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ara-mdk / platform / system / security / cd8df62842b81c93022feabfacda8efd257e1754 / . / keystore / keystore.cpp
blob: ef4c7d4a4cf48c931715223ba802cd7f521018cb [file] [log] [blame]
/*
* Copyright (C) 2009 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 <stdio.h>
#include <stdint.h>
#include <string.h>
#include <unistd.h>
#include <signal.h>
#include <errno.h>
#include <dirent.h>
#include <fcntl.h>
#include <limits.h>
#include <assert.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <arpa/inet.h>
#include <openssl/aes.h>
#include <openssl/bio.h>
#include <openssl/evp.h>
#include <openssl/md5.h>
#include <openssl/pem.h>
#include <hardware/keymaster.h>
#include <utils/UniquePtr.h>
#include <cutils/list.h>
//#define LOG_NDEBUG 0
#define LOG_TAG "keystore"
#include <cutils/log.h>
#include <cutils/sockets.h>
#include <private/android_filesystem_config.h>
#include "keystore.h"
/* KeyStore is a secured storage for key-value pairs. In this implementation,
* each file stores one key-value pair. Keys are encoded in file names, and
* values are encrypted with checksums. The encryption key is protected by a
* user-defined password. To keep things simple, buffers are always larger than
* the maximum space we needed, so boundary checks on buffers are omitted. */
#define KEY_SIZE ((NAME_MAX - 15) / 2)
#define VALUE_SIZE 32768
#define PASSWORD_SIZE VALUE_SIZE
struct BIO_Delete {
void operator()(BIO* p) const {
BIO_free(p);
}
};
typedef UniquePtr<BIO, BIO_Delete> Unique_BIO;
struct EVP_PKEY_Delete {
void operator()(EVP_PKEY* p) const {
EVP_PKEY_free(p);
}
};
typedef UniquePtr<EVP_PKEY, EVP_PKEY_Delete> Unique_EVP_PKEY;
struct PKCS8_PRIV_KEY_INFO_Delete {
void operator()(PKCS8_PRIV_KEY_INFO* p) const {
PKCS8_PRIV_KEY_INFO_free(p);
}
};
typedef UniquePtr<PKCS8_PRIV_KEY_INFO, PKCS8_PRIV_KEY_INFO_Delete> Unique_PKCS8_PRIV_KEY_INFO;
struct Value {
Value(const uint8_t* orig, int origLen) {
assert(origLen <= VALUE_SIZE);
memcpy(value, orig, origLen);
length = origLen;
}
Value() {
}
int length;
uint8_t value[VALUE_SIZE];
};
class ValueString {
public:
ValueString(const Value* orig) {
assert(length <= VALUE_SIZE);
length = orig->length;
value = new char[length + 1];
memcpy(value, orig->value, length);
value[length] = '\0';
}
~ValueString() {
delete[] value;
}
const char* c_str() const {
return value;
}
char* release() {
char* ret = value;
value = NULL;
return ret;
}
private:
char* value;
size_t length;
};
static int keymaster_device_initialize(keymaster_device_t** dev) {
int rc;
const hw_module_t* mod;
rc = hw_get_module_by_class(KEYSTORE_HARDWARE_MODULE_ID, NULL, &mod);
if (rc) {
ALOGE("could not find any keystore module");
goto out;
}
rc = keymaster_open(mod, dev);
if (rc) {
ALOGE("could not open keymaster device in %s (%s)",
KEYSTORE_HARDWARE_MODULE_ID, strerror(-rc));
goto out;
}
return 0;
out:
*dev = NULL;
return rc;
}
static void keymaster_device_release(keymaster_device_t* dev) {
keymaster_close(dev);
}
/* Here is the encoding of keys. This is necessary in order to allow arbitrary
* characters in keys. Characters in [0-~] are not encoded. Others are encoded
* into two bytes. The first byte is one of [+-.] which represents the first
* two bits of the character. The second byte encodes the rest of the bits into
* [0-o]. Therefore in the worst case the length of a key gets doubled. Note
* that Base64 cannot be used here due to the need of prefix match on keys. */
static int encode_key(char* out, const Value* key) {
const uint8_t* in = key->value;
int length = key->length;
for (int i = length; i > 0; --i, ++in, ++out) {
if (*in >= '0' && *in <= '~') {
*out = *in;
} else {
*out = '+' + (*in >> 6);
*++out = '0' + (*in & 0x3F);
++length;
}
}
*out = '\0';
return length;
}
static int encode_key_for_uid(char* out, uid_t uid, const Value* key) {
int n = snprintf(out, NAME_MAX, "%u_", uid);
out += n;
return n + encode_key(out, key);
}
static int decode_key(uint8_t* out, const char* in, int length) {
for (int i = 0; i < length; ++i, ++in, ++out) {
if (*in >= '0' && *in <= '~') {
*out = *in;
} else {
*out = (*in - '+') << 6;
*out |= (*++in - '0') & 0x3F;
--length;
}
}
*out = '\0';
return length;
}
static size_t readFully(int fd, uint8_t* data, size_t size) {
size_t remaining = size;
while (remaining > 0) {
ssize_t n = TEMP_FAILURE_RETRY(read(fd, data, size));
if (n == -1 || n == 0) {
return size-remaining;
}
data += n;
remaining -= n;
}
return size;
}
static size_t writeFully(int fd, uint8_t* data, size_t size) {
size_t remaining = size;
while (remaining > 0) {
ssize_t n = TEMP_FAILURE_RETRY(write(fd, data, size));
if (n == -1 || n == 0) {
return size-remaining;
}
data += n;
remaining -= n;
}
return size;
}
class Entropy {
public:
Entropy() : mRandom(-1) {}
~Entropy() {
if (mRandom != -1) {
close(mRandom);
}
}
bool open() {
const char* randomDevice = "/dev/urandom";
mRandom = ::open(randomDevice, O_RDONLY);
if (mRandom == -1) {
ALOGE("open: %s: %s", randomDevice, strerror(errno));
return false;
}
return true;
}
bool generate_random_data(uint8_t* data, size_t size) const {
return (readFully(mRandom, data, size) == size);
}
private:
int mRandom;
};
/* Here is the file format. There are two parts in blob.value, the secret and
* the description. The secret is stored in ciphertext, and its original size
* can be found in blob.length. The description is stored after the secret in
* plaintext, and its size is specified in blob.info. The total size of the two
* parts must be no more than VALUE_SIZE bytes. The first field is the version,
* the second is the blob's type, and the third byte is reserved. Fields other
* than blob.info, blob.length, and blob.value are modified by encryptBlob()
* and decryptBlob(). Thus they should not be accessed from outside. */
/* ** Note to future implementors of encryption: **
* Currently this is the construction:
* metadata || Enc(MD5(data) || data)
*
* This should be the construction used for encrypting if re-implementing:
*
* Derive independent keys for encryption and MAC:
* Kenc = AES_encrypt(masterKey, "Encrypt")
* Kmac = AES_encrypt(masterKey, "MAC")
*
* Store this:
* metadata || AES_CTR_encrypt(Kenc, rand_IV, data) ||
* HMAC(Kmac, metadata || Enc(data))
*/
struct __attribute__((packed)) blob {
uint8_t version;
uint8_t type;
uint8_t reserved;
uint8_t info;
uint8_t vector[AES_BLOCK_SIZE];
uint8_t encrypted[0]; // Marks offset to encrypted data.
