key_blob.cpp - platform/system/keymaster - Git at Google

 /*
  * Copyright 2014 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 <assert.h>

 #include <openssl/aes.h>
 #include <openssl/sha.h>

 #include <keymaster/google_keymaster_utils.h>
 #include <keymaster/key_blob.h>

 #include "ae.h"

 namespace keymaster {

 class KeyBlob::AeCtx {
   public:
     AeCtx() : ctx_(ae_allocate(NULL)) {}
     ~AeCtx() {
         ae_clear(ctx_);
         ae_free(ctx_);
     }

     ae_ctx* get() { return ctx_; }

   private:
     ae_ctx* ctx_;
 };

 const size_t KeyBlob::NONCE_LENGTH;
 const size_t KeyBlob::TAG_LENGTH;

 KeyBlob::KeyBlob(const AuthorizationSet& enforced, const AuthorizationSet& unenforced,
                  const AuthorizationSet& hidden, const keymaster_key_blob_t& key,
                  const keymaster_key_blob_t& master_key, const uint8_t nonce[NONCE_LENGTH])
     : error_(KM_ERROR_OK), nonce_(new uint8_t[NONCE_LENGTH]), tag_(new uint8_t[TAG_LENGTH]),
       enforced_(enforced), unenforced_(unenforced), hidden_(hidden) {
     if (!nonce_.get() || !tag_.get()) {
         error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return;
     }
     error_ = KM_ERROR_OK;

     if (enforced_.is_valid() == AuthorizationSet::ALLOCATION_FAILURE ||
         unenforced_.is_valid() == AuthorizationSet::ALLOCATION_FAILURE ||
         hidden_.is_valid() == AuthorizationSet::ALLOCATION_FAILURE) {
         error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return;
     }

     if (enforced_.is_valid() != AuthorizationSet::OK ||
         unenforced_.is_valid() != AuthorizationSet::OK ||
         hidden_.is_valid() != AuthorizationSet::OK) {
         error_ = KM_ERROR_UNKNOWN_ERROR;
         return;
     }

     if (!ExtractKeyCharacteristics())
         return;

     key_material_length_ = key.key_material_size;
     key_material_.reset(new uint8_t[key_material_length_]);
     encrypted_key_material_.reset(new uint8_t[key_material_length_]);

     if (!key_material_.get() || !encrypted_key_material_.get() || !nonce_.get() || !tag_.get()) {
         error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return;
     }

     memcpy(nonce_.get(), nonce, NONCE_LENGTH);
     memcpy(key_material_.get(), key.key_material, key_material_length_);
     EncryptKey(master_key);
 }

 KeyBlob::KeyBlob(const keymaster_key_blob_t& key, const AuthorizationSet& hidden,
                  const keymaster_key_blob_t& master_key)
     : nonce_(new uint8_t[NONCE_LENGTH]), tag_(new uint8_t[TAG_LENGTH]), hidden_(hidden) {
     if (!nonce_.get() || !tag_.get()) {
         error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return;
     }
     error_ = KM_ERROR_OK;

     const uint8_t* p = key.key_material;
     if (!Deserialize(&p, key.key_material + key.key_material_size))
         return;
     DecryptKey(master_key);
 }

 KeyBlob::KeyBlob(const uint8_t* key_blob, size_t blob_size)
     : nonce_(new uint8_t[NONCE_LENGTH]), tag_(new uint8_t[TAG_LENGTH]) {
     if (!nonce_.get() || !tag_.get()) {
         error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return;
     }
     error_ = KM_ERROR_OK;

     if (!Deserialize(&key_blob, key_blob + blob_size))
         return;
 }

 size_t KeyBlob::SerializedSize() const {
     return NONCE_LENGTH + sizeof(uint32_t) + key_material_length() + TAG_LENGTH +
            enforced_.SerializedSize() + unenforced_.SerializedSize();
 }

 uint8_t* KeyBlob::Serialize(uint8_t* buf, const uint8_t* end) const {
     const uint8_t* start = buf;
     buf = append_to_buf(buf, end, nonce(), NONCE_LENGTH);
     buf = append_size_and_data_to_buf(buf, end, encrypted_key_material(), key_material_length());
     buf = append_to_buf(buf, end, tag(), TAG_LENGTH);
     buf = enforced_.Serialize(buf, end);
     buf = unenforced_.Serialize(buf, end);
     assert(buf - start == static_cast<ptrdiff_t>(SerializedSize()));
     return buf;
 }

