1 /* 2 * Copyright (C) 2009 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 #include <stdio.h> 18 #include <stdint.h> 19 #include <string.h> 20 #include <unistd.h> 21 #include <signal.h> 22 #include <errno.h> 23 #include <dirent.h> 24 #include <fcntl.h> 25 #include <limits.h> 26 #include <sys/types.h> 27 #include <sys/socket.h> 28 #include <sys/stat.h> 29 #include <sys/time.h> 30 #include <arpa/inet.h> 31 32 #include <openssl/aes.h> 33 #include <openssl/evp.h> 34 #include <openssl/md5.h> 35 36 #define LOG_TAG "keystore" 37 #include <cutils/log.h> 38 #include <cutils/sockets.h> 39 #include <private/android_filesystem_config.h> 40 41 #include "keystore.h" 42 43 /* KeyStore is a secured storage for key-value pairs. In this implementation, 44 * each file stores one key-value pair. Keys are encoded in file names, and 45 * values are encrypted with checksums. The encryption key is protected by a 46 * user-defined password. To keep things simple, buffers are always larger than 47 * the maximum space we needed, so boundary checks on buffers are omitted. */ 48 49 #define KEY_SIZE ((NAME_MAX - 15) / 2) 50 #define VALUE_SIZE 32768 51 #define PASSWORD_SIZE VALUE_SIZE 52 53 struct Value { 54 int length; 55 uint8_t value[VALUE_SIZE]; 56 }; 57 58 /* Here is the encoding of keys. This is necessary in order to allow arbitrary 59 * characters in keys. Characters in [0-~] are not encoded. Others are encoded 60 * into two bytes. The first byte is one of [+-.] which represents the first 61 * two bits of the character. The second byte encodes the rest of the bits into 62 * [0-o]. Therefore in the worst case the length of a key gets doubled. Note 63 * that Base64 cannot be used here due to the need of prefix match on keys. */ 64 65 static int encode_key(char* out, uid_t uid, const Value* key) { 66 int n = snprintf(out, NAME_MAX, "%u_", uid); 67 out += n; 68 const uint8_t* in = key->value; 69 int length = key->length; 70 for (int i = length; i > 0; --i, ++in, ++out) { 71 if (*in >= '0' && *in <= '~') { 72 *out = *in; 73 } else { 74 *out = '+' + (*in >> 6); 75 *++out = '0' + (*in & 0x3F); 76 ++length; 77 } 78 } 79 *out = '\0'; 80 return n + length; 81 } 82 83 static int decode_key(uint8_t* out, char* in, int length) { 84 for (int i = 0; i < length; ++i, ++in, ++out) { 85 if (*in >= '0' && *in <= '~') { 86 *out = *in; 87 } else { 88 *out = (*in - '+') << 6; 89 *out |= (*++in - '0') & 0x3F; 90 --length; 91 } 92 } 93 *out = '\0'; 94 return length; 95 } 96 97 static size_t readFully(int fd, uint8_t* data, size_t size) { 98 size_t remaining = size; 99 while (remaining > 0) { 100 ssize_t n = TEMP_FAILURE_RETRY(read(fd, data, size)); 101 if (n == -1 || n == 0) { 102 return size-remaining; 103 } 104 data += n; 105 remaining -= n; 106 } 107 return size; 108 } 109 110 static size_t writeFully(int fd, uint8_t* data, size_t size) { 111 size_t remaining = size; 112 while (remaining > 0) { 113 ssize_t n = TEMP_FAILURE_RETRY(write(fd, data, size)); 114 if (n == -1 || n == 0) { 115 return size-remaining; 116 } 117 