uint8_t digest[MD5_DIGEST_LENGTH];
uint8_t digested[0]; // Marks offset to digested data.
int32_t length; // in network byte order when encrypted
uint8_t value[VALUE_SIZE + AES_BLOCK_SIZE];
};
typedef enum {
TYPE_GENERIC = 1,
TYPE_MASTER_KEY = 2,
TYPE_KEY_PAIR = 3,
} BlobType;
static const uint8_t CurrentBlobVersion = 1;
class Blob {
public:
Blob(uint8_t* value, int32_t valueLength, uint8_t* info, uint8_t infoLength, BlobType type) {
mBlob.length = valueLength;
memcpy(mBlob.value, value, valueLength);
mBlob.info = infoLength;
memcpy(mBlob.value + valueLength, info, infoLength);
mBlob.version = CurrentBlobVersion;
mBlob.type = uint8_t(type);
}
Blob(blob b) {
mBlob = b;
}
Blob() {}
const uint8_t* getValue() const {
return mBlob.value;
}
int32_t getLength() const {
return mBlob.length;
}
const uint8_t* getInfo() const {
return mBlob.value + mBlob.length;
}
uint8_t getInfoLength() const {
return mBlob.info;
}
uint8_t getVersion() const {
return mBlob.version;
}
void setVersion(uint8_t version) {
mBlob.version = version;
}
BlobType getType() const {
return BlobType(mBlob.type);
}
void setType(BlobType type) {
mBlob.type = uint8_t(type);
}
ResponseCode encryptBlob(const char* filename, AES_KEY *aes_key, Entropy* entropy) {
if (!entropy->generate_random_data(mBlob.vector, AES_BLOCK_SIZE)) {
return SYSTEM_ERROR;
}
// data includes the value and the value's length
size_t dataLength = mBlob.length + sizeof(mBlob.length);
// pad data to the AES_BLOCK_SIZE
size_t digestedLength = ((dataLength + AES_BLOCK_SIZE - 1)
/ AES_BLOCK_SIZE * AES_BLOCK_SIZE);
// encrypted data includes the digest value
size_t encryptedLength = digestedLength + MD5_DIGEST_LENGTH;
// move info after space for padding
memmove(&mBlob.encrypted[encryptedLength], &mBlob.value[mBlob.length], mBlob.info);
// zero padding area
memset(mBlob.value + mBlob.length, 0, digestedLength - dataLength);
mBlob.length = htonl(mBlob.length);
MD5(mBlob.digested, digestedLength, mBlob.digest);
uint8_t vector[AES_BLOCK_SIZE];
memcpy(vector, mBlob.vector, AES_BLOCK_SIZE);
AES_cbc_encrypt(mBlob.encrypted, mBlob.encrypted, encryptedLength,
aes_key, vector, AES_ENCRYPT);
mBlob.reserved = 0;
size_t headerLength = (mBlob.encrypted - (uint8_t*) &mBlob);
size_t fileLength = encryptedLength + headerLength + mBlob.info;
const char* tmpFileName = ".tmp";
int out = open(tmpFileName, O_WRONLY | O_TRUNC | O_CREAT, S_IRUSR | S_IWUSR);
if (out == -1) {
return SYSTEM_ERROR;
}
size_t writtenBytes = writeFully(out, (uint8_t*) &mBlob, fileLength);
if (close(out) != 0) {
return SYSTEM_ERROR;
}
if (writtenBytes != fileLength) {
unlink(tmpFileName);
return SYSTEM_ERROR;
}
return (rename(tmpFileName, filename) == 0) ? NO_ERROR : SYSTEM_ERROR;
}
ResponseCode decryptBlob(const char* filename, AES_KEY *aes_key) {
int in = open(filename, O_RDONLY);
if (in == -1) {
return (errno == ENOENT) ? KEY_NOT_FOUND : SYSTEM_ERROR;
}
// fileLength may be less than sizeof(mBlob) since the in
// memory version has extra padding to tolerate rounding up to
// the AES_BLOCK_SIZE
size_t fileLength = readFully(in, (uint8_t*) &mBlob, sizeof(mBlob));
if (close(in) != 0) {
return SYSTEM_ERROR;
}
size_t headerLength = (mBlob.encrypted - (uint8_t*) &mBlob);
