far) {
//ui->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);
uint8_t* sig_der = nullptr;
size_t sig_der_length = 0;
uint8_t* signature = eocd + eocd_size - signature_start;
size_t signature_size = signature_start - FOOTER_SIZE;
LOGI("signature (offset: 0x%zx, length: %zu): %s\n",
length - signature_start, signature_size,
print_hex(signature, signature_size).c_str());
if (!read_pkcs7(signature, signature_size, &sig_der, &sig_der_length)) {
LOGE("Could not find signature DER block\n");
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,
sig_der_length, key.rsa.get())) {
LOGI("failed to verify against RSA key %zu\n", i);
continue;
}
LOGI("whole-file signature verified against RSA key %zu\n", i);
free(sig_der);
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,
sig_der_length, key.ec.get())) {
LOGI("failed to verify against EC key %zu\n", i);
continue;
}
LOGI("whole-file signature verified against EC key %zu\n", i);
free(sig_der);
return VERIFY_SUCCESS;
} else {
LOGI("Unknown key type %d\n", key.key_type);
}
i++;
}
if (need_sha1) {
LOGI("SHA-1 digest: %s\n", print_hex(sha1, SHA_DIGEST_LENGTH).c_str());
}
if (need_sha256) {
LOGI("SHA-256 digest: %s\n", print_hex(sha256, SHA256_DIGEST_LENGTH).c_str());
}
free(sig_der);
LOGE("failed to verify whole-file signature\n");
return VERIFY_FAILURE;
}
std::unique_ptr<RSA, RSADeleter> parse_rsa_key(FILE* file, uint32_t exponent) {
// Read key length in words and n0inv. n0inv is a precomputed montgomery
// parameter derived from the modulus and can be used to speed up
// verification. n0inv is 32 bits wide here, assuming the verification logic
// uses 32 bit arithmetic. However, BoringSSL may use a word size of 64 bits
// internally, in which case we don't have a valid n0inv. Thus, we just
// ignore the montgomery parameters and have BoringSSL recompute them
// internally. If/When the speedup from using the montgomery parameters
// becomes relevant, we can add more sophisticated code here to obtain a
// 64-bit n0inv and initialize the montgomery parameters in the key object.
uint32_t key_len_words = 0;
uint32_t n0inv = 0;
if (fscanf(file, " %i , 0x%x", &key_len_words, &n0inv) != 2) {
return nullptr;
}
if (key_len_words > 8192 / 32) {
LOGE("key length (%d) too large\n", key_len_words);
return nullptr;
}
// Read the modulus.
std::unique_ptr<uint32_t[]> modulus(new uint32_t[key_len_words]);
if (fscanf(file, " , { %u", &modulus[0]) != 1) {
return nullptr;
}
for (uint32_t i = 1; i < key_len_words; ++i) {
if (fscanf(file, " , %u", &modulus[i]) != 1) {
return nullptr;
}
}
// Cconvert from little-endian array of little-endian words to big-endian
// byte array suitable as input for BN_bin2bn.
std::reverse((uint8_t*)modulus.get(),
(uint8_t*)(modulus.get() + key_len_words));
// The next sequence of values is the montgomery parameter R^2. Since we
// generally don't have a valid |n0inv|, we ignore this (see comment above).
uint32_t rr_value;
if (fscanf(file, " } , { %u", &rr_value) != 1) {
return nullptr;
}
for (uint32_t i = 1; i < key_len_words; ++i) {
if (fscanf(file, " , %u", &rr_value) != 1) {
return nullptr;
}
}
if (fscanf(file, " } } ") != 0) {
return nullptr;
}
// Initialize the key.
std::unique_ptr<RSA, RSADeleter> key(RSA_new());
if (!key) {
return nullptr;
}
key->n = BN_bin2bn((uint8_t*)modulus.get(),
key_len_words * sizeof(uint32_t), NULL);
if (!key->n) {
return nullptr;
}
key->e = BN_new();
if (!key->e || !BN_set_word(key->e, exponent)) {
return nullptr;
}
return key;
}
struct BNDeleter {
void operator()(BIGNUM* bn) {
BN_free(bn);
}
};
std::unique_ptr<EC_KEY, ECKEYDeleter> parse_ec_key(FILE* file) {
uint32_t key_len_bytes = 0;
if (fscanf(file, " %i", &key_len_bytes) != 1) {
return nullptr;
}
std::unique_ptr<EC_GROUP, void (*)(EC_GROUP*)> group(
EC_GROUP_new_by_curve_name(NID_X9_62_prime256v1), EC_GROUP_free);
if (!group) {
return nullptr;
}
// Verify that |key_len| matches the group order.
if (key_len_bytes != BN_num_bytes(EC_GROUP_get0_order(group.get()))) {
return nullptr;
}
// Read the public key coordinates. Note that the byte order in the file is
// little-endian, so we convert to big-endian here.
