cc3000_simple_socket_demo - cc3000 simple socket demo (not using EthernetInte…

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Martin Kojtal / Mbed 2 deprecated cc3000_simple_socket_demo

cc3000 simple socket demo (not using EthernetInterface) !

Dependencies: NVIC_set_all_priorities cc3000_hostdriver_mbedsocket mbed

Info

Simple Socket demo application for the wireless CC3000 module.

Warning

The on-board Firmware must be updated to mbed enable the wireless module.
Goto the Component page to get the FirmwareUpdate tool (scroll down to the FirmwareUpdate topic).

Setup

Note

It is recommended to run an initial test WITHOUT security settings.

Changing network parameters in main.h

Setup a wireless router with a non-secure wireless connection using the wireless settings stored in main.h
or set SSID to your wireless router SSID. For now, do not change USE_SMART_CONFIG and AP_KEY,
only change AP_SECURITY to NONE.

// use smart config
#define USE_SMART_CONFIG 0

 // Default SSID Settings
#define AP_KEY       "test"
#define AP_SECURITY  NONE
#define SSID         "test"

By default, DHCP is used to obtain the IP address.
When you want to use a fixed IP address, set IP_ALLOC_METHOD USE_STATIC_IP and enter your preferred values for STATIC_IP_OCT_x (device IP address) and STATIC_GW_OCT4 (4th number of your gateway IP address) .
See the next chapter on how to use USE_SMART_CONFIG.

Setting up the Python script

Download Python 2.7 from http://www.python.org/download/
Install it on a computer connected to the router you previously set up (wireless or wired).
Download this Python script to the Python2.7 folder (credit : Jim Carver from Avnet).
Compile the CC3000_Simple_Socket_demo code and save it to your board.

Running the application for the first time

Open a terminal program (eg: TeraTerm) and connect to your board (serial speed : 115200 baud).
Press the reset button on your board.
Following startup screen will appear :

Note

The version info can be different.
the dots in the MAC address will show your CC3000's real MAC address.

cc3000 simple socket demo.
MAC address + cc3000 info
 MAC address ..:..:..:..:..:..

 FTC        0
 PP_version 3.4
 SERV_PACK  1.11
 DRV_VER    7.14.24
 FW_VER     7.12.14
User's AP setup: SSID: "test", Password: "test", Security: 3

<0> Normal run. SmartConfig will
    start if no valid connection exists.
<1> Connect using fixed SSID without AP_KEY: test
<2> Connect using fixed SSID with AP_KEY: test
<8> Erase all stored profiles.
<9> SmartConfig.

For the initial test, select option <1> (Connect using fixed SSID without AP_KEY: ...).
If all goes well, the following screen is shown (the IP address can be different):

Attempting SSID Connection.
DHCP request
  Waiting for dhcp to be set.
  Waiting for dhcp to be set.
DHCP assigned IP Address = 192.168.1.100

On the computer where you installed Python2.7:
- Make sure the connection between your computer and the wireless router is active.
- Open a DOS prompt and go to the folder where Python2.7 is installed.
- Type following command :

python wigo_test.py -a 192.168.0.101 -p 15000

Note

Don't forget to replace the IP address with the real IP address assigned by DHCP to the CC3000 module.

If a connection is established, the DOS window will show

-----------------
run tcp client
-----------------
connected to  remote ip=192.168.0.101 remote port=15000
Press ENTER ....

In return the controller board will send following info to the serial port:

Connection from: 192.168.1.101

When we press Enter in the DOS window, the controller board will send following info to the serial port:

Connection from: 192.168.0.10
Received: Hello Wi-Go
Sending the message to the server.

And the DOS window will show:

recv from :  data:  Hello Python

Using option <2>

In your wireless router, change the non-secure wireless connection to WEP, WPA or WPA2 and enter a security key.
In main.h, update AP_SECURITY and AP_KEY with the values you set in your wireless router.
Valid values for AP_SECURITY are : NONE, WEP, WPA and WPA2
Recompile the code and save it to your board. Reconnect the terminal program and press reset on your board.
When the selection menu appears, choose option <2>.
The communication sequence for option <2> is identical as described for option <1> but now a secure connection is used.

Using the application's options <0>, <8> and <9>

Options <0> (Normal run) and <9> (SmartConfig) are very similar.
They both allow us to connect the CC3000 to another wireless network, without changing the pre-configured wireless settings stored in main.h.
Option <0> will only start SmartConfig if no valid connection exists (First Time Config),
but if the CC3000 was previously configured using SmartConfig, it will automatically connect using the stored wireless network profile.
Option <8> : As there are only 7 profile slots available, this option can be used to erase all stored profiles.
Option <9> allows the user to switch to another wireless connection.
This connection is stored in one of the 7 profiles. More info on profile priorities is available here.

