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- /*
- * Copyright (C) 2011-2017 Intel Corporation. All rights reserved.
- *
- * Redistribution and use in source and binary forms, with or without
- * modification, are permitted provided that the following conditions
- * are met:
- *
- * * Redistributions of source code must retain the above copyright
- * notice, this list of conditions and the following disclaimer.
- * * Redistributions in binary form must reproduce the above copyright
- * notice, this list of conditions and the following disclaimer in
- * the documentation and/or other materials provided with the
- * distribution.
- * * Neither the name of Intel Corporation nor the names of its
- * contributors may be used to endorse or promote products derived
- * from this software without specific prior written permission.
- *
- * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
- * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
- * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
- * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
- * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
- * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
- * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
- * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
- * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
- * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
- * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
- *
- */
- // Enclave2.cpp : Defines the exported functions for the DLL application
- #include "sgx_eid.h"
- #include "sgx_tcrypto.h"
- #include "Decryptor_t.h"
- #include "EnclaveMessageExchange.h"
- #include "error_codes.h"
- #include "sgx_thread.h"
- #include "sgx_dh.h"
- #include <map>
- #include "sgx_tcrypto.h"
- #include "LocalAttestationCode_t.h"
- #include "sgx_tseal.h"
- #include "Openssl_crypto.h"
- //extern dh_session_t global_session_info;
- uint8_t apache_iv[12] = {0,0,0,0, 0,0,0,0, 0,0,0,0};
- uint8_t client_iv[12] = {0,0,0,0, 0,0,0,0, 0,0,0,0};
- uint8_t verifier_iv[12] = {0,0,0,0, 0,0,0,0, 0,0,0,0};
- extern uint8_t apache_key[16];
- extern uint8_t verifier_key[16];
- //uint32_t client_iv=0;
- // internal-internal
- uint32_t create_ec_key_pair(sgx_ec256_public_t* pub_key, sgx_ec256_private_t* priv_key);
- void serialize_key_pair_to_string( sgx_ec256_public_t* pub_key, sgx_ec256_private_t* signing_priv_key, uint8_t* private_public_key_string);
- void deserialize_string_to_key_pair(uint8_t* private_public_key_string, sgx_ec256_public_t* pub_key, sgx_ec256_private_t* priv_key);
- uint32_t create_mitigator_header_value(__attribute__((unused)) uint8_t* signature_data, __attribute__((unused)) uint8_t* signature, __attribute__((unused)) uint8_t* private_key, __attribute__((unused)) sgx_ec256_signature_t* sig2);
- uint32_t aes_gcm_192_call(uint32_t enc, uint8_t* ip_key, uint8_t* ip_iv, uint8_t* ip_ciphertext, uint32_t ip_ciphertext_len, uint8_t* op_plaintext, uint32_t* op_plaintext_length, uint8_t* tag);
- //uint32_t aes_gcm_internal_call(uint32_t enc, uint8_t* ip_ciphertext, uint32_t ip_ciphertext_len, uint8_t* ip_key, uint8_t* ip_iv, uint8_t* op_plaintext, uint8_t* tag);