std::unique_ptr<uint8_t[]> bytes(new uint8_t[key_len_bytes]);
std::unique_ptr<BIGNUM, BNDeleter> point[2];
for (int i = 0; i < 2; ++i) {
unsigned int byte = 0;
if (fscanf(file, " , { %u", &byte) != 1) {
return nullptr;
}
bytes[key_len_bytes - 1] = byte;
for (size_t i = 1; i < key_len_bytes; ++i) {
if (fscanf(file, " , %u", &byte) != 1) {
return nullptr;
}
bytes[key_len_bytes - i - 1] = byte;
}
point[i].reset(BN_bin2bn(bytes.get(), key_len_bytes, nullptr));
if (!point[i]) {
return nullptr;
}
if (fscanf(file, " }") != 0) {
return nullptr;
}
}
if (fscanf(file, " } ") != 0) {
return nullptr;
}
// Create and initialize the key.
std::unique_ptr<EC_KEY, ECKEYDeleter> key(EC_KEY_new());
if (!key || !EC_KEY_set_group(key.get(), group.get()) ||
!EC_KEY_set_public_key_affine_coordinates(key.get(), point[0].get(),
point[1].get())) {
return nullptr;
}
return key;
}
// Reads a file containing one or more public keys as produced by
// DumpPublicKey: this is an RSAPublicKey struct as it would appear
// as a C source literal, eg:
//
// "{64,0xc926ad21,{1795090719,...,-695002876},{-857949815,...,1175080310}}"
//
// For key versions newer than the original 2048-bit e=3 keys
// supported by Android, the string is preceded by a version
// identifier, eg:
//
// "v2 {64,0xc926ad21,{1795090719,...,-695002876},{-857949815,...,1175080310}}"
//
// (Note that the braces and commas in this example are actual
// characters the parser expects to find in the file; the ellipses
// indicate more numbers omitted from this example.)
//
// The file may contain multiple keys in this format, separated by
// commas. The last key must not be followed by a comma.
//
// A Certificate is a pair of an RSAPublicKey and a particular hash
// (we support SHA-1 and SHA-256; we store the hash length to signify
// which is being used). The hash used is implied by the version number.
//
// 1: 2048-bit RSA key with e=3 and SHA-1 hash
// 2: 2048-bit RSA key with e=65537 and SHA-1 hash
// 3: 2048-bit RSA key with e=3 and SHA-256 hash
// 4: 2048-bit RSA key with e=65537 and SHA-256 hash
// 5: 256-bit EC key using the NIST P-256 curve parameters and SHA-256 hash
//
// Returns true on success, and appends the found keys (at least one) to certs.
// Otherwise returns false if the file failed to parse, or if it contains zero
// keys. The contents in certs would be unspecified on failure.
bool load_keys(const char* filename, std::vector<Certificate>& certs) {
std::unique_ptr<FILE, decltype(&fclose)> f(fopen(filename, "r"), fclose);
if (!f) {
LOGE("opening %s: %s\n", filename, strerror(errno));
return false;
}
while (true) {
certs.emplace_back(0, Certificate::KEY_TYPE_RSA, nullptr, nullptr);
Certificate& cert = certs.back();
uint32_t exponent = 0;
char start_char;
if (fscanf(f.get(), " %c", &start_char) != 1) return false;
if (start_char == '{') {
// a version 1 key has no version specifier.
cert.key_type = Certificate::KEY_TYPE_RSA;
exponent = 3;
cert.hash_len = SHA_DIGEST_LENGTH;
} else if (start_char == 'v') {
int version;
if (fscanf(f.get(), "%d {", &version) != 1) return false;
switch (version) {
case 2:
cert.key_type = Certificate::KEY_TYPE_RSA;
exponent = 65537;
cert.hash_len = SHA_DIGEST_LENGTH;
break;
case 3:
cert.key_type = Certificate::KEY_TYPE_RSA;
exponent = 3;
cert.hash_len = SHA256_DIGEST_LENGTH;
break;
case 4:
cert.key_type = Certificate::KEY_TYPE_RSA;
exponent = 65537;
cert.hash_len = SHA256_DIGEST_LENGTH;
break;
case 5:
cert.key_type = Certificate::KEY_TYPE_EC;
cert.hash_len = SHA256_DIGEST_LENGTH;
break;
default:
return false;
}
}
if (cert.key_type == Certificate::KEY_TYPE_RSA) {
cert.rsa = parse_rsa_key(f.get(), exponent);
if (!cert.rsa) {
return false;
}
LOGI("read key e=%d hash=%d\n", exponent, cert.hash_len);
} else if (cert.key_type == Certificate::KEY_TYPE_EC) {
cert.ec = parse_ec_key(f.get());
if (!cert.ec) {
return false;
}
} else {
LOGE("Unknown key type %d\n", cert.key_type);
return false;
}
// if the line ends in a comma, this file has more keys.
int ch = fgetc(f.get());
if (ch == ',') {
// more keys to come.
continue;
} else if (ch == EOF) {
break;
} else {
LOGE("unexpected character between keys\n");
return false;
}
}
return true;
}