if (fileLength < headerLength) {
return VALUE_CORRUPTED;
}
ssize_t encryptedLength = fileLength - (headerLength + mBlob.info);
if (encryptedLength < 0 || encryptedLength % AES_BLOCK_SIZE != 0) {
return VALUE_CORRUPTED;
}
AES_cbc_encrypt(mBlob.encrypted, mBlob.encrypted, encryptedLength, aes_key,
mBlob.vector, AES_DECRYPT);
size_t digestedLength = encryptedLength - MD5_DIGEST_LENGTH;
uint8_t computedDigest[MD5_DIGEST_LENGTH];
MD5(mBlob.digested, digestedLength, computedDigest);
if (memcmp(mBlob.digest, computedDigest, MD5_DIGEST_LENGTH) != 0) {
return VALUE_CORRUPTED;
}
ssize_t maxValueLength = digestedLength - sizeof(mBlob.length);
mBlob.length = ntohl(mBlob.length);
if (mBlob.length < 0 || mBlob.length > maxValueLength) {
return VALUE_CORRUPTED;
}
if (mBlob.info != 0) {
// move info from after padding to after data
memmove(&mBlob.value[mBlob.length], &mBlob.value[maxValueLength], mBlob.info);
}
return NO_ERROR;
}
private:
struct blob mBlob;
};
typedef struct {
uint32_t uid;
const uint8_t* filename;
struct listnode plist;
} grant_t;
class KeyStore {
public:
KeyStore(Entropy* entropy, keymaster_device_t* device)
: mEntropy(entropy)
, mDevice(device)
, mRetry(MAX_RETRY)
{
if (access(MASTER_KEY_FILE, R_OK) == 0) {
setState(STATE_LOCKED);
} else {
setState(STATE_UNINITIALIZED);
}
list_init(&mGrants);
}
State getState() const {
return mState;
}
int8_t getRetry() const {
return mRetry;
}
keymaster_device_t* getDevice() const {
return mDevice;
}
ResponseCode initialize(Value* pw) {
if (!generateMasterKey()) {
return SYSTEM_ERROR;
}
ResponseCode response = writeMasterKey(pw);
if (response != NO_ERROR) {
return response;
}
setupMasterKeys();
return NO_ERROR;
}
ResponseCode writeMasterKey(Value* pw) {
uint8_t passwordKey[MASTER_KEY_SIZE_BYTES];
generateKeyFromPassword(passwordKey, MASTER_KEY_SIZE_BYTES, pw, mSalt);
AES_KEY passwordAesKey;
AES_set_encrypt_key(passwordKey, MASTER_KEY_SIZE_BITS, &passwordAesKey);
Blob masterKeyBlob(mMasterKey, sizeof(mMasterKey), mSalt, sizeof(mSalt), TYPE_MASTER_KEY);
return masterKeyBlob.encryptBlob(MASTER_KEY_FILE, &passwordAesKey, mEntropy);
}
ResponseCode readMasterKey(Value* pw) {
int in = open(MASTER_KEY_FILE, O_RDONLY);
if (in == -1) {
return SYSTEM_ERROR;
}
// we read the raw blob to just to get the salt to generate
// the AES key, then we create the Blob to use with decryptBlob
blob rawBlob;
size_t length = readFully(in, (uint8_t*) &rawBlob, sizeof(rawBlob));
if (close(in) != 0) {
return SYSTEM_ERROR;
}
// find salt at EOF if present, otherwise we have an old file
uint8_t* salt;
if (length > SALT_SIZE && rawBlob.info == SALT_SIZE) {
salt = (uint8_t*) &rawBlob + length - SALT_SIZE;
} else {
salt = NULL;
}
uint8_t passwordKey[MASTER_KEY_SIZE_BYTES];
generateKeyFromPassword(passwordKey, MASTER_KEY_SIZE_BYTES, pw, salt);
AES_KEY passwordAesKey;
AES_set_decrypt_key(passwordKey, MASTER_KEY_SIZE_BITS, &passwordAesKey);
Blob masterKeyBlob(rawBlob);
ResponseCode response = masterKeyBlob.decryptBlob(MASTER_KEY_FILE, &passwordAesKey);
if (response == SYSTEM_ERROR) {
return SYSTEM_ERROR;
}
if (response == NO_ERROR && masterKeyBlob.getLength() == MASTER_KEY_SIZE_BYTES) {
// if salt was missing, generate one and write a new master key file with the salt.
