void checkpoint_sync::encode(data_buffer & buffer)
{
    buffer.write_var_int(m_message.size());
    buffer.write_bytes(
        reinterpret_cast<char *>(&m_message[0]), m_message.size()
    );
    
    buffer.write_var_int(m_signature.size());
    buffer.write_bytes(
        reinterpret_cast<char *>(&m_signature[0]), m_signature.size()
    );
}
Exemple #2
0
void key_wallet::encode(data_buffer & buffer)
{
    /**
     * Write the version.
     */
    buffer.write_uint32(constants::version_client);
    
    /**
     * Write the private key length.
     */
    buffer.write_var_int(m_key_private.size());
    
    /**
     * Write the private key.
     */
    if (m_key_private.size() > 0)
    {
        buffer.write_bytes(
            reinterpret_cast<const char *>(&m_key_private[0]),
            m_key_private.size()
        );
    }
    
    /**
     * Write the time created.
     */
    buffer.write_int64(m_time_created);
    
    /**
     * Write the time expires.
     */
    buffer.write_int64(m_time_expires);
    
    /**
     * Write the comment length.
     */
    buffer.write_var_int(m_comment.size());
    
    /**
     * Write the comment.
     */
    if (m_comment.size() > 0)
    {
        buffer.write_bytes(m_comment.data(), m_comment.size());
    }
}
Exemple #3
0
void transaction::encode(
    data_buffer & buffer, const bool & encode_version
    ) const
{
    if (encode_version)
    {
        /**
         * Write the version.
         */
        buffer.write_uint32(m_version);
    }
    
    /**
     * Write the time.
     */
    buffer.write_uint32(m_time);
    
    /**
     * Write the m_transactions_in size.
     */
    buffer.write_var_int(m_transactions_in.size());
    
    for (auto & i : m_transactions_in)
    {
        i.encode(buffer);
    }
    
    /**
     * Write the m_transactions_out size.
     */
    buffer.write_var_int(m_transactions_out.size());
    
    for (auto & i : m_transactions_out)
    {
        i.encode(buffer);
    }
    
    /**
     * Write the time lock.
     */
    buffer.write_uint32(m_time_lock);
}
void merkle_tree_partial::encode(data_buffer & buffer)
{
    buffer.write_uint32(m_total_transactions);
    buffer.write_var_int(m_hashes.size());
    
    for (auto & i : m_hashes)
    {
        buffer.write_sha256(i);
    }
    
    std::vector<std::uint8_t> bytes;
    
    bytes.resize((m_flags.size() + 7) / 8);
    
    for (auto i = 0; i < m_flags.size(); i++)
    {
        bytes[i / 8] |= m_flags[i] << (i % 8);
    }
    
    buffer.write_var_int(bytes.size());
    buffer.write_bytes(
        reinterpret_cast<const char *> (&bytes[0]), bytes.size()
    );
}
Exemple #5
0
bool incentive_vote::sign(data_buffer & buffer)
{
    auto ret = false;
    
    /**
     * Calculate the hash of the nonce hash.
     */
    auto digest = hash::sha256d(
        m_hash_nonce.digest(), sha256::digest_length
    );

    /**
     * Hash the encoded message buffer.
     */
    sha256 hash_value = sha256::from_digest(&digest[0]);
    
    if (incentive::instance().sign(hash_value, m_signature) == true)
    {
        /**
         * Write the signature length.
         */
        buffer.write_var_int(m_signature.size());
        
        /**
         * Write the signature.
         */
        buffer.write_bytes(
            reinterpret_cast<char *>(&m_signature[0]),
            m_signature.size()
        );

        log_debug(
            "Incentive vote signed value (" <<
            hash_value.to_string().substr(0, 8) << ")."
        );
        
        ret = true;
    }
    else
    {
        log_error("Incentive vote failed to sign value.");
    }
    
    return ret;
}
void incentive_answer::encode(data_buffer & buffer, const bool & is_copy )
{
    /**
     * Encode the version.
     */
    buffer.write_uint32(m_version);

    /**
     * Encode the public key.
     */
    m_public_key.encode(buffer);

    /**
     * Encode the transaction_in.
     */
    m_transaction_in.encode(buffer);

    /**
     * If we are encoding a copy reuse the existing signature.
     */
    if (is_copy == true)
    {
        /**
         * Write the signature length.
         */
        buffer.write_var_int(m_signature.size());
        
        /**
         * Write the signature.
         */
        buffer.write_bytes(
            reinterpret_cast<char *>(&m_signature[0]),
            m_signature.size()
        );
    }
    else
    {
        /**
         * Sign the message.
         */
        sign(buffer);
    }
}
void zerotime_question::encode(data_buffer & buffer)
{
    /**
     * Encode the version.
     */
    buffer.write_uint32(m_version);
    
    /** 
     * Encode the transaction inputs length.
     */
    buffer.write_var_int(m_transactions_in.size());
    
    for (auto & i : m_transactions_in)
    {
        /**
         * Encode the transaction_in.
         */
        i.encode(buffer);
    }
}
bool incentive_answer::sign(data_buffer & buffer)
{
    auto ret = false;
    
    /**
     * Hash the encoded message buffer.
     */
    sha256 hash_value = m_public_key.get_hash();
    
    if (incentive::instance().sign(hash_value, m_signature) == true)
    {
        /**
         * Write the signature length.
         */
        buffer.write_var_int(m_signature.size());
        