 bool KeyBlob::Deserialize(const uint8_t** buf_ptr, const uint8_t* end) {
     UniquePtr<uint8_t[]> tmp_key_ptr;
     if (!copy_from_buf(buf_ptr, end, nonce_.get(), NONCE_LENGTH) ||
         !copy_size_and_data_from_buf(buf_ptr, end, &key_material_length_, &tmp_key_ptr) ||
         !copy_from_buf(buf_ptr, end, tag_.get(), TAG_LENGTH) ||
         !enforced_.Deserialize(buf_ptr, end) || !unenforced_.Deserialize(buf_ptr, end)) {
         error_ = KM_ERROR_INVALID_KEY_BLOB;
         return false;
     }

     if (!ExtractKeyCharacteristics())
         return false;

     encrypted_key_material_.reset(tmp_key_ptr.release());
     key_material_.reset(new uint8_t[key_material_length_]);
     return true;
 }

 void KeyBlob::EncryptKey(const keymaster_key_blob_t& master_key) {
     UniquePtr<AeCtx> ctx(InitializeKeyWrappingContext(master_key, &error_));
     if (error_ != KM_ERROR_OK)
         return;

     int ae_err = ae_encrypt(ctx->get(), nonce_.get(), key_material(), key_material_length(),
                             NULL /* additional data */, 0 /* additional data length */,
                             encrypted_key_material_.get(), tag_.get(), 1 /* final */);
     if (ae_err < 0) {
         error_ = KM_ERROR_UNKNOWN_ERROR;
         return;
     }
     assert(ae_err == static_cast<int>(key_material_length_));
     error_ = KM_ERROR_OK;
 }

 void KeyBlob::DecryptKey(const keymaster_key_blob_t& master_key) {
     UniquePtr<AeCtx> ctx(InitializeKeyWrappingContext(master_key, &error_));
     if (error_ != KM_ERROR_OK)
         return;

     int ae_err =
         ae_decrypt(ctx->get(), nonce_.get(), encrypted_key_material(), key_material_length(),
                    NULL /* additional data */, 0 /* additional data length */, key_material_.get(),
                    tag_.get(), 1 /* final */);
     if (ae_err == AE_INVALID) {
         // Authentication failed!  Decryption probably succeeded(ish), but we don't want to return
         // any data when the authentication fails, so clear it.
         memset_s(key_material_.get(), 0, key_material_length());
         error_ = KM_ERROR_INVALID_KEY_BLOB;
         return;
     } else if (ae_err < 0) {
         error_ = KM_ERROR_UNKNOWN_ERROR;
         return;
     }
     assert(ae_err == static_cast<int>(key_material_length()));
     error_ = KM_ERROR_OK;
 }

 KeyBlob::AeCtx* KeyBlob::InitializeKeyWrappingContext(const keymaster_key_blob_t& master_key,
                                                       keymaster_error_t* error) const {
     size_t derivation_data_length;
     UniquePtr<const uint8_t[]> derivation_data(BuildDerivationData(&derivation_data_length));
     if (derivation_data.get() == NULL) {
         *error = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return NULL;
     }

     *error = KM_ERROR_OK;
     UniquePtr<AeCtx> ctx(new AeCtx);

     SHA256_CTX sha256_ctx;
     UniquePtr<uint8_t[]> hash_buf(new uint8_t[SHA256_DIGEST_LENGTH]);
     Eraser hash_eraser(hash_buf.get(), SHA256_DIGEST_LENGTH);
     UniquePtr<uint8_t[]> derived_key(new uint8_t[AES_BLOCK_SIZE]);
     Eraser derived_key_eraser(derived_key.get(), AES_BLOCK_SIZE);

     if (ctx.get() == NULL || hash_buf.get() == NULL || derived_key.get() == NULL) {
         *error = KM_ERROR_MEMORY_ALLOCATION_FAILED;
         return NULL;
     }

     Eraser sha256_ctx_eraser(sha256_ctx);

     // Hash derivation data.
     SHA256_Init(&sha256_ctx);
     SHA256_Update(&sha256_ctx, derivation_data.get(), derivation_data_length);
     SHA256_Final(hash_buf.get(), &sha256_ctx);