if (salt == NULL) {
if (!generateSalt()) {
return SYSTEM_ERROR;
}
response = writeMasterKey(pw);
}
if (response == NO_ERROR) {
memcpy(mMasterKey, masterKeyBlob.getValue(), MASTER_KEY_SIZE_BYTES);
setupMasterKeys();
}
return response;
}
if (mRetry <= 0) {
reset();
return UNINITIALIZED;
}
--mRetry;
switch (mRetry) {
case 0: return WRONG_PASSWORD_0;
case 1: return WRONG_PASSWORD_1;
case 2: return WRONG_PASSWORD_2;
case 3: return WRONG_PASSWORD_3;
default: return WRONG_PASSWORD_3;
}
}
bool reset() {
clearMasterKeys();
setState(STATE_UNINITIALIZED);
DIR* dir = opendir(".");
struct dirent* file;
if (!dir) {
return false;
}
while ((file = readdir(dir)) != NULL) {
unlink(file->d_name);
}
closedir(dir);
return true;
}
bool isEmpty() const {
DIR* dir = opendir(".");
struct dirent* file;
if (!dir) {
return true;
}
bool result = true;
while ((file = readdir(dir)) != NULL) {
if (isKeyFile(file->d_name)) {
result = false;
break;
}
}
closedir(dir);
return result;
}
void lock() {
clearMasterKeys();
setState(STATE_LOCKED);
}
ResponseCode get(const char* filename, Blob* keyBlob, const BlobType type) {
ResponseCode rc = keyBlob->decryptBlob(filename, &mMasterKeyDecryption);
if (rc != NO_ERROR) {
return rc;
}
const uint8_t version = keyBlob->getVersion();
if (version < CurrentBlobVersion) {
upgrade(filename, keyBlob, version, type);
}
if (keyBlob->getType() != type) {
ALOGW("key found but type doesn't match: %d vs %d", keyBlob->getType(), type);
return KEY_NOT_FOUND;
}
return rc;
}
ResponseCode put(const char* filename, Blob* keyBlob) {
return keyBlob->encryptBlob(filename, &mMasterKeyEncryption, mEntropy);
}
void addGrant(const char* filename, const Value* uidValue) {
uid_t uid;
if (!convertToUid(uidValue, &uid)) {
return;
}
grant_t *grant = getGrant(filename, uid);
if (grant == NULL) {
grant = new grant_t;
grant->uid = uid;
grant->filename = reinterpret_cast<const uint8_t*>(strdup(filename));
list_add_tail(&mGrants, &grant->plist);
}
}
bool removeGrant(const char* filename, const Value* uidValue) {
uid_t uid;
if (!convertToUid(uidValue, &uid)) {
return false;
}
grant_t *grant = getGrant(filename, uid);
if (grant != NULL) {
list_remove(&grant->plist);
delete grant;
return true;
}
return false;
}
bool hasGrant(const char* filename, const uid_t uid) const {
return getGrant(filename, uid) != NULL;
}
ResponseCode importKey(const Value* key, const char* filename) {
uint8_t* data;
size_t dataLength;
int rc;
if (mDevice->import_keypair == NULL) {
ALOGE("Keymaster doesn't support import!");
return SYSTEM_ERROR;
}
rc = mDevice->import_keypair(mDevice, key->value, key->length, &data, &dataLength);
if (rc) {
ALOGE("Error while importing keypair: %d", rc);
return SYSTEM_ERROR;
}
Blob keyBlob(data, dataLength, NULL, 0, TYPE_KEY_PAIR);
free(data);
return put(filename, &keyBlob);
}
private:
static const char* MASTER_KEY_FILE;
static const int MASTER_KEY_SIZE_BYTES = 16;
static const int MASTER_KEY_SIZE_BITS = MASTER_KEY_SIZE_BYTES * 8;
static const int MAX_RETRY = 4;
static const size_t SALT_SIZE = 16;
Entropy* mEntropy;
keymaster_device_t* mDevice;
State mState;
int8_t mRetry;
uint8_t mMasterKey[MASTER_KEY_SIZE_BYTES];
uint8_t mSalt[SALT_SIZE];
AES_KEY mMasterKeyEncryption;
AES_KEY mMasterKeyDecryption;
struct listnode mGrants;
void setState(State state) {
mState = state;
if (mState == STATE_NO_ERROR || mState == STATE_UNINITIALIZED) {
mRetry = MAX_RETRY;
}
}
bool generateSalt() {
return mEntropy->generate_random_data(mSalt, sizeof(mSalt));
}
bool generateMasterKey() {
if (!mEntropy->generate_random_data(mMasterKey, sizeof(mMasterKey))) {
return false;
}
if (!generateSalt()) {
return false;
}
return true;
}
void setupMasterKeys() {
AES_set_encrypt_key(mMasterKey, MASTER_KEY_SIZE_BITS, &mMasterKeyEncryption);
AES_set_decrypt_key(mMasterKey, MASTER_KEY_SIZE_BITS, &mMasterKeyDecryption);
setState(STATE_NO_ERROR);
}
void clearMasterKeys() {
memset(mMasterKey, 0, sizeof(mMasterKey));
memset(mSalt, 0, sizeof(mSalt));
memset(&mMasterKeyEncryption, 0, sizeof(mMasterKeyEncryption));
memset(&mMasterKeyDecryption, 0, sizeof(mMasterKeyDecryption));
}
static void generateKeyFromPassword(uint8_t* key, ssize_t keySize, Value* pw, uint8_t* salt) {
size_t saltSize;
if (salt != NULL) {
saltSize = SALT_SIZE;
} else {
// pre-gingerbread used this hardwired salt, readMasterKey will rewrite these when found
salt = (uint8_t*) "keystore";
// sizeof = 9, not strlen = 8
saltSize = sizeof("keystore");
}
PKCS5_PBKDF2_HMAC_SHA1((char*) pw->value, pw->length, salt, saltSize, 8192, keySize, key);
}
static bool isKeyFile(const char* filename) {
return ((strcmp(filename, MASTER_KEY_FILE) != 0)
&& (strcmp(filename, ".") != 0)
&& (strcmp(filename, "..") != 0));
}
grant_t* getGrant(const char* filename, uid_t uid) const {
struct listnode *node;
grant_t *grant;
list_for_each(node, &mGrants) {
grant = node_to_item(node, grant_t, plist);
if (grant->uid == uid
&& !strcmp(reinterpret_cast<const char*>(grant->filename),
filename)) {
return grant;
}
}
return NULL;
}
bool convertToUid(const Value* uidValue, uid_t* uid) const {
ValueString uidString(uidValue);
char* end = NULL;
*uid = strtol(uidString.c_str(), &end, 10);
return *end == '\0';
}
/**
* Upgrade code. This will upgrade the key from the current version
* to whatever is newest.
*/
void upgrade(const char* filename, Blob* blob, const uint8_t oldVersion, const BlobType type) {
bool updated = false;
uint8_t version = oldVersion;
/* From V0 -> V1: All old types were unknown */
if (version == 0) {
ALOGV("upgrading to version 1 and setting type %d", type);
blob->setType(type);
if (type == TYPE_KEY_PAIR) {
importBlobAsKey(blob, filename);
}
version = 1;
updated = true;
}
/*
* If we've updated, set the key blob to the right version
* and write it.