- void memcpy_equivalent_copy(uint8_t* dest, uint8_t* src, uint32_t length);
- uint32_t verify_mitigator_header_value(uint8_t* signature_data, uint8_t* signature, sgx_ec256_public_t* pub_key);
- uint32_t calculate_sealed_data_size( uint32_t input_size) ;
- uint32_t create_and_seal_ecdsa_signing_key_pair(__attribute__((unused)) sgx_ec256_public_t* pub_key, __attribute__((unused)) uint32_t* sealed_data_length, __attribute__((unused)) uint8_t* sealed_data);
- uint32_t unseal_and_restore_sealed_signing_key_pair(__attribute__((unused)) sgx_ec256_public_t* pub_key, uint8_t* sealed_data, size_t* sgx_sealed_data_length);
- uint32_t decrypt_verifiers_message_set_apache_mrsigner(uint8_t* ciphertext, uint8_t* tag);
- uint32_t create_and_encrypt_mitigator_header_value(uint8_t* plaintext_sign_data_and_sign, uint8_t* encrypted_sign_data_and_sign, uint8_t* tag, uint8_t* signing_private_key, __attribute__((unused)) sgx_ec256_signature_t* sig2);
- //static void reverse_byte_array(uint8_t *array, size_t size);
- uint32_t one_la_done=0;
- static sgx_ec256_public_t short_term_pub_key;
- static sgx_ec256_private_t short_term_priv_key;
- unsigned char short_term_private_key_arr[32];
- unsigned char short_term_public_key_arr[64];
- //sgx_ec256_signature_t generated_signature; // TODO: remove
- sgx_measurement_t apache_mr_signer; // TODO: remove
- sgx_measurement_t verifier_mr_enclave; // TODO: remove
- static sgx_ec256_private_t signing_priv_key;
- extern "C" uint32_t verify_peer_enclave_trust(__attribute__((unused)) sgx_dh_session_enclave_identity_t* peer_enclave_identity)
- {
- uint32_t count;
- if(!peer_enclave_identity)
- {
- return INVALID_PARAMETER_ERROR;
- }
- if(one_la_done==0)
- {
- // return 0x55;
- //sgx_measurement_t local_mr_enclave;
- verifier_mr_enclave = peer_enclave_identity->mr_enclave;
- memset(&(apache_mr_signer.m),0x0,SGX_HASH_SIZE); // "initialization"
- one_la_done=1;
- }
- else // apache enclave
- {
- sgx_measurement_t actual_mr_signer = peer_enclave_identity->mr_signer;
- // verifier's mrsigner
- // uint8_t expected_mr_signer[32] ={0xdf, 0xd7, 0x3b, 0x93, 0xea, 0x39, 0x02, 0x02, 0x3c, 0xd0, 0x52, 0x1a, 0xbd, 0x00, 0xaf, 0xb9, 0xa6, 0x54, 0x57, 0x3e, 0xe5, 0xef, 0x36, 0xf4, 0x8c, 0xc2, 0x4d, 0x92, 0x70, 0xae, 0xd4, 0x7c};
- int count;
- for(count=0; count<SGX_HASH_SIZE; count++)
- {
- if( actual_mr_signer.m[count] != apache_mr_signer.m[count] )
- return ENCLAVE_TRUST_ERROR;
- }
- }
- return SGX_SUCCESS;
- }
- // increments last 4 bytes (in big-endian order)
- uint32_t aes_gcm_increment_iv_internal_call(uint8_t* iv)
- {
- uint32_t counter;
- for(counter=11;counter>7;counter--)
- {
- if(iv[counter] == 0xff)
- {
- if(counter - 1 == 7)
- return 0xff;
- iv[counter-1] = 0x01;
- iv[counter] = 0x0;
- }
- else
- iv[counter] += 1;
- }
- return 0;
- }
- // TODO: change global_session_info to two different dh_sessions
- // This needs to be called after the first local attestation is successful - otherwise, the internal apache_mr_signer.m will not be set properly for the comparison of the mrsigner for the 2nd LA in verify_peer_enclave_trust.
