Systemsicherheit/Assignment 7 - SGX Hands-on/SGX101_sample_code-master/ProcessLocalAttestation/Enclave2/Enclave1/Enclave1.cpp

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// Enclave1.cpp : Defines the exported functions for the .so application
#include "sgx_eid.h"
#include "Enclave1_t.h"
#include "EnclaveMessageExchange.h"
#include "error_codes.h"
#include "Utility_E1.h"
#include "sgx_thread.h"
#include "sgx_dh.h"
#include <map>

#define UNUSED(val) (void)(val)

std::map<sgx_enclave_id_t, dh_session_t>g_src_session_info_map;

static uint32_t e1_foo1_wrapper(ms_in_msg_exchange_t *ms, size_t param_lenth, char** resp_buffer, size_t* resp_length);

//Function pointer table containing the list of functions that the enclave exposes
const struct {
    size_t num_funcs;
    const void* table[1];
} func_table = {
    1,
    {
        (const void*)e1_foo1_wrapper,
    }
};

//Makes use of the sample code function to establish a secure channel with the destination enclave (Test Vector)
uint32_t test_create_session(sgx_enclave_id_t src_enclave_id,
                         sgx_enclave_id_t dest_enclave_id)
{
    ATTESTATION_STATUS ke_status = SUCCESS;
    dh_session_t dest_session_info;

    //Core reference code function for creating a session
    ke_status = create_session(src_enclave_id, dest_enclave_id, &dest_session_info);

    return ke_status;
}

//Makes use of the sample code function to do an enclave to enclave call (Test Vector)
uint32_t test_enclave_to_enclave_call(sgx_enclave_id_t src_enclave_id,
                                          sgx_enclave_id_t dest_enclave_id)
{
    ATTESTATION_STATUS ke_status = SUCCESS;
    uint32_t var1,var2;
    uint32_t target_fn_id, msg_type;
    char* marshalled_inp_buff;
    size_t marshalled_inp_buff_len;
    char* out_buff;
    size_t out_buff_len;
    dh_session_t *dest_session_info;
    size_t max_out_buff_size;
    char* retval;

    var1 = 0x4;
    var2 = 0x5;
    target_fn_id = 0;
    msg_type = ENCLAVE_TO_ENCLAVE_CALL;
    max_out_buff_size = 50;

    //Marshals the input parameters for calling function foo1 in Enclave2 into a input buffer
    ke_status = marshal_input_parameters_e2_foo1(target_fn_id, msg_type, var1, var2, &marshalled_inp_buff, &marshalled_inp_buff_len);
    if(ke_status != SUCCESS)
    {
        return ke_status;
    }

    //Search the map for the session information associated with the destination enclave id of Enclave2 passed in
    std::map<sgx_enclave_id_t, dh_session_t>::iterator it = g_src_session_info_map.find(dest_enclave_id);
    if(it != g_src_session_info_map.end())
    {
          dest_session_info = &it->second;
    }
    else
    {
        SAFE_FREE(marshalled_inp_buff);
        return INVALID_SESSION;
    }

    //Core Reference Code function
    ke_status = send_request_receive_response(src_enclave_id, dest_enclave_id, dest_session_info, marshalled_inp_buff,
                                            marshalled_inp_buff_len, max_out_buff_size, &out_buff, &out_buff_len);


    if(ke_status != SUCCESS)
    {
        SAFE_FREE(marshalled_inp_buff);
        SAFE_FREE(out_buff);
        return ke_status;
    }

    //Un-marshal the return value and output parameters from foo1 of Enclave 2
    ke_status = unmarshal_retval_and_output_parameters_e2_foo1(out_buff, &retval);
    if(ke_status != SUCCESS)
    {
        SAFE_FREE(marshalled_inp_buff);
        SAFE_FREE(out_buff);
        return ke_status;
    }

    SAFE_FREE(marshalled_inp_buff);
    SAFE_FREE(out_buff);
    SAFE_FREE(retval);
    return SUCCESS;
}