data += n; 118 remaining -= n; 119 } 120 return size; 121 } 122 123 class Entropy { 124 public: 125 Entropy() : mRandom(-1) {} 126 ~Entropy() { 127 if (mRandom != -1) { 128 close(mRandom); 129 } 130 } 131 132 bool open() { 133 const char* randomDevice = "/dev/urandom"; 134 mRandom = ::open(randomDevice, O_RDONLY); 135 if (mRandom == -1) { 136 LOGE("open: %s: %s", randomDevice, strerror(errno)); 137 return false; 138 } 139 return true; 140 } 141 142 bool generate_random_data(uint8_t* data, size_t size) { 143 return (readFully(mRandom, data, size) == size); 144 } 145 146 private: 147 int mRandom; 148 }; 149 150 /* Here is the file format. There are two parts in blob.value, the secret and 151 * the description. The secret is stored in ciphertext, and its original size 152 * can be found in blob.length. The description is stored after the secret in 153 * plaintext, and its size is specified in blob.info. The total size of the two 154 * parts must be no more than VALUE_SIZE bytes. The first three bytes of the 155 * file are reserved for future use and are always set to zero. Fields other 156 * than blob.info, blob.length, and blob.value are modified by encryptBlob() 157 * and decryptBlob(). Thus they should not be accessed from outside. */ 158 159 struct __attribute__((packed)) blob { 160 uint8_t reserved[3]; 161 uint8_t info; 162 uint8_t vector[AES_BLOCK_SIZE]; 163 uint8_t encrypted[0]; 164 uint8_t digest[MD5_DIGEST_LENGTH]; 165 uint8_t digested[0]; 166 int32_t length; // in network byte order when encrypted 167 uint8_t value[VALUE_SIZE + AES_BLOCK_SIZE]; 168 }; 169 170 class Blob { 171 public: 172 Blob(uint8_t* value, int32_t valueLength, uint8_t* info, uint8_t infoLength) { 173 mBlob.length = valueLength; 174 memcpy(mBlob.value, value, valueLength); 175 176 mBlob.info = infoLength; 177 memcpy(mBlob.value + valueLength, info, infoLength); 178 } 179 180 Blob(blob b) { 181 mBlob = b; 182 } 183 184 Blob() {} 185 186 uint8_t* getValue() { 187 return mBlob.value; 188 } 189 190 int32_t getLength() { 191 return mBlob.length; 192 } 193 194 uint8_t getInfo() { 195 return mBlob.info; 196 } 197 198 ResponseCode encryptBlob(const char* filename, AES_KEY *aes_key, Entropy* entropy) { 199 if (!entropy->generate_random_data(mBlob.vector, AES_BLOCK_SIZE)) { 200 return SYSTEM_ERROR; 201 } 202 203 // data includes the value and the value's length 204 size_t dataLength = mBlob.length + sizeof(mBlob.length); 205 // pad data to the AES_BLOCK_SIZE 206 size_t digestedLength = ((dataLength + AES_BLOCK_SIZE - 1) 207 / AES_BLOCK_SIZE * AES_BLOCK_SIZE); 208 // encrypted data includes the digest value 209 size_t encryptedLength = digestedLength + MD5_DIGEST_LENGTH; 210 // move info after space for padding 211 memmove(&mBlob.encrypted[encryptedLength], &mBlob.value[mBlob.length], mBlob.info); 212 // zero padding area 213 memset(mBlob.value + mBlob.length, 0, digestedLength - dataLength); 214 215 mBlob.length = htonl(mBlob.length); 216 MD5(mBlob.digested, digestedLength, mBlob.digest); 217 218 uint8_t vector[AES_BLOCK_SIZE]; 