* */
if (updated) {
ALOGV("updated and writing file %s", filename);
blob->setVersion(version);
this->put(filename, blob);
}
}
/**
* Takes a blob that is an PEM-encoded RSA key as a byte array and
* converts it to a DER-encoded PKCS#8 for import into a keymaster.
* Then it overwrites the original blob with the new blob
* format that is returned from the keymaster.
*/
ResponseCode importBlobAsKey(Blob* blob, const char* filename) {
// We won't even write to the blob directly with this BIO, so const_cast is okay.
Unique_BIO b(BIO_new_mem_buf(const_cast<uint8_t*>(blob->getValue()), blob->getLength()));
if (b.get() == NULL) {
ALOGE("Problem instantiating BIO");
return SYSTEM_ERROR;
}
Unique_EVP_PKEY pkey(PEM_read_bio_PrivateKey(b.get(), NULL, NULL, NULL));
if (pkey.get() == NULL) {
ALOGE("Couldn't read old PEM file");
return SYSTEM_ERROR;
}
Unique_PKCS8_PRIV_KEY_INFO pkcs8(EVP_PKEY2PKCS8(pkey.get()));
int len = i2d_PKCS8_PRIV_KEY_INFO(pkcs8.get(), NULL);
if (len < 0) {
ALOGE("Couldn't measure PKCS#8 length");
return SYSTEM_ERROR;
}
Value pkcs8key;
pkcs8key.length = len;
uint8_t* tmp = pkcs8key.value;
if (i2d_PKCS8_PRIV_KEY_INFO(pkcs8.get(), &tmp) != len) {
ALOGE("Couldn't convert to PKCS#8");
return SYSTEM_ERROR;
}
ResponseCode rc = importKey(&pkcs8key, filename);
if (rc != NO_ERROR) {
return rc;
}
return get(filename, blob, TYPE_KEY_PAIR);
}
};
const char* KeyStore::MASTER_KEY_FILE = ".masterkey";
/* Here is the protocol used in both requests and responses:
* code [length_1 message_1 ... length_n message_n] end-of-file
* where code is one byte long and lengths are unsigned 16-bit integers in
* network order. Thus the maximum length of a message is 65535 bytes. */
static int recv_code(int sock, int8_t* code) {
return recv(sock, code, 1, 0) == 1;
}
static int recv_message(int sock, uint8_t* message, int length) {
uint8_t bytes[2];
if (recv(sock, &bytes[0], 1, 0) != 1 ||
recv(sock, &bytes[1], 1, 0) != 1) {
return -1;
} else {
int offset = bytes[0] << 8 | bytes[1];
if (length < offset) {
return -1;
}
length = offset;
offset = 0;
while (offset < length) {
int n = recv(sock, &message[offset], length - offset, 0);
if (n <= 0) {
return -1;
}
offset += n;
}
}
return length;
}
static int recv_end_of_file(int sock) {
uint8_t byte;
return recv(sock, &byte, 1, 0) == 0;
}
static void send_code(int sock, int8_t code) {
send(sock, &code, 1, 0);
}
static void send_message(int sock, const uint8_t* message, int length) {
uint16_t bytes = htons(length);
send(sock, &bytes, 2, 0);
send(sock, message, length, 0);
}
static ResponseCode get_key_for_name(KeyStore* keyStore, Blob* keyBlob, const Value* keyName,
const uid_t uid, const BlobType type) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
ResponseCode responseCode = keyStore->get(filename, keyBlob, type);
if (responseCode == NO_ERROR) {
return responseCode;
}
// If this is the Wifi or VPN user, they actually want system
// UID keys.
if (uid == AID_WIFI || uid == AID_VPN) {
encode_key_for_uid(filename, AID_SYSTEM, keyName);
responseCode = keyStore->get(filename, keyBlob, type);
if (responseCode == NO_ERROR) {
return responseCode;
}
}
// They might be using a granted key.
encode_key(filename, keyName);
if (!keyStore->hasGrant(filename, uid)) {
return responseCode;
}
// It is a granted key. Try to load it.
return keyStore->get(filename, keyBlob, type);
}
/* Here are the actions. Each of them is a function without arguments. All
* information is defined in global variables, which are set properly before
* performing an action. The number of parameters required by each action is
* fixed and defined in a table. If the return value of an action is positive,
* it will be treated as a response code and transmitted to the client. Note
* that the lengths of parameters are checked when they are received, so
* boundary checks on parameters are omitted. */
static const ResponseCode NO_ERROR_RESPONSE_CODE_SENT = (ResponseCode) 0;
static ResponseCode test(KeyStore* keyStore, int, uid_t, Value*, Value*, Value*) {
return (ResponseCode) keyStore->getState();
}
static ResponseCode get(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value*, Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
Blob keyBlob;
ResponseCode responseCode = keyStore->get(filename, &keyBlob, TYPE_GENERIC);
if (responseCode != NO_ERROR) {
return responseCode;
}
send_code(sock, NO_ERROR);
send_message(sock, keyBlob.getValue(), keyBlob.getLength());
return NO_ERROR_RESPONSE_CODE_SENT;
}
static ResponseCode insert(KeyStore* keyStore, int, uid_t uid, Value* keyName, Value* val,
Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
Blob keyBlob(val->value, val->length, NULL, 0, TYPE_GENERIC);
return keyStore->put(filename, &keyBlob);
}
static ResponseCode del(KeyStore* keyStore, int, uid_t uid, Value* keyName, Value*, Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
Blob keyBlob;
ResponseCode responseCode = keyStore->get(filename, &keyBlob, TYPE_GENERIC);
if (responseCode != NO_ERROR) {
return responseCode;
}
return (unlink(filename) && errno != ENOENT) ? SYSTEM_ERROR : NO_ERROR;
}
static ResponseCode exist(KeyStore*, int, uid_t uid, Value* keyName, Value*, Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
if (access(filename, R_OK) == -1) {