- // (I.e. if it is not called then DoS
- uint32_t decrypt_verifiers_message_set_apache_mrsigner(uint8_t* ciphertext, uint8_t* tag)
- {
- uint32_t length;
- uint32_t internal_ret_status= aes_gcm_192_call(0, verifier_key, verifier_iv, ciphertext, 32, (uint8_t*) &(apache_mr_signer.m), &length, tag);
- return internal_ret_status;
- }
- // signature_data - 96 bytes, encrypted_signature assumed to be at least 64 bytes, tag - at least 16 bytes
- uint32_t create_and_encrypt_mitigator_header_value(uint8_t* plaintext_sign_data_and_sign, uint8_t* encrypted_sign_data_and_sign, uint8_t* tag, uint8_t* signing_private_key, __attribute__((unused)) sgx_ec256_signature_t* sig2)
- {
- uint32_t count; uint32_t length;
- uint8_t sign_data_and_sign[160];
- uint32_t ret_status=create_mitigator_header_value(sign_data_and_sign, sign_data_and_sign+96, signing_private_key, sig2);
- if(ret_status != SGX_SUCCESS)
- return 0xFFFFFFDD;
- // TODO: Remove - just for troubleshooting
- for(count=0; count<160; count++)
- *(plaintext_sign_data_and_sign+count)=sign_data_and_sign[count];
- ret_status = aes_gcm_192_call(1, apache_key, apache_iv, sign_data_and_sign, 160, encrypted_sign_data_and_sign, &length, tag);
- // ret_status = encrypt_internal(sign_data_and_sign, 160, tag, encrypted_sign_data_and_sign);
- aes_gcm_increment_iv_internal_call(apache_iv);
- return ret_status;
- }
- uint32_t create_ec_key_pair(sgx_ec256_public_t* pub_key, sgx_ec256_private_t* priv_key)
- {
- sgx_status_t se_ret; sgx_status_t se_ret2;
- //create ECC context
- sgx_ecc_state_handle_t ecc_state = NULL;
- se_ret = sgx_ecc256_open_context(&ecc_state);
- if(SGX_SUCCESS != se_ret)
- return se_ret;
- // generate private key and public key
- se_ret = sgx_ecc256_create_key_pair(priv_key, pub_key, ecc_state);
- se_ret2 = sgx_ecc256_close_context(ecc_state);
- if(SGX_SUCCESS != se_ret || se_ret2!= SGX_SUCCESS) // something weird has happened - couldn't shut it down.
- return 0xFFFFFFFF;
- return SGX_SUCCESS;
- }
- // todo: set to private
- // todo: assumes that the length of the keystring is at least 3*SGX_ECP256_KEY_SIZE
- void serialize_key_pair_to_string(sgx_ec256_public_t* pub_key, sgx_ec256_private_t* signing_priv_key, uint8_t* private_public_key_string)
- {
- if(private_public_key_string != NULL) // nowhere to serialize to
- {
- uint32_t counter;
- if(pub_key != NULL) // public key to serialize
- {
- for(counter=0;counter<SGX_ECP256_KEY_SIZE; counter++)
- *(private_public_key_string+counter)=pub_key->gx[counter];
- for(counter=SGX_ECP256_KEY_SIZE;counter<2*SGX_ECP256_KEY_SIZE; counter++)
- *(private_public_key_string+counter)=pub_key->gy[counter-SGX_ECP256_KEY_SIZE];
- }
- if(signing_priv_key != NULL) // private key to serialize
- {
- for(counter=2*SGX_ECP256_KEY_SIZE;counter<3*SGX_ECP256_KEY_SIZE; counter++)
- *(private_public_key_string+counter)=signing_priv_key->r[counter - 2*SGX_ECP256_KEY_SIZE];
- }
- }
- }
- // todo: set to private
- void deserialize_string_to_key_pair(uint8_t* private_public_key_string, sgx_ec256_public_t* pub_key, sgx_ec256_private_t* signing_priv_key)
- {
- if(private_public_key_string != NULL) // nowhere to deserialize from
- {
- uint32_t counter;
- if(signing_priv_key != NULL)
- {
- for(counter=2*SGX_ECP256_KEY_SIZE;counter<3*SGX_ECP256_KEY_SIZE; counter++)
- signing_priv_key->r[counter-2*SGX_ECP256_KEY_SIZE]=*(private_public_key_string+counter);
- }
- if(pub_key != NULL)
- {
- for(counter=0;counter<SGX_ECP256_KEY_SIZE; counter++)
- pub_key->gx[counter]=*(private_public_key_string+counter);
- for(counter=SGX_ECP256_KEY_SIZE;counter<2*SGX_ECP256_KEY_SIZE; counter++)
- pub_key->gy[counter-SGX_ECP256_KEY_SIZE]=*(private_public_key_string+counter);
- }
- }
- }
- uint32_t create_and_seal_ecdsa_signing_key_pair(__attribute__((unused)) sgx_ec256_public_t* pub_key, __attribute__((unused)) uint32_t* sealed_data_length,
- __attribute__((unused)) uint8_t* sealed_data)
- {
- uint32_t ret_status; sgx_ec256_private_t private_key; uint32_t counter;
- ret_status=create_ec_key_pair(pub_key, &private_key);
- if(ret_status!=SGX_SUCCESS)
- return ret_status;
- for(counter=0;counter<SGX_ECP256_KEY_SIZE; counter++)
- signing_priv_key.r[counter]=private_key.r[counter];
- // generating the entire string as there is no SGX function to generate the public key from the private one.