219 memcpy(vector, mBlob.vector, AES_BLOCK_SIZE); 220 AES_cbc_encrypt(mBlob.encrypted, mBlob.encrypted, encryptedLength, 221 aes_key, vector, AES_ENCRYPT); 222 223 memset(mBlob.reserved, 0, sizeof(mBlob.reserved)); 224 size_t headerLength = (mBlob.encrypted - (uint8_t*) &mBlob); 225 size_t fileLength = encryptedLength + headerLength + mBlob.info; 226 227 const char* tmpFileName = ".tmp"; 228 int out = open(tmpFileName, O_WRONLY | O_TRUNC | O_CREAT, S_IRUSR | S_IWUSR); 229 if (out == -1) { 230 return SYSTEM_ERROR; 231 } 232 size_t writtenBytes = writeFully(out, (uint8_t*) &mBlob, fileLength); 233 if (close(out) != 0) { 234 return SYSTEM_ERROR; 235 } 236 if (writtenBytes != fileLength) { 237 unlink(tmpFileName); 238 return SYSTEM_ERROR; 239 } 240 return (rename(tmpFileName, filename) == 0) ? NO_ERROR : SYSTEM_ERROR; 241 } 242 243 ResponseCode decryptBlob(const char* filename, AES_KEY *aes_key) { 244 int in = open(filename, O_RDONLY); 245 if (in == -1) { 246 return (errno == ENOENT) ? KEY_NOT_FOUND : SYSTEM_ERROR; 247 } 248 // fileLength may be less than sizeof(mBlob) since the in 249 // memory version has extra padding to tolerate rounding up to 250 // the AES_BLOCK_SIZE 251 size_t fileLength = readFully(in, (uint8_t*) &mBlob, sizeof(mBlob)); 252 if (close(in) != 0) { 253 return SYSTEM_ERROR; 254 } 255 size_t headerLength = (mBlob.encrypted - (uint8_t*) &mBlob); 256 if (fileLength < headerLength) { 257 return VALUE_CORRUPTED; 258 } 259 260 ssize_t encryptedLength = fileLength - (headerLength + mBlob.info); 261 if (encryptedLength < 0 || encryptedLength % AES_BLOCK_SIZE != 0) { 262 return VALUE_CORRUPTED; 263 } 264 AES_cbc_encrypt(mBlob.encrypted, mBlob.encrypted, encryptedLength, aes_key, 265 mBlob.vector, AES_DECRYPT); 266 size_t digestedLength = encryptedLength - MD5_DIGEST_LENGTH; 267 uint8_t computedDigest[MD5_DIGEST_LENGTH]; 268 MD5(mBlob.digested, digestedLength, computedDigest); 269 if (memcmp(mBlob.digest, computedDigest, MD5_DIGEST_LENGTH) != 0) { 270 return VALUE_CORRUPTED; 271 } 272 273 ssize_t maxValueLength = digestedLength - sizeof(mBlob.length); 274 mBlob.length = ntohl(mBlob.length); 275 if (mBlob.length < 0 || mBlob.length > maxValueLength) { 276 return VALUE_CORRUPTED; 277 } 278 if (mBlob.info != 0) { 279 // move info from after padding to after data 280 memmove(&mBlob.value[mBlob.length], &mBlob.value[maxValueLength], mBlob.info); 281 } 282 return NO_ERROR; 283 } 284 285 private: 286 struct blob mBlob; 287 }; 288 289 class KeyStore { 290 public: 291 KeyStore(Entropy* entropy) : mEntropy(entropy), mRetry(MAX_RETRY) { 292 if (access(MASTER_KEY_FILE, R_OK) == 0) { 293 setState(STATE_LOCKED); 294 } else { 295 setState(STATE_UNINITIALIZED); 296 } 297 } 298 299 State getState() { 300 return mState; 301 } 302 303 int8_t getRetry() { 304 return mRetry; 305 } 306 307 ResponseCode initialize(Value* pw) { 308 if (!generateMasterKey()) { 309 return SYSTEM_ERROR; 310 } 311 ResponseCode response = writeMasterKey(pw); 312 if (response != NO_ERROR) { 313 return response; 