return (errno != ENOENT) ? SYSTEM_ERROR : KEY_NOT_FOUND;
}
return NO_ERROR;
}
static ResponseCode saw(KeyStore*, int sock, uid_t uid, Value* keyPrefix, Value*, Value*) {
DIR* dir = opendir(".");
if (!dir) {
return SYSTEM_ERROR;
}
char filename[NAME_MAX];
int n = encode_key_for_uid(filename, uid, keyPrefix);
send_code(sock, NO_ERROR);
struct dirent* file;
while ((file = readdir(dir)) != NULL) {
if (!strncmp(filename, file->d_name, n)) {
const char* p = &file->d_name[n];
keyPrefix->length = decode_key(keyPrefix->value, p, strlen(p));
send_message(sock, keyPrefix->value, keyPrefix->length);
}
}
closedir(dir);
return NO_ERROR_RESPONSE_CODE_SENT;
}
static ResponseCode reset(KeyStore* keyStore, int, uid_t, Value*, Value*, Value*) {
ResponseCode rc = keyStore->reset() ? NO_ERROR : SYSTEM_ERROR;
const keymaster_device_t* device = keyStore->getDevice();
if (device == NULL) {
ALOGE("No keymaster device!");
return SYSTEM_ERROR;
}
if (device->delete_all == NULL) {
ALOGV("keymaster device doesn't implement delete_all");
return rc;
}
if (device->delete_all(device)) {
ALOGE("Problem calling keymaster's delete_all");
return SYSTEM_ERROR;
}
return rc;
}
/* Here is the history. To improve the security, the parameters to generate the
* master key has been changed. To make a seamless transition, we update the
* file using the same password when the user unlock it for the first time. If
* any thing goes wrong during the transition, the new file will not overwrite
* the old one. This avoids permanent damages of the existing data. */
static ResponseCode password(KeyStore* keyStore, int, uid_t, Value* pw, Value*, Value*) {
switch (keyStore->getState()) {
case STATE_UNINITIALIZED: {
// generate master key, encrypt with password, write to file, initialize mMasterKey*.
return keyStore->initialize(pw);
}
case STATE_NO_ERROR: {
// rewrite master key with new password.
return keyStore->writeMasterKey(pw);
}
case STATE_LOCKED: {
// read master key, decrypt with password, initialize mMasterKey*.
return keyStore->readMasterKey(pw);
}
}
return SYSTEM_ERROR;
}
static ResponseCode lock(KeyStore* keyStore, int, uid_t, Value*, Value*, Value*) {
keyStore->lock();
return NO_ERROR;
}
static ResponseCode unlock(KeyStore* keyStore, int sock, uid_t uid, Value* pw, Value* unused,
Value* unused2) {
return password(keyStore, sock, uid, pw, unused, unused2);
}
static ResponseCode zero(KeyStore* keyStore, int, uid_t, Value*, Value*, Value*) {
return keyStore->isEmpty() ? KEY_NOT_FOUND : NO_ERROR;
}
static ResponseCode generate(KeyStore* keyStore, int, uid_t uid, Value* keyName, Value*,
Value*) {
char filename[NAME_MAX];
uint8_t* data;
size_t dataLength;
int rc;
const keymaster_device_t* device = keyStore->getDevice();
if (device == NULL) {
return SYSTEM_ERROR;
}
if (device->generate_keypair == NULL) {
return SYSTEM_ERROR;
}
keymaster_rsa_keygen_params_t rsa_params;
rsa_params.modulus_size = 2048;
rsa_params.public_exponent = 0x10001;
rc = device->generate_keypair(device, TYPE_RSA, &rsa_params, &data, &dataLength);
if (rc) {
return SYSTEM_ERROR;
}
encode_key_for_uid(filename, uid, keyName);
Blob keyBlob(data, dataLength, NULL, 0, TYPE_KEY_PAIR);
free(data);
return keyStore->put(filename, &keyBlob);
}
static ResponseCode import(KeyStore* keyStore, int, uid_t uid, Value* keyName, Value* key,
Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
return keyStore->importKey(key, filename);
}
/*
* TODO: The abstraction between things stored in hardware and regular blobs
* of data stored on the filesystem should be moved down to keystore itself.
* Unfortunately the Java code that calls this has naming conventions that it
* knows about. Ideally keystore shouldn't be used to store random blobs of
* data.
*
* Until that happens, it's necessary to have a separate "get_pubkey" and
* "del_key" since the Java code doesn't really communicate what it's
* intentions are.
*/
static ResponseCode get_pubkey(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value*, Value*) {
Blob keyBlob;
ALOGV("get_pubkey '%s' from uid %d", ValueString(keyName).c_str(), uid);
ResponseCode responseCode = get_key_for_name(keyStore, &keyBlob, keyName, uid, TYPE_KEY_PAIR);
if (responseCode != NO_ERROR) {
return responseCode;
}
const keymaster_device_t* device = keyStore->getDevice();
if (device == NULL) {
return SYSTEM_ERROR;
}
if (device->get_keypair_public == NULL) {
ALOGE("device has no get_keypair_public implementation!");
return SYSTEM_ERROR;
}
uint8_t* data = NULL;
size_t dataLength;
int rc = device->get_keypair_public(device, keyBlob.getValue(), keyBlob.getLength(), &data,
&dataLength);
if (rc) {
return SYSTEM_ERROR;
}
send_code(sock, NO_ERROR);
send_message(sock, data, dataLength);
free(data);
return NO_ERROR_RESPONSE_CODE_SENT;
}
static ResponseCode del_key(KeyStore* keyStore, int, uid_t uid, Value* keyName, Value*,
Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
Blob keyBlob;
ResponseCode responseCode = keyStore->get(filename, &keyBlob, TYPE_KEY_PAIR);
if (responseCode != NO_ERROR) {
return responseCode;
}
ResponseCode rc = NO_ERROR;
const keymaster_device_t* device = keyStore->getDevice();
if (device == NULL) {
rc = SYSTEM_ERROR;
} else {
// A device doesn't have to implement delete_keypair.