        /**
         * Write the signature.
         */
        buffer.write_bytes(
            reinterpret_cast<char *>(&m_signature[0]),
            m_signature.size()
        );

        log_debug(
            "Incentive answer signed value (" <<
            hash_value.to_string().substr(0, 8) << ")."
        );
        
        ret = true;
    }
    else
    {
        log_error("Incentive answer failed to sign value.");
    }
    
    return ret;
}
void transaction_out::encode(data_buffer & buffer) const
{
    /**
     * Write the value.
     */
    buffer.write_int64(m_value);
    
    /**
     * Write the m_script_public_key size var_int.
     */
    buffer.write_var_int(m_script_public_key.size());
    
    if (m_script_public_key.size() > 0)
    {
        /**
         * Write the m_script_public_key.
         */
        buffer.write_bytes(
            reinterpret_cast<const char *> (&m_script_public_key[0]),
            m_script_public_key.size()
        );
    }
}
void incentive_collaterals::encode(data_buffer & buffer)
{
    /**
     * Encode the version.
     */
    buffer.write_uint32(m_version);
    
    /**
     * Write the number of collateral entries.
     */
    buffer.write_var_int(m_collaterals.size());
    
    /**
     * Write the collateral entries.
     */
     for (auto & i : m_collaterals)
     {
        /**
         * Write the address.
         */
        buffer.write_network_address(i.addr, false);
        
        /**
         * Write the size of the wallet address.
         */
        buffer.write_var_int(i.wallet_address.size());
        
        /**
         * Write the wallet address.
         */
        buffer.write_bytes(i.wallet_address.data(), i.wallet_address.size());
        
        auto public_key = i.public_key;
        
        /**
         * Write the public key.
         */
        public_key.encode(buffer);
        
        /**
         * Write the transaction_in.
         */
        i.tx_in.encode(buffer);
        
        /**
         * Write the time.
         */
        buffer.write_uint64(i.time);
        
        /**
         * Write the protocol version.
         */
        buffer.write_uint32(i.protocol_version);
        
        /**
         * Write the protocol user agent.
         */
        buffer.write_var_int(i.protocol_version_user_agent.size());
        
        /**
         * Write the protocol version user agent.
         */
        buffer.write_bytes(
            i.protocol_version_user_agent.data(),
            i.protocol_version_user_agent.size()
        );
        
        /**
         * Write the protocol version services.
         */
        buffer.write_uint64(i.protocol_version_services);
        
        /**
         * Write the protocol version start height.
         */
        buffer.write_int32(i.protocol_version_start_height);
     }
}
Exemple #11
0
void incentive_vote::encode(data_buffer & buffer, const bool & is_copy)
{
    /**
     * Write the version.
     */
    buffer.write_uint32(m_version);
    
    /**
     * Write the block height.
     */
    buffer.write_uint32(m_block_height);
    
    /**
     * Write the block hash
     */
    buffer.write_sha256(m_hash_block);
    
    /**
     * Write the nonce hash.
     */
    buffer.write_sha256(m_hash_nonce);
    
    /**
     * Write the address length.
     */
    buffer.write_var_int(m_address.size());
    
    /**
     * Write the address.
     */
    buffer.write_bytes(m_address.data(), m_address.size());

    /**
     * Encode the public key.
     */
    m_public_key.encode(buffer);

    /**
     * If we are encoding a copy reuse the existing signature.
     */
    if (is_copy == true)
    {
        /**
         * Write the signature length.
         */
        buffer.write_var_int(m_signature.size());
        
        /**
         * Write the signature.
         */
        buffer.write_bytes(
            reinterpret_cast<char *>(&m_signature[0]),
            m_signature.size()
        );
    }
    else
    {
        /**
         * Sign the message.
         */
        sign(buffer);
    }
}
Exemple #12
0
void transaction_wallet::encode(data_buffer & buffer)
{
    auto is_spent = false;

    m_values["fromaccount"] = m_from_account;

    std::string str;
    
    for (auto & i : m_spent)
    {
        str += (i ? '1' : '0');
        
        if (i)
        {
            is_spent = true;
        }
    }
    
    m_values["spent"] = str;

    wallet::write_order_position(m_order_position, m_values);

    if (m_time_smart)
    {
        m_values["timesmart"] = std::to_string(m_time_smart);
    }
    
    /**
     * Encode the base class.
     */
    transaction_merkle::encode(buffer);
    
    buffer.write_var_int(m_previous_transactions.size());
    
    for (auto & i : m_previous_transactions)
    {
        i.encode(buffer);
    }
    
    /**
     * If we are an (SPV) client set the block height as a value.
     */
    if (globals::instance().is_client_spv() == true)
    {
        auto block_height = spv_block_height();
        
        m_values["spv_block_height"] = std::to_string(block_height);
    }
    
    buffer.write_var_int(m_values.size());
    
    for (auto & i : m_values)
    {
        buffer.write_var_int(i.first.size());
        buffer.write_bytes(i.first.data(), i.first.size());
        buffer.write_var_int(i.second.size());
        buffer.write_bytes(i.second.data(), i.second.size());
    }
    
    buffer.write_var_int(m_order_form.size());
    
    for (auto & i : m_order_form)
    {
        buffer.write_var_int(i.first.size());
        buffer.write_bytes(i.first.data(), i.first.size());
        buffer.write_var_int(i.second.size());
        buffer.write_bytes(i.second.data(), i.second.size());
    }
    
    buffer.write_uint32(m_time_received_is_tx_time);
    buffer.write_uint32(m_time_received);
    buffer.write_uint8(m_is_from_me);
    buffer.write_uint8(is_spent);

    m_values.erase("fromaccount");
    m_values.erase("version");
    m_values.erase("spent");
    m_values.erase("n");
    m_values.erase("timesmart");
}