See TI's pages on how to use the SmartConfig tool:

Preferred method : Configuration using the SmartConfig tool
SmartConfig download: Smart Config and Home Automation
- iOS app : available at Apple app store.
- Android app : Open the Smart Config and Home Automation link and install the Android SmartConfig Application on a PC.
  This file contains the source code as well as the compiled APK file.
  The APK file is stored in ti\CC3000AndroidApp\SmartConfigCC3X\bin.
Alternate method (no longer works since firmware upgrade 1.11 - only kept as a reference):
Configuration without the SmartConfig tool
This page also contains info on the First Time Config Probe and Beacon Definition

main.cpp

Committer:: Kojto
Date:: 2014-06-03
Revision:: 15:af967b9898f8
Parent:: 14:5f84f9ae168e

File content as of revision 15:af967b9898f8:

/* mbed Microcontroller Library
 * Copyright (c) 2006-2013 ARM Limited
 *
 * 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 "mbed.h"
#include "cc3000.h"
#include "main.h"
#include "TCPSocketConnection.h"
#include "TCPSocketServer.h"

#define STRINGIFY(x) #x
#define TO_STRING(x) STRINGIFY(x)

using namespace mbed_cc3000;

tUserFS user_info;

/* cc3000 module declaration specific for user's board. Check also init() */
#if (MY_BOARD == WIGO)
cc3000 wifi(PTA16, PTA13, PTD0, SPI(PTD2, PTD3, PTC5));
Serial pc(USBTX, USBRX);
#elif (MY_BOARD == WIFI_DIPCORTEX)
cc3000 wifi(p28, p27, p30, SPI(p21, p14, p37));
Serial pc(UART_TX, UART_RX);
#elif (MY_BOARD == MBED_BOARD_EXAMPLE)
cc3000 wifi(p9, p10, p8, SPI(p5, p6, p7));
Serial pc(USBTX, USBRX);
#else

#endif

#ifndef CC3000_UNENCRYPTED_SMART_CONFIG
  const uint8_t smartconfigkey[] = {0x73,0x6d,0x61,0x72,0x74,0x63,0x6f,0x6e,0x66,0x69,0x67,0x41,0x45,0x53,0x31,0x36};
#else
  const uint8_t smartconfigkey = 0;
#endif

/**
 *  \brief Print cc3000 information
 *  \param none
 *  \return none
 */
void print_cc3000_info() {
    uint8_t myMAC[8];

    printf("MAC address + cc3000 info \r\n");
    wifi.get_user_file_info((uint8_t *)&user_info, sizeof(user_info));
    wifi.get_mac_address(myMAC);
    printf(" MAC address %02x:%02x:%02x:%02x:%02x:%02x \r\n \r\n", myMAC[0], myMAC[1], myMAC[2], myMAC[3], myMAC[4], myMAC[5]);

    printf(" FTC        %i \r\n",user_info.FTC);
    printf(" PP_version %i.%i \r\n",user_info.PP_version[0], user_info.PP_version[1]);
    printf(" SERV_PACK  %i.%i \r\n",user_info.SERV_PACK[0], user_info.SERV_PACK[1]);
    printf(" DRV_VER    %i.%i.%i \r\n",user_info.DRV_VER[0], user_info.DRV_VER[1], user_info.DRV_VER[2]);
    printf(" FW_VER     %i.%i.%i \r\n",user_info.FW_VER[0], user_info.FW_VER[1], user_info.FW_VER[2]);
}

/**
 *  \brief Connect to SSID with a timeout
 *  \param ssid     Name of SSID
 *  \param key      Password
 *  \param sec_mode Security mode
 *  \return none
 */
void connect_to_ssid(char *ssid, char *key, unsigned char sec_mode) {
    printf("Connecting to SSID: %s. Timeout is 10s. \r\n",ssid);
    if (wifi.connect_to_AP((uint8_t *)ssid, (uint8_t *)key, sec_mode) == true) {
        printf(" Connected. \r\n");
    } else {
        printf(" Connection timed-out (error). Please restart. \r\n");
        while(1);
  }
}

/**
 *  \brief Connect to SSID without security
 *  \param ssid Name of SSID
 *  \return none
 */
void connect_to_ssid(char *ssid) {
    wifi.connect_open((uint8_t *)ssid);
}