if (device->delete_keypair != NULL) {
if (device->delete_keypair(device, keyBlob.getValue(), keyBlob.getLength())) {
rc = SYSTEM_ERROR;
}
}
}
if (rc != NO_ERROR) {
return rc;
}
return (unlink(filename) && errno != ENOENT) ? SYSTEM_ERROR : NO_ERROR;
}
static ResponseCode sign(KeyStore* keyStore, int sock, uid_t uid, Value* keyName, Value* data,
Value*) {
ALOGV("sign %s from uid %d", ValueString(keyName).c_str(), uid);
Blob keyBlob;
int rc;
ResponseCode responseCode = get_key_for_name(keyStore, &keyBlob, keyName, uid, TYPE_KEY_PAIR);
if (responseCode != NO_ERROR) {
return responseCode;
}
uint8_t* signedData;
size_t signedDataLength;
const keymaster_device_t* device = keyStore->getDevice();
if (device == NULL) {
ALOGE("no keymaster device; cannot sign");
return SYSTEM_ERROR;
}
if (device->sign_data == NULL) {
ALOGE("device doesn't implement signing");
return SYSTEM_ERROR;
}
keymaster_rsa_sign_params_t params;
params.digest_type = DIGEST_NONE;
params.padding_type = PADDING_NONE;
rc = device->sign_data(device, &params, keyBlob.getValue(), keyBlob.getLength(),
data->value, data->length, &signedData, &signedDataLength);
if (rc) {
ALOGW("device couldn't sign data");
return SYSTEM_ERROR;
}
send_code(sock, NO_ERROR);
send_message(sock, signedData, signedDataLength);
return NO_ERROR_RESPONSE_CODE_SENT;
}
static ResponseCode verify(KeyStore* keyStore, int, uid_t uid, Value* keyName, Value* data,
Value* signature) {
Blob keyBlob;
int rc;
ResponseCode responseCode = get_key_for_name(keyStore, &keyBlob, keyName, uid, TYPE_KEY_PAIR);
if (responseCode != NO_ERROR) {
return responseCode;
}
const keymaster_device_t* device = keyStore->getDevice();
if (device == NULL) {
return SYSTEM_ERROR;
}
if (device->verify_data == NULL) {
return SYSTEM_ERROR;
}
keymaster_rsa_sign_params_t params;
params.digest_type = DIGEST_NONE;
params.padding_type = PADDING_NONE;
rc = device->verify_data(device, &params, keyBlob.getValue(), keyBlob.getLength(),
data->value, data->length, signature->value, signature->length);
if (rc) {
return SYSTEM_ERROR;
} else {
return NO_ERROR;
}
}
static ResponseCode grant(KeyStore* keyStore, int, uid_t uid, Value* keyName,
Value* granteeData, Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
if (access(filename, R_OK) == -1) {
return (errno != ENOENT) ? SYSTEM_ERROR : KEY_NOT_FOUND;
}
keyStore->addGrant(filename, granteeData);
return NO_ERROR;
}
static ResponseCode ungrant(KeyStore* keyStore, int, uid_t uid, Value* keyName,
Value* granteeData, Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
if (access(filename, R_OK) == -1) {
return (errno != ENOENT) ? SYSTEM_ERROR : KEY_NOT_FOUND;
}
return keyStore->removeGrant(filename, granteeData) ? NO_ERROR : KEY_NOT_FOUND;
}
static ResponseCode getmtime(KeyStore*, int sock, uid_t uid, Value* keyName,
Value*, Value*) {
char filename[NAME_MAX];
encode_key_for_uid(filename, uid, keyName);
if (access(filename, R_OK) == -1) {
return (errno != ENOENT) ? SYSTEM_ERROR : KEY_NOT_FOUND;
}
int fd = open(filename, O_NOFOLLOW, O_RDONLY);
if (fd < 0) {
return SYSTEM_ERROR;
}
struct stat s;
int ret = fstat(fd, &s);
close(fd);
if (ret == -1) {
return SYSTEM_ERROR;
}
uint8_t *data;
int dataLength = asprintf(reinterpret_cast<char**>(&data), "%lu", s.st_mtime);
if (dataLength < 0) {
return SYSTEM_ERROR;
}
send_code(sock, NO_ERROR);
send_message(sock, data, dataLength);
free(data);
return NO_ERROR_RESPONSE_CODE_SENT;
}
/* Here are the permissions, actions, users, and the main function. */
enum perm {
P_TEST = 1 << TEST,
P_GET = 1 << GET,
P_INSERT = 1 << INSERT,
P_DELETE = 1 << DELETE,
P_EXIST = 1 << EXIST,
P_SAW = 1 << SAW,
P_RESET = 1 << RESET,
P_PASSWORD = 1 << PASSWORD,
P_LOCK = 1 << LOCK,
P_UNLOCK = 1 << UNLOCK,
P_ZERO = 1 << ZERO,
P_SIGN = 1 << SIGN,
P_VERIFY = 1 << VERIFY,
P_GRANT = 1 << GRANT,
};
static const int MAX_PARAM = 3;
static const State STATE_ANY = (State) 0;
static struct action {
ResponseCode (*run)(KeyStore* keyStore, int sock, uid_t uid, Value* param1, Value* param2,
Value* param3);
int8_t code;
State state;
uint32_t perm;
int lengths[MAX_PARAM];
} actions[] = {
{test, CommandCodes[TEST], STATE_ANY, P_TEST, {0, 0, 0}},