314 } 315 setupMasterKeys(); 316 return NO_ERROR; 317 } 318 319 ResponseCode writeMasterKey(Value* pw) { 320 uint8_t passwordKey[MASTER_KEY_SIZE_BYTES]; 321 generateKeyFromPassword(passwordKey, MASTER_KEY_SIZE_BYTES, pw, mSalt); 322 AES_KEY passwordAesKey; 323 AES_set_encrypt_key(passwordKey, MASTER_KEY_SIZE_BITS, &passwordAesKey); 324 Blob masterKeyBlob(mMasterKey, sizeof(mMasterKey), mSalt, sizeof(mSalt)); 325 return masterKeyBlob.encryptBlob(MASTER_KEY_FILE, &passwordAesKey, mEntropy); 326 } 327 328 ResponseCode readMasterKey(Value* pw) { 329 int in = open(MASTER_KEY_FILE, O_RDONLY); 330 if (in == -1) { 331 return SYSTEM_ERROR; 332 } 333 334 // we read the raw blob to just to get the salt to generate 335 // the AES key, then we create the Blob to use with decryptBlob 336 blob rawBlob; 337 size_t length = readFully(in, (uint8_t*) &rawBlob, sizeof(rawBlob)); 338 if (close(in) != 0) { 339 return SYSTEM_ERROR; 340 } 341 // find salt at EOF if present, otherwise we have an old file 342 uint8_t* salt; 343 if (length > SALT_SIZE && rawBlob.info == SALT_SIZE) { 344 salt = (uint8_t*) &rawBlob + length - SALT_SIZE; 345 } else { 346 salt = NULL; 347 } 348 uint8_t passwordKey[MASTER_KEY_SIZE_BYTES]; 349 generateKeyFromPassword(passwordKey, MASTER_KEY_SIZE_BYTES, pw, salt); 350 AES_KEY passwordAesKey; 351 AES_set_decrypt_key(passwordKey, MASTER_KEY_SIZE_BITS, &passwordAesKey); 352 Blob masterKeyBlob(rawBlob); 353 ResponseCode response = masterKeyBlob.decryptBlob(MASTER_KEY_FILE, &passwordAesKey); 354 if (response == SYSTEM_ERROR) { 355 return SYSTEM_ERROR; 356 } 357 if (response == NO_ERROR && masterKeyBlob.getLength() == MASTER_KEY_SIZE_BYTES) { 358 // if salt was missing, generate one and write a new master key file with the salt. 359 if (salt == NULL) { 360 if (!generateSalt()) { 361 return SYSTEM_ERROR; 362 } 363 response = writeMasterKey(pw); 364 } 365 if (response == NO_ERROR) { 366 memcpy(mMasterKey, masterKeyBlob.getValue(), MASTER_KEY_SIZE_BYTES); 367 setupMasterKeys(); 368 } 369 return response; 370 } 371 if (mRetry <= 0) { 372 reset(); 373 return UNINITIALIZED; 374 } 375 --mRetry; 376 switch (mRetry) { 377 case 0: return WRONG_PASSWORD_0; 378 case 1: return WRONG_PASSWORD_1; 379 case 2: return WRONG_PASSWORD_2; 380 case 3: return WRONG_PASSWORD_3; 381 default: return WRONG_PASSWORD_3; 382 } 383 } 384 385 bool reset() { 386 clearMasterKeys(); 387 setState(STATE_UNINITIALIZED); 388 389 DIR* dir = opendir("."); 390 struct dirent* file; 391 392 if (!dir) { 393 return false; 394 } 395 while ((file = readdir(dir)) != NULL) { 396 unlink(file->d_name); 397 } 398 closedir(dir); 399 return true; 400 } 401 402 bool isEmpty() { 403 DIR* dir = opendir("."); 404 struct dirent* file; 405 if (!dir) { 406 return true; 407 } 408 bool result = true; 409 while ((file = readdir(dir)) != NULL) { 410 if (isKeyFile(file->d_name)) { 411 result = false; 412 break; 413 } 414 } 415 closedir(dir); 416 return result; 417 } 418 419 void lock() { 420 clearMasterKeys(); 421 setState(STATE_LOCKED); 422 } 423 424 