     // Encrypt hash with master key to build derived key.
     AES_KEY aes_key;
     Eraser aes_key_eraser(AES_KEY);
     if (AES_set_encrypt_key(master_key.key_material, master_key.key_material_size * 8, &aes_key) !=
         0) {
         *error = KM_ERROR_UNKNOWN_ERROR;
         return NULL;
     }
     AES_encrypt(hash_buf.get(), derived_key.get(), &aes_key);

     // Set up AES OCB context using derived key.
     if (ae_init(ctx->get(), derived_key.get(), AES_BLOCK_SIZE, NONCE_LENGTH, TAG_LENGTH) ==
         AE_SUCCESS)
         return ctx.release();
     else {
         memset_s(ctx.get(), 0, ae_ctx_sizeof());
         return NULL;
     }
 }

 const uint8_t* KeyBlob::BuildDerivationData(size_t* derivation_data_length) const {
     *derivation_data_length =
         hidden_.SerializedSize() + enforced_.SerializedSize() + unenforced_.SerializedSize();
     uint8_t* derivation_data = new uint8_t[*derivation_data_length];
     if (derivation_data != NULL) {
         uint8_t* buf = derivation_data;
         uint8_t* end = derivation_data + *derivation_data_length;
         buf = hidden_.Serialize(buf, end);
         buf = enforced_.Serialize(buf, end);
         buf = unenforced_.Serialize(buf, end);
     }
     return derivation_data;
 }

 bool KeyBlob::ExtractKeyCharacteristics() {
     if (!enforced_.GetTagValue(TAG_ALGORITHM, &algorithm_) &&
         !unenforced_.GetTagValue(TAG_ALGORITHM, &algorithm_)) {
         error_ = KM_ERROR_UNSUPPORTED_ALGORITHM;
         return false;
     }
     if (!enforced_.GetTagValue(TAG_KEY_SIZE, &key_size_bits_) &&
         !unenforced_.GetTagValue(TAG_KEY_SIZE, &key_size_bits_)) {
         error_ = KM_ERROR_UNSUPPORTED_KEY_SIZE;
         return false;
     }
     return true;
 }

 }  // namespace keymaster
	/*
	* Copyright 2014 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 <assert.h>

	#include <openssl/aes.h>
	#include <openssl/sha.h>

	#include <keymaster/google_keymaster_utils.h>
	#include <keymaster/key_blob.h>

	#include "ae.h"

	namespace keymaster {

	class KeyBlob::AeCtx {
	public:
	AeCtx() : ctx_(ae_allocate(NULL)) {}
	~AeCtx() {
	ae_clear(ctx_);
	ae_free(ctx_);
	}

	ae_ctx* get() { return ctx_; }

	private:
	ae_ctx* ctx_;
	};

	const size_t KeyBlob::NONCE_LENGTH;
	const size_t KeyBlob::TAG_LENGTH;

	KeyBlob::KeyBlob(const AuthorizationSet& enforced, const AuthorizationSet& unenforced,
	const AuthorizationSet& hidden, const keymaster_key_blob_t& key,
	const keymaster_key_blob_t& master_key, const uint8_t nonce[NONCE_LENGTH])
	: error_(KM_ERROR_OK), nonce_(new uint8_t[NONCE_LENGTH]), tag_(new uint8_t[TAG_LENGTH]),
	enforced_(enforced), unenforced_(unenforced), hidden_(hidden) {
	if (!nonce_.get() \|\| !tag_.get()) {
	error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return;
	}
	error_ = KM_ERROR_OK;

	if (enforced_.is_valid() == AuthorizationSet::ALLOCATION_FAILURE \|\|
	unenforced_.is_valid() == AuthorizationSet::ALLOCATION_FAILURE \|\|
	hidden_.is_valid() == AuthorizationSet::ALLOCATION_FAILURE) {
	error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return;
	}

	if (enforced_.is_valid() != AuthorizationSet::OK \|\|
	unenforced_.is_valid() != AuthorizationSet::OK \|\|
	hidden_.is_valid() != AuthorizationSet::OK) {
	error_ = KM_ERROR_UNKNOWN_ERROR;
	return;
	}

	if (!ExtractKeyCharacteristics())
	return;

	key_material_length_ = key.key_material_size;
	key_material_.reset(new uint8_t[key_material_length_]);
	encrypted_key_material_.reset(new uint8_t[key_material_length_]);

	if (!key_material_.get() \|\| !encrypted_key_material_.get() \|\| !nonce_.get() \|\| !tag_.get()) {
	error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return;
	}

	memcpy(nonce_.get(), nonce, NONCE_LENGTH);
	memcpy(key_material_.get(), key.key_material, key_material_length_);
	EncryptKey(master_key);
	}