/**
 *  \brief First time configuration
 *  \param none
 *  \return none
 */
void do_FTC(void) {
    printf("Running First Time Configuration \r\n");
    wifi.start_smart_config(smartconfigkey);
    while (wifi.is_dhcp_configured() == false) {
         wait_ms(500);
         printf("Waiting for dhcp to be set. \r\n");
    }
    user_info.FTC = 1;
    wifi.set_user_file_info((uint8_t *)&user_info, sizeof(user_info));
    wifi._wlan.stop();
    printf("FTC finished. \r\n");
}

/**
 *  \brief Start smart config
 *  \param none
 *  \return none
 */
void start_smart_config() {
    wifi.start_smart_config(smartconfigkey);
}

/**
 *  \brief Simple socket demo
 *  \param none
 *  \return int
 */
int main() {
    init(); /* board dependent init */
    pc.baud(115200);

    wifi.start(0);
    printf("cc3000 simple socket demo. \r\n");
    print_cc3000_info();

    printf("User's AP setup: SSID: %s, Password: %s, Security: %s \r\n", TO_STRING(SSID), TO_STRING(AP_KEY), TO_STRING(AP_SECURITY));

    printf("\n<0> Normal run. SmartConfig will \r\n    start if no valid connection exists. \r\n");
    printf("<1> Connect using fixed SSID without AP_KEY: %s \r\n", SSID);
    printf("<2> Connect using fixed SSID with AP_KEY: %s \r\n", SSID);
    printf("<8> Erase all stored profiles.\r\n");
    printf("<9> SmartConfig. \r\n");

    signed char c = getchar();
    switch (c)
    {
        case '0':
            if (!user_info.FTC) {
                do_FTC();
                wifi._wlan.stop();
            } else {
                wifi._wlan.ioctl_set_connection_policy(0, 1, 1);
            }
            break;
        case '1':
            printf("Attempting SSID Connection. \r\n");

            wifi._wlan.ioctl_set_connection_policy(0, 0, 0);
            connect_to_ssid(SSID);
            break;
        case '2':
            printf("Attempting SSID Connection. \r\n");

            wifi._wlan.ioctl_set_connection_policy(0, 0, 0);
#ifndef CC3000_TINY_DRIVER
            connect_to_ssid(SSID, AP_KEY, AP_SECURITY);
#else
            connect_to_ssid(SSID);
#endif
            break;
        case '8':
            printf("Erasing all wireless profiles. \r\n");
            wifi.delete_profiles();
            wifi.stop();
            printf("Done - press the reset button on your board... \r\n");
            while(1);

        case '9':
            printf("Starting Smart Config configuration. \r\n");
            if (!user_info.FTC) {
                printf("First Time Configuration was not run. \r\nSwitching to First Time Configuration. \r\n");
                do_FTC();
                wifi._wlan.stop();
            } else {
                start_smart_config();
            }
            while (wifi.is_dhcp_configured() == false)
            {
                wait_ms(500);
                printf("Waiting for dhcp to be set. \r\n");
            }
            printf("Press the reset button on your board and select 0... \r\n");
            while(1);
        default:
            printf("Wrong selection. \r\n");
            printf("Reset the board and try again. \r\n");
            break;
    }

    printf("DHCP request \r\n");
    while (wifi.is_dhcp_configured() == false) {
         wait_ms(500);
         printf("  Waiting for dhcp to be set. \r\n");
    }

    tNetappIpconfigRetArgs ipinfo2;
    wifi.get_ip_config(&ipinfo2); // data is returned in the ipinfo2 structure
    printf("DHCP assigned IP Address = %d.%d.%d.%d \r\n", ipinfo2.aucIP[3], ipinfo2.aucIP[2], ipinfo2.aucIP[1], ipinfo2.aucIP[0]);

    char python_msg[] = "Hello Python\n";
    TCPSocketServer server;
    TCPSocketConnection client;

    server.bind(15000);
    server.listen();

    while (1) {
        int32_t status = server.accept(client);
        if (status >= 0) {
            client.set_blocking(false, 1500); // Timeout after (1.5)s
            printf("Connection from: %s \r\n", client.get_address());
            char buffer[256];
            int stat = client.receive(buffer, sizeof(buffer));
            if (stat >=0) {
                printf("Received: %s \r\n",buffer);
                printf("Sending the message to the server. \r\n");
                client.send_all(python_msg, sizeof(python_msg));
                client.close();
            }
        }
    }
}