- uint8_t* private_public_key_string = (uint8_t*) malloc(3*SGX_ECP256_KEY_SIZE);
- uint8_t* sealed_data2 = (uint8_t*) malloc(*sealed_data_length);
- // serializing keypair to string
- serialize_key_pair_to_string(pub_key, &private_key, private_public_key_string);
- uint8_t* private_key_string = (uint8_t*) malloc(SGX_ECP256_KEY_SIZE);
- for(counter=0;counter<SGX_ECP256_KEY_SIZE;counter++)
- *(private_key_string+counter)=private_key.r[counter];
- // return *sealed_data_length;
- ret_status = sgx_seal_data(0, NULL, 3*SGX_ECP256_KEY_SIZE, private_public_key_string, *sealed_data_length, (sgx_sealed_data_t*) sealed_data2);
- for(counter=0;counter<*sealed_data_length;counter++)
- *(sealed_data+counter)=*(sealed_data2+counter);
- free(sealed_data2);
- free(private_key_string); //free(private_key);
- free(private_public_key_string);
- return ret_status; // SGX_SUCCESS;
- }
- uint32_t unseal_and_restore_sealed_signing_key_pair(__attribute__((unused)) sgx_ec256_public_t* pub_key, uint8_t* sealed_data, size_t* sgx_sealed_data_length)
- {
- uint32_t expected_plaintext_msg_length; uint8_t* temp_plaintext; uint32_t counter; uint32_t ret_status;
- expected_plaintext_msg_length = sgx_get_encrypt_txt_len((sgx_sealed_data_t*)sealed_data);
- if(expected_plaintext_msg_length == 0xffffffff)
- return 0xFFFFFFFF;
- uint8_t* sealed_data2 = (uint8_t*) malloc(*sgx_sealed_data_length);
- for(counter=0;counter<*sgx_sealed_data_length;counter++)
- {
- *(sealed_data2+counter)=*(sealed_data+counter);
- }
- temp_plaintext = (uint8_t*)malloc( expected_plaintext_msg_length );
- ret_status = sgx_unseal_data((sgx_sealed_data_t*)sealed_data2, NULL, 0, temp_plaintext, &expected_plaintext_msg_length);
- if(ret_status != SGX_SUCCESS)
- {
- free(temp_plaintext);free(sealed_data2);
- return ret_status;
- }
- deserialize_string_to_key_pair(temp_plaintext, pub_key, &signing_priv_key);
- free(temp_plaintext); free(sealed_data2);
- return SGX_SUCCESS;
- }
- uint32_t create_mitigator_header_value(__attribute__((unused)) uint8_t* signature_data, __attribute__((unused)) uint8_t* signature, __attribute__((unused)) uint8_t* private_key, __attribute__((unused)) sgx_ec256_signature_t* sig2)
- {
- // Otherwise: DoS or possible bypass (fake verifier does LA but real verifier mrenclave is given out by decryptor) - signature with junk verifier mrenclave or whatever is in the memory.