{get, CommandCodes[GET], STATE_NO_ERROR, P_GET, {KEY_SIZE, 0, 0}},
{insert, CommandCodes[INSERT], STATE_NO_ERROR, P_INSERT, {KEY_SIZE, VALUE_SIZE, 0}},
{del, CommandCodes[DELETE], STATE_ANY, P_DELETE, {KEY_SIZE, 0, 0}},
{exist, CommandCodes[EXIST], STATE_ANY, P_EXIST, {KEY_SIZE, 0, 0}},
{saw, CommandCodes[SAW], STATE_ANY, P_SAW, {KEY_SIZE, 0, 0}},
{reset, CommandCodes[RESET], STATE_ANY, P_RESET, {0, 0, 0}},
{password, CommandCodes[PASSWORD], STATE_ANY, P_PASSWORD, {PASSWORD_SIZE, 0, 0}},
{lock, CommandCodes[LOCK], STATE_NO_ERROR, P_LOCK, {0, 0, 0}},
{unlock, CommandCodes[UNLOCK], STATE_LOCKED, P_UNLOCK, {PASSWORD_SIZE, 0, 0}},
{zero, CommandCodes[ZERO], STATE_ANY, P_ZERO, {0, 0, 0}},
{generate, CommandCodes[GENERATE], STATE_NO_ERROR, P_INSERT, {KEY_SIZE, 0, 0}},
{import, CommandCodes[IMPORT], STATE_NO_ERROR, P_INSERT, {KEY_SIZE, VALUE_SIZE, 0}},
{sign, CommandCodes[SIGN], STATE_NO_ERROR, P_SIGN, {KEY_SIZE, VALUE_SIZE, 0}},
{verify, CommandCodes[VERIFY], STATE_NO_ERROR, P_VERIFY, {KEY_SIZE, VALUE_SIZE, VALUE_SIZE}},
{get_pubkey, CommandCodes[GET_PUBKEY], STATE_NO_ERROR, P_GET, {KEY_SIZE, 0, 0}},
{del_key, CommandCodes[DEL_KEY], STATE_ANY, P_DELETE, {KEY_SIZE, 0, 0}},
{grant, CommandCodes[GRANT], STATE_NO_ERROR, P_GRANT, {KEY_SIZE, KEY_SIZE, 0}},
{ungrant, CommandCodes[UNGRANT], STATE_NO_ERROR, P_GRANT, {KEY_SIZE, KEY_SIZE, 0}},
{getmtime, CommandCodes[GETMTIME], STATE_ANY, P_SAW, {KEY_SIZE, 0, 0}},
{NULL, 0, STATE_ANY, 0, {0, 0, 0}},
};
static struct user {
uid_t uid;
uid_t euid;
uint32_t perms;
} users[] = {
{AID_SYSTEM, ~0, ~0},
{AID_VPN, AID_SYSTEM, P_GET | P_SIGN | P_VERIFY },
{AID_WIFI, AID_SYSTEM, P_GET | P_SIGN | P_VERIFY },
{AID_ROOT, AID_SYSTEM, P_GET},
{~0, ~0, P_TEST | P_GET | P_INSERT | P_DELETE | P_EXIST | P_SAW |
P_SIGN | P_VERIFY},
};
static ResponseCode process(KeyStore* keyStore, int sock, uid_t uid, int8_t code) {
struct user* user = users;
struct action* action = actions;
int i;
while (~user->uid && user->uid != (uid % AID_USER)) {
++user;
}
while (action->code && action->code != code) {
++action;
}
if (!action->code) {
return UNDEFINED_ACTION;
}
if (!(action->perm & user->perms)) {
return PERMISSION_DENIED;
}
if (action->state != STATE_ANY && action->state != keyStore->getState()) {
return (ResponseCode) keyStore->getState();
}
if (~user->euid) {
uid = user->euid;
}
Value params[MAX_PARAM];
for (i = 0; i < MAX_PARAM && action->lengths[i] != 0; ++i) {
params[i].length = recv_message(sock, params[i].value, action->lengths[i]);
if (params[i].length < 0) {
return PROTOCOL_ERROR;
}
}
if (!recv_end_of_file(sock)) {
return PROTOCOL_ERROR;
}
return action->run(keyStore, sock, uid, &params[0], &params[1], &params[2]);
}
int main(int argc, char* argv[]) {
int controlSocket = android_get_control_socket("keystore");
if (argc < 2) {
ALOGE("A directory must be specified!");
return 1;
}
if (chdir(argv[1]) == -1) {
ALOGE("chdir: %s: %s", argv[1], strerror(errno));
return 1;
}
Entropy entropy;
if (!entropy.open()) {
return 1;
}
keymaster_device_t* dev;
if (keymaster_device_initialize(&dev)) {
ALOGE("keystore keymaster could not be initialized; exiting");
return 1;
}
if (listen(controlSocket, 3) == -1) {
ALOGE("listen: %s", strerror(errno));
return 1;
}
signal(SIGPIPE, SIG_IGN);
KeyStore keyStore(&entropy, dev);
int sock;
while ((sock = accept(controlSocket, NULL, 0)) != -1) {
struct timeval tv;
tv.tv_sec = 3;
setsockopt(sock, SOL_SOCKET, SO_RCVTIMEO, &tv, sizeof(tv));
setsockopt(sock, SOL_SOCKET, SO_SNDTIMEO, &tv, sizeof(tv));
struct ucred cred;
socklen_t size = sizeof(cred);
int credResult = getsockopt(sock, SOL_SOCKET, SO_PEERCRED, &cred, &size);
if (credResult != 0) {
ALOGW("getsockopt: %s", strerror(errno));
} else {
int8_t request;
if (recv_code(sock, &request)) {
State old_state = keyStore.getState();
ResponseCode response = process(&keyStore, sock, cred.uid, request);
if (response == NO_ERROR_RESPONSE_CODE_SENT) {
response = NO_ERROR;
} else {
send_code(sock, response);
}
ALOGI("uid: %d action: %c -> %d state: %d -> %d retry: %d",
cred.uid,
request, response,
old_state, keyStore.getState(),
keyStore.getRetry());
}
}
close(sock);
}
ALOGE("accept: %s", strerror(errno));
keymaster_device_release(dev);
return 1;
}