	KeyBlob::KeyBlob(const keymaster_key_blob_t& key, const AuthorizationSet& hidden,
	const keymaster_key_blob_t& master_key)
	: nonce_(new uint8_t[NONCE_LENGTH]), tag_(new uint8_t[TAG_LENGTH]), hidden_(hidden) {
	if (!nonce_.get() \|\| !tag_.get()) {
	error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return;
	}
	error_ = KM_ERROR_OK;

	const uint8_t* p = key.key_material;
	if (!Deserialize(&p, key.key_material + key.key_material_size))
	return;
	DecryptKey(master_key);
	}

	KeyBlob::KeyBlob(const uint8_t* key_blob, size_t blob_size)
	: nonce_(new uint8_t[NONCE_LENGTH]), tag_(new uint8_t[TAG_LENGTH]) {
	if (!nonce_.get() \|\| !tag_.get()) {
	error_ = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return;
	}
	error_ = KM_ERROR_OK;

	if (!Deserialize(&key_blob, key_blob + blob_size))
	return;
	}

	size_t KeyBlob::SerializedSize() const {
	return NONCE_LENGTH + sizeof(uint32_t) + key_material_length() + TAG_LENGTH +
	enforced_.SerializedSize() + unenforced_.SerializedSize();
	}

	uint8_t* KeyBlob::Serialize(uint8_t* buf, const uint8_t* end) const {
	const uint8_t* start = buf;
	buf = append_to_buf(buf, end, nonce(), NONCE_LENGTH);
	buf = append_size_and_data_to_buf(buf, end, encrypted_key_material(), key_material_length());
	buf = append_to_buf(buf, end, tag(), TAG_LENGTH);
	buf = enforced_.Serialize(buf, end);
	buf = unenforced_.Serialize(buf, end);
	assert(buf - start == static_cast<ptrdiff_t>(SerializedSize()));
	return buf;
	}

	bool KeyBlob::Deserialize(const uint8_t** buf_ptr, const uint8_t* end) {
	UniquePtr<uint8_t[]> tmp_key_ptr;
	if (!copy_from_buf(buf_ptr, end, nonce_.get(), NONCE_LENGTH) \|\|
	!copy_size_and_data_from_buf(buf_ptr, end, &key_material_length_, &tmp_key_ptr) \|\|
	!copy_from_buf(buf_ptr, end, tag_.get(), TAG_LENGTH) \|\|
	!enforced_.Deserialize(buf_ptr, end) \|\| !unenforced_.Deserialize(buf_ptr, end)) {
	error_ = KM_ERROR_INVALID_KEY_BLOB;
	return false;
	}

	if (!ExtractKeyCharacteristics())
	return false;

	encrypted_key_material_.reset(tmp_key_ptr.release());
	key_material_.reset(new uint8_t[key_material_length_]);
	return true;
	}

	void KeyBlob::EncryptKey(const keymaster_key_blob_t& master_key) {
	UniquePtr<AeCtx> ctx(InitializeKeyWrappingContext(master_key, &error_));
	if (error_ != KM_ERROR_OK)
	return;

	int ae_err = ae_encrypt(ctx->get(), nonce_.get(), key_material(), key_material_length(),
	NULL /* additional data /, 0 / additional data length */,
	encrypted_key_material_.get(), tag_.get(), 1 /* final */);
	if (ae_err < 0) {
	error_ = KM_ERROR_UNKNOWN_ERROR;
	return;
	}
	assert(ae_err == static_cast<int>(key_material_length_));
	error_ = KM_ERROR_OK;
	}

	void KeyBlob::DecryptKey(const keymaster_key_blob_t& master_key) {
	UniquePtr<AeCtx> ctx(InitializeKeyWrappingContext(master_key, &error_));
	if (error_ != KM_ERROR_OK)
	return;