- if(one_la_done < 1)
- return 0xde; // This needs to be called at any point after the first local attestation is done - else, a junk verifier mrenclave will be included in the signature
- // create key pair
- uint32_t ret_status = ecdh_key_gen(short_term_public_key_arr, short_term_public_key_arr + 32, short_term_private_key_arr); //create_ec_key_pair(&short_term_pub_key, &short_term_priv_key);
- uint32_t counter;
- uint32_t ret_status2;
- if(ret_status!=0)
- return ret_status;
- for(counter=0;counter<32;counter++)
- {
- *(signature_data + counter) = short_term_public_key_arr[counter]; // public key -> x component
- *(signature_data + counter + 32) = short_term_public_key_arr[counter + 32]; // public key -> y component
- *(signature_data + counter + 64) = 0x55; // verifier mr_enclave // TODO: fix this.
- }
- // retrieve long-term private key from global variable - apparently, need to create a local copy or it crashes
- sgx_ec256_private_t long_term_priv_key;
- for(counter=0; counter<SGX_ECP256_KEY_SIZE; counter++)
- long_term_priv_key.r[counter] = signing_priv_key.r[counter];
- // sign public key with long-term private key
- sgx_ec256_signature_t local_signature; sgx_ecc_state_handle_t ecc_handle;
- // TODO: For testing/checking purposes only.
- for(counter=0;counter<32;counter++)
- *(private_key+counter)=short_term_private_key_arr[counter]; //short_term_priv_key.r[counter];
- //// opening context for signature
- ret_status = sgx_ecc256_open_context(&ecc_handle);
- if(ret_status != SGX_SUCCESS)
- return ret_status;
- ret_status = sgx_ecdsa_sign(signature_data, 96, &long_term_priv_key, &local_signature, ecc_handle);
- ret_status2 = sgx_ecc256_close_context(ecc_handle);
- // free(public_key_string);
- if(ret_status == SGX_SUCCESS)
- { // this only works for Little-endian architectures - need to do byte-wise swapping of the bytes obtained on RHS
- uint8_t *current_sig_byte = (uint8_t*)(&(local_signature.x));
- uint32_t ecdsa_sig_count;
- for(ecdsa_sig_count=0;ecdsa_sig_count<32;ecdsa_sig_count++)
- signature[31-ecdsa_sig_count]=*(current_sig_byte+ecdsa_sig_count);
- current_sig_byte = (uint8_t*)(&(local_signature.y));
- for(ecdsa_sig_count=0;ecdsa_sig_count<32;ecdsa_sig_count++)
- signature[63-ecdsa_sig_count]=*(current_sig_byte+ecdsa_sig_count);
- for(ecdsa_sig_count=0;ecdsa_sig_count<8;ecdsa_sig_count++)
- sig2->x[ecdsa_sig_count]=local_signature.x[ecdsa_sig_count];
- for(ecdsa_sig_count=0;ecdsa_sig_count<8;ecdsa_sig_count++)
- sig2->y[ecdsa_sig_count]=local_signature.y[ecdsa_sig_count];
- }
- if(ret_status != SGX_SUCCESS || ret_status2 != SGX_SUCCESS)
- return 0xFFFFFFFF;
- return 0;
- }
- uint32_t verify_mitigator_header_value(uint8_t* signature_data, uint8_t* signature, sgx_ec256_public_t* pub_key)
- {
- sgx_ec256_public_t local_pub_key; uint32_t counter; uint32_t ret_status; uint32_t ret_status2;
- for(counter=0;counter<SGX_ECP256_KEY_SIZE;counter++)
- {
- local_pub_key.gx[counter] = pub_key->gx[counter];
- local_pub_key.gy[counter] = pub_key->gy[counter];
- }
- sgx_ec256_signature_t local_signature; sgx_ecc_state_handle_t ecc_handle;
- uint8_t *current_sig_byte = (uint8_t*)(&(local_signature.x));