ResponseCode get(const char* filename, Blob* keyBlob) { 425 return keyBlob->decryptBlob(filename, &mMasterKeyDecryption); 426 } 427 428 ResponseCode put(const char* filename, Blob* keyBlob) { 429 return keyBlob->encryptBlob(filename, &mMasterKeyEncryption, mEntropy); 430 } 431 432 private: 433 static const char* MASTER_KEY_FILE; 434 static const int MASTER_KEY_SIZE_BYTES = 16; 435 static const int MASTER_KEY_SIZE_BITS = MASTER_KEY_SIZE_BYTES * 8; 436 437 static const int MAX_RETRY = 4; 438 static const size_t SALT_SIZE = 16; 439 440 Entropy* mEntropy; 441 442 State mState; 443 int8_t mRetry; 444 445 uint8_t mMasterKey[MASTER_KEY_SIZE_BYTES]; 446 uint8_t mSalt[SALT_SIZE]; 447 448 AES_KEY mMasterKeyEncryption; 449 AES_KEY mMasterKeyDecryption; 450 451 void setState(State state) { 452 mState = state; 453 if (mState == STATE_NO_ERROR || mState == STATE_UNINITIALIZED) { 454 mRetry = MAX_RETRY; 455 } 456 } 457 458 bool generateSalt() { 459 return mEntropy->generate_random_data(mSalt, sizeof(mSalt)); 460 } 461 462 bool generateMasterKey() { 463 if (!mEntropy->generate_random_data(mMasterKey, sizeof(mMasterKey))) { 464 return false; 465 } 466 if (!generateSalt()) { 467 return false; 468 } 469 return true; 470 } 471 472 void setupMasterKeys() { 473 AES_set_encrypt_key(mMasterKey, MASTER_KEY_SIZE_BITS, &mMasterKeyEncryption); 474 AES_set_decrypt_key(mMasterKey, MASTER_KEY_SIZE_BITS, &mMasterKeyDecryption); 475 setState(STATE_NO_ERROR); 476 } 477 478 void clearMasterKeys() { 479 memset(mMasterKey, 0, sizeof(mMasterKey)); 480 memset(mSalt, 0, sizeof(mSalt)); 481 memset(&mMasterKeyEncryption, 0, sizeof(mMasterKeyEncryption)); 482 memset(&mMasterKeyDecryption, 0, sizeof(mMasterKeyDecryption)); 483 } 484 485 static void generateKeyFromPassword(uint8_t* key, ssize_t keySize, Value* pw, uint8_t* salt) { 486 size_t saltSize; 487 if (salt != NULL) { 488 saltSize = SALT_SIZE; 489 } else { 490 // pre-gingerbread used this hardwired salt, readMasterKey will rewrite these when found 491 salt = (uint8_t*) "keystore"; 492 // sizeof = 9, not strlen = 8 493 saltSize = sizeof("keystore"); 494 } 495 PKCS5_PBKDF2_HMAC_SHA1((char*) pw->value, pw->length, salt, saltSize, 8192, keySize, key); 496 } 497 498 static bool isKeyFile(const char* filename) { 499 return ((strcmp(filename, MASTER_KEY_FILE) != 0) 500 && (strcmp(filename, ".") != 0) 501 && (strcmp(filename, "..") != 0)); 502 } 503 }; 504 505 const char* KeyStore::MASTER_KEY_FILE = ".masterkey"; 506 507 /* Here is the protocol used in both requests and responses: 508 * code [length_1 message_1 ... length_n message_n] end-of-file 509 * where code is one byte long and lengths are unsigned 16-bit integers in 510 * network order. Thus the maximum length of a message is 65535 bytes. */ 511 512 static int recv_code(int sock, int8_t* code) { 513 return recv(sock, code, 1, 0) == 1; 514 } 515 516 static int recv_message(int sock, uint8_t* message, int length) { 517 uint8_t bytes[2]; 518 if (recv(sock, &bytes[0], 1, 0) != 1 || 519 recv(sock, &bytes[1], 1, 0) != 1) { 520 