//Makes use of the sample code function to do a generic secret message exchange (Test Vector)
uint32_t test_message_exchange(sgx_enclave_id_t src_enclave_id,
                               sgx_enclave_id_t dest_enclave_id)
{
    ATTESTATION_STATUS ke_status = SUCCESS;
    uint32_t target_fn_id, msg_type;
    char* marshalled_inp_buff;
    size_t marshalled_inp_buff_len;
    char* out_buff;
    size_t out_buff_len;
    dh_session_t *dest_session_info;
    size_t max_out_buff_size;
    char* secret_response;
    uint32_t secret_data;

    target_fn_id = 0;
    msg_type = MESSAGE_EXCHANGE;
    max_out_buff_size = 50;
    secret_data = 0x12345678; //Secret Data here is shown only for purpose of demonstration.

    //Marshals the secret data into a buffer
    ke_status = marshal_message_exchange_request(target_fn_id, msg_type, secret_data, &marshalled_inp_buff, &marshalled_inp_buff_len);
    if(ke_status != SUCCESS)
    {
        return ke_status;
    }
    //Search the map for the session information associated with the destination enclave id passed in
    std::map<sgx_enclave_id_t, dh_session_t>::iterator it = g_src_session_info_map.find(dest_enclave_id);
    if(it != g_src_session_info_map.end())
    {
         dest_session_info = &it->second;
    }
    else
    {
        SAFE_FREE(marshalled_inp_buff);
        return INVALID_SESSION;
    }

    //Core Reference Code function
    ke_status = send_request_receive_response(src_enclave_id, dest_enclave_id, dest_session_info, marshalled_inp_buff,
                                                marshalled_inp_buff_len, max_out_buff_size, &out_buff, &out_buff_len);
    if(ke_status != SUCCESS)
    {
        SAFE_FREE(marshalled_inp_buff);
        SAFE_FREE(out_buff);
        return ke_status;
    }

    //Un-marshal the secret response data
    ke_status = umarshal_message_exchange_response(out_buff, &secret_response);
    if(ke_status != SUCCESS)
    {
        SAFE_FREE(marshalled_inp_buff);
        SAFE_FREE(out_buff);
        return ke_status;
    }

    SAFE_FREE(marshalled_inp_buff);
    SAFE_FREE(out_buff);
    SAFE_FREE(secret_response);
    return SUCCESS;
}


//Makes use of the sample code function to close a current session
uint32_t test_close_session(sgx_enclave_id_t src_enclave_id,
                                sgx_enclave_id_t dest_enclave_id)
{
    dh_session_t dest_session_info;
    ATTESTATION_STATUS ke_status = SUCCESS;
    //Search the map for the session information associated with the destination enclave id passed in
    std::map<sgx_enclave_id_t, dh_session_t>::iterator it = g_src_session_info_map.find(dest_enclave_id);
    if(it != g_src_session_info_map.end())
    {
        dest_session_info = it->second;
    }
    else
    {
        return NULL;
    }

    //Core reference code function for closing a session
    ke_status = close_session(src_enclave_id, dest_enclave_id);

    //Erase the session information associated with the destination enclave id
    g_src_session_info_map.erase(dest_enclave_id);
    return ke_status;
}

//Function that is used to verify the trust of the other enclave
//Each enclave can have its own way verifying the peer enclave identity
extern "C" uint32_t verify_peer_enclave_trust(sgx_dh_session_enclave_identity_t* peer_enclave_identity)
{
    if(!peer_enclave_identity)
    {
        return INVALID_PARAMETER_ERROR;
    }
    if(peer_enclave_identity->isv_prod_id != 0 || !(peer_enclave_identity->attributes.flags & SGX_FLAGS_INITTED))
        // || peer_enclave_identity->attributes.xfrm !=3)// || peer_enclave_identity->mr_signer != xx //TODO: To be hardcoded with values to check
    {
        return ENCLAVE_TRUST_ERROR;
    }
    else
    {
        return SUCCESS;
    }
}