- uint32_t ecdsa_sig_count; uint8_t verification_result;
- for(ecdsa_sig_count=0;ecdsa_sig_count<32;ecdsa_sig_count++)
- *(current_sig_byte+ecdsa_sig_count)=signature[ecdsa_sig_count];
- current_sig_byte = (uint8_t*)(&(local_signature.y));
- for(ecdsa_sig_count=0;ecdsa_sig_count<32;ecdsa_sig_count++)
- *(current_sig_byte+ecdsa_sig_count)=signature[ecdsa_sig_count+32];
- //// opening context for signature
- ret_status = sgx_ecc256_open_context(&ecc_handle);
- if(ret_status != SGX_SUCCESS)
- return ret_status;
- ret_status = sgx_ecdsa_verify(signature_data,3*SGX_ECP256_KEY_SIZE, &local_pub_key, &local_signature, &verification_result, ecc_handle);
- ret_status2 = sgx_ecc256_close_context(ecc_handle);
- if(ret_status != SGX_SUCCESS || ret_status2 != SGX_SUCCESS)
- return 0xFFFFFFFF;
- if(verification_result != SGX_EC_VALID)
- return 0xee;
- return 0;
- }
- uint32_t derive_shared_secret_for_client(uint8_t* pub_key, uint8_t* shared_key)
- {
- return 0;
- }
- uint32_t calculate_sealed_data_size( uint32_t input_size)
- {
- // *op_size=sgx_calc_sealed_data_size(0, input_size);
- return sgx_calc_sealed_data_size(0, input_size);
- }
- // ip_key will always be within the enclave.
- // enc = 1 for encryption and 0 for decryption, like openssl api
- // TODO: Rename this - it's actually 128 bit encryption.
- uint32_t aes_gcm_192_call(uint32_t enc, uint8_t* ip_key, uint8_t* ip_iv, uint8_t* ip_ciphertext, uint32_t ip_ciphertext_len, uint8_t* op_plaintext, uint32_t* op_plaintext_length, uint8_t* tag)
- {
- uint32_t counter;
- if(ip_ciphertext == NULL)
- return 0x33;
- if(tag == NULL)
- return 0x34;
- if(op_plaintext == NULL)
- return 0x36;
- if(ip_key == NULL)
- return 0x35;
- if(ip_iv == NULL)
- return 0x37;
- uint8_t* ip_ciphertext_in_enclave = (uint8_t*) malloc(ip_ciphertext_len);
- memcpy_equivalent_copy(ip_ciphertext_in_enclave, ip_ciphertext, ip_ciphertext_len);
- uint8_t tag_in_enclave [16];
- if(!enc)
- memcpy_equivalent_copy(tag_in_enclave, tag, 16);
- uint8_t* op_plaintext_in_enclave = (uint8_t*) malloc(ip_ciphertext_len);
- uint32_t internal_ret_status;
- if(enc)
- internal_ret_status = sgx_rijndael128GCM_encrypt((sgx_key_128bit_t*) ip_key, ip_ciphertext_in_enclave, ip_ciphertext_len, op_plaintext_in_enclave, ip_iv, 0xc, NULL, 0, (sgx_aes_gcm_128bit_tag_t*)tag_in_enclave);
- else
- internal_ret_status = sgx_rijndael128GCM_decrypt((sgx_key_128bit_t*) ip_key, ip_ciphertext_in_enclave, ip_ciphertext_len, op_plaintext_in_enclave, ip_iv, 0xc, NULL, 0, (sgx_aes_gcm_128bit_tag_t*)tag_in_enclave);
- if(internal_ret_status == 0)
- {
- memcpy_equivalent_copy(op_plaintext, op_plaintext_in_enclave, ip_ciphertext_len);
- if(enc)
- memcpy_equivalent_copy(tag, tag_in_enclave, 16);
- *op_plaintext_length = ip_ciphertext_len;
- }
- free(ip_ciphertext_in_enclave); free(op_plaintext_in_enclave);
- return internal_ret_status;
- }
- void memcpy_equivalent_copy(uint8_t* dest, uint8_t* src, uint32_t length)
- {
- uint32_t counter;
- for(counter=0; counter<length; counter++)
- *(dest + counter) = *(src + counter);
- }
- // Output buffer should be of length at least equal to the second argument.