return -1; 521 } else { 522 int offset = bytes[0] << 8 | bytes[1]; 523 if (length < offset) { 524 return -1; 525 } 526 length = offset; 527 offset = 0; 528 while (offset < length) { 529 int n = recv(sock, &message[offset], length - offset, 0); 530 if (n <= 0) { 531 return -1; 532 } 533 offset += n; 534 } 535 } 536 return length; 537 } 538 539 static int recv_end_of_file(int sock) { 540 uint8_t byte; 541 return recv(sock, &byte, 1, 0) == 0; 542 } 543 544 static void send_code(int sock, int8_t code) { 545 send(sock, &code, 1, 0); 546 } 547 548 static void send_message(int sock, uint8_t* message, int length) { 549 uint16_t bytes = htons(length); 550 send(sock, &bytes, 2, 0); 551 send(sock, message, length, 0); 552 } 553 554 /* Here are the actions. Each of them is a function without arguments. All 555 * information is defined in global variables, which are set properly before 556 * performing an action. The number of parameters required by each action is 557 * fixed and defined in a table. If the return value of an action is positive, 558 * it will be treated as a response code and transmitted to the client. Note 559 * that the lengths of parameters are checked when they are received, so 560 * boundary checks on parameters are omitted. */ 561 562 static const ResponseCode NO_ERROR_RESPONSE_CODE_SENT = (ResponseCode) 0; 563 564 static ResponseCode test(KeyStore* keyStore, int sock, uid_t uid, Value*, Value*) { 565 return (ResponseCode) keyStore->getState(); 566 } 567 568 static ResponseCode get(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value*) { 569 char filename[NAME_MAX]; 570 encode_key(filename, uid, keyName); 571 Blob keyBlob; 572 ResponseCode responseCode = keyStore->get(filename, &keyBlob); 573 if (responseCode != NO_ERROR) { 574 return responseCode; 575 } 576 send_code(sock, NO_ERROR); 577 send_message(sock, keyBlob.getValue(), keyBlob.getLength()); 578 return NO_ERROR_RESPONSE_CODE_SENT; 579 } 580 581 static ResponseCode insert(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value* val) { 582 char filename[NAME_MAX]; 583 encode_key(filename, uid, keyName); 584 Blob keyBlob(val->value, val->length, 0, NULL); 585 return keyStore->put(filename, &keyBlob); 586 } 587 588 static ResponseCode del(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value*) { 589 char filename[NAME_MAX]; 590 encode_key(filename, uid, keyName); 591 return (unlink(filename) && errno != ENOENT) ? SYSTEM_ERROR : NO_ERROR; 592 } 593 594 static ResponseCode exist(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value*) { 595 char filename[NAME_MAX]; 596 encode_key(filename, uid, keyName); 597 if (access(filename, R_OK) == -1) { 598 return (errno != ENOENT) ? SYSTEM_ERROR : KEY_NOT_FOUND; 599 } 600 return NO_ERROR; 601 } 602 603 static ResponseCode saw(KeyStore* keyStore, int sock, uid_t uid, Value* keyPrefix, Value*) { 604 DIR* dir = opendir("."); 605 if (!dir) { 606 return SYSTEM_ERROR; 607 } 608 char filename[NAME_MAX]; 609 int n = encode_key(filename, uid, keyPrefix); 610 