//Dispatcher function that calls the approriate enclave function based on the function id
//Each enclave can have its own way of dispatching the calls from other enclave
extern "C" uint32_t enclave_to_enclave_call_dispatcher(char* decrypted_data,
                                                       size_t decrypted_data_length,
                                                       char** resp_buffer,
                                                       size_t* resp_length)
{
    ms_in_msg_exchange_t *ms;
    uint32_t (*fn1)(ms_in_msg_exchange_t *ms, size_t, char**, size_t*);
    if(!decrypted_data || !resp_length)
    {
        return INVALID_PARAMETER_ERROR;
    }
    ms = (ms_in_msg_exchange_t *)decrypted_data;
    if(ms->target_fn_id >= func_table.num_funcs)
    {
        return INVALID_PARAMETER_ERROR;
    }
    fn1 = (uint32_t (*)(ms_in_msg_exchange_t*, size_t, char**, size_t*))func_table.table[ms->target_fn_id];
    return fn1(ms, decrypted_data_length, resp_buffer, resp_length);
}

//Operates on the input secret and generates the output secret
uint32_t get_message_exchange_response(uint32_t inp_secret_data)
{
    uint32_t secret_response;

    //User should use more complex encryption method to protect their secret, below is just a simple example
    secret_response = inp_secret_data & 0x11111111;

    return secret_response;

}

//Generates the response from the request message
extern "C" uint32_t message_exchange_response_generator(char* decrypted_data,
                                              char** resp_buffer,
                                              size_t* resp_length)
{
    ms_in_msg_exchange_t *ms;
    uint32_t inp_secret_data;
    uint32_t out_secret_data;
    if(!decrypted_data || !resp_length)
    {
        return INVALID_PARAMETER_ERROR;
    }
    ms = (ms_in_msg_exchange_t *)decrypted_data;

    if(umarshal_message_exchange_request(&inp_secret_data,ms) != SUCCESS)
        return ATTESTATION_ERROR;

    out_secret_data = get_message_exchange_response(inp_secret_data);

    if(marshal_message_exchange_response(resp_buffer, resp_length, out_secret_data) != SUCCESS)
        return MALLOC_ERROR;

    return SUCCESS;

}


static uint32_t e1_foo1(external_param_struct_t *p_struct_var)
{
    if(!p_struct_var)
    {
        return INVALID_PARAMETER_ERROR;
    }
    (p_struct_var->var1)++;
    (p_struct_var->var2)++;
    (p_struct_var->p_internal_struct->ivar1)++;
    (p_struct_var->p_internal_struct->ivar2)++;

    return (p_struct_var->var1 + p_struct_var->var2 + p_struct_var->p_internal_struct->ivar1 + p_struct_var->p_internal_struct->ivar2);
}

//Function which is executed on request from the source enclave
static uint32_t e1_foo1_wrapper(ms_in_msg_exchange_t *ms,
                    size_t param_lenth,
                    char** resp_buffer,
                    size_t* resp_length)
{
    UNUSED(param_lenth);

    uint32_t ret;
    size_t len_data, len_ptr_data;
    external_param_struct_t *p_struct_var;
    internal_param_struct_t internal_struct_var;

    if(!ms || !resp_length)
    {
        return INVALID_PARAMETER_ERROR;
    }

    p_struct_var = (external_param_struct_t*)malloc(sizeof(external_param_struct_t));
    if(!p_struct_var)
        return MALLOC_ERROR;

    p_struct_var->p_internal_struct = &internal_struct_var;

    if(unmarshal_input_parameters_e1_foo1(p_struct_var, ms) != SUCCESS)//can use the stack
    {
        SAFE_FREE(p_struct_var);
        return ATTESTATION_ERROR;
    }

    ret = e1_foo1(p_struct_var);

    len_data = sizeof(external_param_struct_t) - sizeof(p_struct_var->p_internal_struct);
    len_ptr_data = sizeof(internal_struct_var);

    if(marshal_retval_and_output_parameters_e1_foo1(resp_buffer, resp_length, ret, p_struct_var, len_data, len_ptr_data) != SUCCESS)
    {
        SAFE_FREE(p_struct_var);
        return MALLOC_ERROR;
    }
    SAFE_FREE(p_struct_var);
    return SUCCESS;
}