- uint32_t decrypt_client_data(unsigned char* ip_encrypted_client_pub_key_and_data, uint32_t ip_encrypted_client_pub_key_and_data_length, unsigned char* op_client_data, uint8_t* clen)
- {
- unsigned int counter; unsigned long check_ret; uint32_t ret;
- unsigned char derived_key[32];
- unsigned char* plaintext_client_public_key;
- unsigned char* plaintext_client_data;
- unsigned char* client_data_encrypted_to_decryptor;
- uint32_t client_data_encrypted_to_decryptor_length;
- unsigned char* tag_for_client_data_encrypted_to_decryptor;
- unsigned char* client_data_encrypted_to_apache;
- uint32_t client_data_encrypted_to_apache_length;
- unsigned char tag_for_client_data_encrypted_to_apache[16];
- unsigned char* temp_array;
- uint32_t temp_array_valid_length;
- unsigned char client_iv[12]={0,0,0,0, 0,0,0,0, 0,0,0,0};
- for(counter=64;counter<ip_encrypted_client_pub_key_and_data_length;counter++)
- op_client_data[counter]=ip_encrypted_client_pub_key_and_data[counter];
- *clen = (uint8_t) ip_encrypted_client_pub_key_and_data_length;
- temp_array = (unsigned char*) malloc(ip_encrypted_client_pub_key_and_data_length);
- /*
- // TODO: Remove aes_gcm_internal_call function - upgrade to using openssl's aesgcm 192 bit enc
- // TODO: Change the returned 2nd length o/p to be incoming length - tag length for decryption and incoming length + 16 for encryption
- ret = aes_gcm_192_call(0, apache_key, apache_iv, ip_encrypted_client_pub_key_and_data, ip_encrypted_client_pub_key_and_data_length, temp_array, &temp_array_valid_length, ip_encrypted_client_pub_key_and_data + ip_encrypted_client_pub_key_and_data_length - 16);
- if(ret != 0)
- {
- free(temp_array);
- return ret;
- }
-
- for(counter=0; counter<temp_array_valid_length; counter++)
- op_client_data[counter] = temp_array[counter];
- *clen = temp_array_valid_length;
- free(temp_array);
- return 0;
- */
- // Temp_array = {X component of public key (32 bytes), Y component of public key (32 bytes), client data encrypted to decryptor (x), tag for client data encrypted to decryptor (16 bytes)
- // therefore, length x = temp_array_valid_length - 64 (for public key) - 16 (for own tag)
- plaintext_client_public_key = ip_encrypted_client_pub_key_and_data; // temp_array;
- client_data_encrypted_to_decryptor = ip_encrypted_client_pub_key_and_data + 64;
- client_data_encrypted_to_decryptor_length = ip_encrypted_client_pub_key_and_data_length; // temp_array_valid_length - 64 - 16;
- tag_for_client_data_encrypted_to_decryptor = ip_encrypted_client_pub_key_and_data + 64 + ip_encrypted_client_pub_key_and_data_length; //temp_array + 64 + client_data_encrypted_to_decryptor_length;
- check_ret = compute_ecdh_shared_key(plaintext_client_public_key, plaintext_client_public_key + 32, short_term_private_key_arr, derived_key);
- if(check_ret != 0)
- {
- plaintext_client_public_key = NULL;
- client_data_encrypted_to_decryptor = NULL;
- tag_for_client_data_encrypted_to_decryptor = NULL;
- free(temp_array);
- return check_ret;
- }
- /*
- check_ret = aes_gcm(0, derived_key, client_iv, client_data_encrypted_to_decryptor, client_data_encrypted_to_decryptor_length, temp_array, &temp_array_valid_length, tag_for_client_data_encrypted_to_decryptor);