send_code(sock, NO_ERROR); 611 612 struct dirent* file; 613 while ((file = readdir(dir)) != NULL) { 614 if (!strncmp(filename, file->d_name, n)) { 615 char* p = &file->d_name[n]; 616 keyPrefix->length = decode_key(keyPrefix->value, p, strlen(p)); 617 send_message(sock, keyPrefix->value, keyPrefix->length); 618 } 619 } 620 closedir(dir); 621 return NO_ERROR_RESPONSE_CODE_SENT; 622 } 623 624 static ResponseCode reset(KeyStore* keyStore, int sock, uid_t uid, Value*, Value*) { 625 return keyStore->reset() ? NO_ERROR : SYSTEM_ERROR; 626 } 627 628 /* Here is the history. To improve the security, the parameters to generate the 629 * master key has been changed. To make a seamless transition, we update the 630 * file using the same password when the user unlock it for the first time. If 631 * any thing goes wrong during the transition, the new file will not overwrite 632 * the old one. This avoids permanent damages of the existing data. */ 633 634 static ResponseCode password(KeyStore* keyStore, int sock, uid_t uid, Value* pw, Value*) { 635 switch (keyStore->getState()) { 636 case STATE_UNINITIALIZED: { 637 // generate master key, encrypt with password, write to file, initialize mMasterKey*. 638 return keyStore->initialize(pw); 639 } 640 case STATE_NO_ERROR: { 641 // rewrite master key with new password. 642 return keyStore->writeMasterKey(pw); 643 } 644 case STATE_LOCKED: { 645 // read master key, decrypt with password, initialize mMasterKey*. 646 return keyStore->readMasterKey(pw); 647 } 648 } 649 return SYSTEM_ERROR; 650 } 651 652 static ResponseCode lock(KeyStore* keyStore, int sock, uid_t uid, Value*, Value*) { 653 keyStore->lock(); 654 return NO_ERROR; 655 } 656 657 static ResponseCode unlock(KeyStore* keyStore, int sock, uid_t uid, Value* pw, Value* unused) { 658 return password(keyStore, sock, uid, pw, unused); 659 } 660 661 static ResponseCode zero(KeyStore* keyStore, int sock, uid_t uid, Value*, Value*) { 662 return keyStore->isEmpty() ? KEY_NOT_FOUND : NO_ERROR; 663 } 664 665 /* Here are the permissions, actions, users, and the main function. */ 666 667 enum perm { 668 TEST = 1, 669 GET = 2, 670 INSERT = 4, 671 DELETE = 8, 672 EXIST = 16, 673 SAW = 32, 674 RESET = 64, 675 PASSWORD = 128, 676 LOCK = 256, 677 UNLOCK = 512, 678 ZERO = 1024, 679 }; 680 681 static const int MAX_PARAM = 2; 682 683 static const State STATE_ANY = (State) 0; 684 685 static struct action { 686 ResponseCode (*run)(KeyStore* keyStore, int sock, uid_t uid, Value* param1, Value* param2); 687 int8_t code; 688 State state; 689 uint32_t perm; 690 int lengths[MAX_PARAM]; 691 } actions[] = { 692 {test, 't', STATE_ANY, TEST, {0, 0}}, 693 {get, 'g', STATE_NO_ERROR, GET, {KEY_SIZE, 0}}, 694 {insert, 'i', STATE_NO_ERROR, INSERT, {KEY_SIZE, VALUE_SIZE}}, 695 {del, 'd', STATE_ANY, DELETE, {KEY_SIZE, 0}}, 696 {exist, 'e', STATE_ANY, EXIST, {KEY_SIZE, 0}}, 697 {saw, 's', STATE_ANY, SAW, {KEY_SIZE, 0}}, 698 {reset, 'r', STATE_ANY, RESET, {0, 0}}, 699 {password, 'p', STATE_ANY, PASSWORD, {PASSWORD_SIZE, 0}}, 700 {lock, 'l', STATE_NO_ERROR, LOCK, {0, 