	int ae_err =
	ae_decrypt(ctx->get(), nonce_.get(), encrypted_key_material(), key_material_length(),
	NULL /* additional data /, 0 / additional data length */, key_material_.get(),
	tag_.get(), 1 /* final */);
	if (ae_err == AE_INVALID) {
	// Authentication failed! Decryption probably succeeded(ish), but we don't want to return
	// any data when the authentication fails, so clear it.
	memset_s(key_material_.get(), 0, key_material_length());
	error_ = KM_ERROR_INVALID_KEY_BLOB;
	return;
	} else if (ae_err < 0) {
	error_ = KM_ERROR_UNKNOWN_ERROR;
	return;
	}
	assert(ae_err == static_cast<int>(key_material_length()));
	error_ = KM_ERROR_OK;
	}

	KeyBlob::AeCtx* KeyBlob::InitializeKeyWrappingContext(const keymaster_key_blob_t& master_key,
	keymaster_error_t* error) const {
	size_t derivation_data_length;
	UniquePtr<const uint8_t[]> derivation_data(BuildDerivationData(&derivation_data_length));
	if (derivation_data.get() == NULL) {
	*error = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return NULL;
	}

	*error = KM_ERROR_OK;
	UniquePtr<AeCtx> ctx(new AeCtx);

	SHA256_CTX sha256_ctx;
	UniquePtr<uint8_t[]> hash_buf(new uint8_t[SHA256_DIGEST_LENGTH]);
	Eraser hash_eraser(hash_buf.get(), SHA256_DIGEST_LENGTH);
	UniquePtr<uint8_t[]> derived_key(new uint8_t[AES_BLOCK_SIZE]);
	Eraser derived_key_eraser(derived_key.get(), AES_BLOCK_SIZE);

	if (ctx.get() == NULL \|\| hash_buf.get() == NULL \|\| derived_key.get() == NULL) {
	*error = KM_ERROR_MEMORY_ALLOCATION_FAILED;
	return NULL;
	}

	Eraser sha256_ctx_eraser(sha256_ctx);

	// Hash derivation data.
	SHA256_Init(&sha256_ctx);
	SHA256_Update(&sha256_ctx, derivation_data.get(), derivation_data_length);
	SHA256_Final(hash_buf.get(), &sha256_ctx);

	// Encrypt hash with master key to build derived key.
	AES_KEY aes_key;
	Eraser aes_key_eraser(AES_KEY);
	if (AES_set_encrypt_key(master_key.key_material, master_key.key_material_size * 8, &aes_key) !=
	0) {
	*error = KM_ERROR_UNKNOWN_ERROR;
	return NULL;
	}
	AES_encrypt(hash_buf.get(), derived_key.get(), &aes_key);

	// Set up AES OCB context using derived key.
	if (ae_init(ctx->get(), derived_key.get(), AES_BLOCK_SIZE, NONCE_LENGTH, TAG_LENGTH) ==
	AE_SUCCESS)
	return ctx.release();
	else {
	memset_s(ctx.get(), 0, ae_ctx_sizeof());
	return NULL;
	}
	}

	const uint8_t* KeyBlob::BuildDerivationData(size_t* derivation_data_length) const {
	*derivation_data_length =
	hidden_.SerializedSize() + enforced_.SerializedSize() + unenforced_.SerializedSize();
	uint8_t* derivation_data = new uint8_t[*derivation_data_length];
	if (derivation_data != NULL) {
	uint8_t* buf = derivation_data;
	uint8_t* end = derivation_data + *derivation_data_length;
	buf = hidden_.Serialize(buf, end);
	buf = enforced_.Serialize(buf, end);
	buf = unenforced_.Serialize(buf, end);
	}
	return derivation_data;
	}

	bool KeyBlob::ExtractKeyCharacteristics() {
	if (!enforced_.GetTagValue(TAG_ALGORITHM, &algorithm_) &&
	!unenforced_.GetTagValue(TAG_ALGORITHM, &algorithm_)) {
	error_ = KM_ERROR_UNSUPPORTED_ALGORITHM;
	return false;
	}
	if (!enforced_.GetTagValue(TAG_KEY_SIZE, &key_size_bits_) &&
	!unenforced_.GetTagValue(TAG_KEY_SIZE, &key_size_bits_)) {
	error_ = KM_ERROR_UNSUPPORTED_KEY_SIZE;
	return false;
	}
	return true;
	}

	} // namespace keymaster