- if(check_ret != 0)
- {
- plaintext_client_public_key = NULL;
- client_data_encrypted_to_decryptor = NULL;
- tag_for_client_data_encrypted_to_decryptor = NULL;
- free(temp_array);
- return check_ret;
- }
- */
- for(counter=0;counter<32;counter++)
- op_client_data[counter]=derived_key[counter];
- // for(counter=0; counter<temp_array_valid_length; counter++)
- // op_client_data[counter] = temp_array[counter];
- // for(counter=0; counter<16; counter++)
- // op_client_data[temp_array_valid_length + counter] = tag_for_client_data_encrypted_to_decryptor[counter];
- // *clen = temp_array_valid_length + 16;
- *clen = 32;
- return 0;
- /*
- // Temp_array = {X component of public key (32 bytes), Y component of public key (32 bytes), client data encrypted to decryptor (x), tag for client data encrypted to decryptor (16 bytes)
- // therefore, length x = temp_array_valid_length - 64 (for public key) - 16 (for own tag)
- plaintext_client_public_key = temp_array;
- client_data_encrypted_to_decryptor = temp_array + 64;
- client_data_encrypted_to_decryptor_length = temp_array_valid_length - 64 - 16;
- tag_for_client_data_encrypted_to_decryptor = temp_array + 64 + client_data_encrypted_to_decryptor_length;
- check_ret = compute_ecdh_shared_key(plaintext_client_public_key, plaintext_client_public_key + 32, short_term_private_key_arr, derived_key);
- if(check_ret != 0)
- {
- plaintext_client_public_key = NULL;
- client_data_encrypted_to_decryptor = NULL;
- tag_for_client_data_encrypted_to_decryptor = NULL;
- free(temp_array);
- return check_ret;
- }
- check_ret = aes_gcm(0, derived_key, client_iv, client_data_encrypted_to_decryptor, client_data_encrypted_to_decryptor_length, temp_array, &temp_array_valid_length, tag_for_client_data_encrypted_to_decryptor);
- if(check_ret != 0)
- {
- plaintext_client_public_key = NULL;
- client_data_encrypted_to_decryptor = NULL;
- tag_for_client_data_encrypted_to_decryptor = NULL;
- free(temp_array);
- return check_ret;
- }
- client_data_encrypted_to_apache = (uint8_t*) malloc(temp_array_valid_length);
- ret = aes_gcm_192_call(1, apache_key, apache_iv, temp_array, temp_array_valid_length, client_data_encrypted_to_apache, &client_data_encrypted_to_apache_length, tag_for_client_data_encrypted_to_apache);
- if(ret == 0)
- {
- for(counter=0; counter<client_data_encrypted_to_apache_length; counter++)
- op_client_data[counter] = client_data_encrypted_to_apache[counter];
- for(counter=0; counter<16; counter++) // TODO: This overwrites the first 16 bytes of the array written in the line above (WTF is going on)
- op_client_data[counter] = tag_for_client_data_encrypted_to_apache[counter];
- *clen = (uint8_t) client_data_encrypted_to_apache_length + 16; // Need to give in the total wire length
- }
- plaintext_client_public_key = NULL;
- client_data_encrypted_to_decryptor = NULL;
- tag_for_client_data_encrypted_to_decryptor = NULL;
- free(temp_array);
- free(client_data_encrypted_to_apache);
- return ret;
- */
- }
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