0}}, 701 {unlock, 'u', STATE_LOCKED, UNLOCK, {PASSWORD_SIZE, 0}}, 702 {zero, 'z', STATE_ANY, ZERO, {0, 0}}, 703 {NULL, 0 , STATE_ANY, 0, {0, 0}}, 704 }; 705 706 static struct user { 707 uid_t uid; 708 uid_t euid; 709 uint32_t perms; 710 } users[] = { 711 {AID_SYSTEM, ~0, ~0}, 712 {AID_VPN, AID_SYSTEM, GET}, 713 {AID_WIFI, AID_SYSTEM, GET}, 714 {AID_ROOT, AID_SYSTEM, GET}, 715 {~0, ~0, TEST | GET | INSERT | DELETE | EXIST | SAW}, 716 }; 717 718 static ResponseCode process(KeyStore* keyStore, int sock, uid_t uid, int8_t code) { 719 struct user* user = users; 720 struct action* action = actions; 721 int i; 722 723 while (~user->uid && user->uid != uid) { 724 ++user; 725 } 726 while (action->code && action->code != code) { 727 ++action; 728 } 729 if (!action->code) { 730 return UNDEFINED_ACTION; 731 } 732 if (!(action->perm & user->perms)) { 733 return PERMISSION_DENIED; 734 } 735 if (action->state != STATE_ANY && action->state != keyStore->getState()) { 736 return (ResponseCode) keyStore->getState(); 737 } 738 if (~user->euid) { 739 uid = user->euid; 740 } 741 Value params[MAX_PARAM]; 742 for (i = 0; i < MAX_PARAM && action->lengths[i] != 0; ++i) { 743 params[i].length = recv_message(sock, params[i].value, action->lengths[i]); 744 if (params[i].length < 0) { 745 return PROTOCOL_ERROR; 746 } 747 } 748 if (!recv_end_of_file(sock)) { 749 return PROTOCOL_ERROR; 750 } 751 return action->run(keyStore, sock, uid, ¶ms[0], ¶ms[1]); 752 } 753 754 int main(int argc, char* argv[]) { 755 int controlSocket = android_get_control_socket("keystore"); 756 if (argc < 2) { 757 LOGE("A directory must be specified!"); 758 return 1; 759 } 760 if (chdir(argv[1]) == -1) { 761 LOGE("chdir: %s: %s", argv[1], strerror(errno)); 762 return 1; 763 } 764 765 Entropy entropy; 766 if (!entropy.open()) { 767 return 1; 768 } 769 if (listen(controlSocket, 3) == -1) { 770 LOGE("listen: %s", strerror(errno)); 771 return 1; 772 } 773 774 signal(SIGPIPE, SIG_IGN); 775 776 KeyStore keyStore(&entropy); 777 int sock; 778 while ((sock = accept(controlSocket, NULL, 0)) != -1) { 779 struct timeval tv; 780 tv.tv_sec = 3; 781 setsockopt(sock, SOL_SOCKET, SO_RCVTIMEO, &tv, sizeof(tv)); 782 setsockopt(sock, SOL_SOCKET, SO_SNDTIMEO, &tv, sizeof(tv)); 783 784 struct ucred cred; 785 socklen_t size = sizeof(cred); 786 int credResult = getsockopt(sock, SOL_SOCKET, SO_PEERCRED, &cred, &size); 787 if (credResult != 0) { 788 LOGW("getsockopt: %s", strerror(errno)); 789 } else { 790 int8_t request; 791 if (recv_code(sock, &request)) { 792 State old_state = keyStore.getState(); 793 ResponseCode response = process(&keyStore, sock, cred.uid, request); 794 if (response == NO_ERROR_RESPONSE_CODE_SENT) { 795 response = NO_ERROR; 796 } else { 797 send_code(sock, response); 798 } 799 LOGI("uid: %d action: %c -> %d state: %d -> %d retry: %d", 800 cred.uid, 801 request, response, 802 old_state, keyStore.getState(), 803 keyStore.getRetry()); 804 } 805 } 806 close(sock); 807 } 808 LOGE("accept: %s", strerror(errno)); 809 return 1; 810 } 811
