SolderSplash
WiFi DipCortex USB CDC
Dependencies: HTTPClient NTPClient USBDevice WebSocketClient cc3000_hostdriver_mbedsocket mbed
Fork of
WiFiDip-UsbKitchenSink
by 
Carl - SolderSplash Labs
http://www.soldersplash.co.uk/products/wifi-dipcortex/
Demo shows you how to implement the CC3000 library with the WiFi DipCortex.
The demo shows :
- USB CDC ( Serial ) Menu system allow control of the module and starting each example
- Smart Connect
- Manual connect
- Connection status
- Ping
- TCP Client
- TCP Server
- Web Socket read/write to sockets.mbed.org
- HTTP Client test Post, Put, Delete
- Posting ADC data to Xively every 1 second
- UDP Client
- UDP Server
- NTP Example, contacts time server to get the current time
You will need a Driver for the USB CDC port which can be found here : http://www.soldersplash.co.uk/docs/DipCortex-USB-CDC.zip
Please refer to : http://mbed.org/users/SolderSplashLabs/notebook/dipcortex---getting-started-with-mbed/ as well as the SolderSplash Forum for support http://forum.soldersplash.co.uk/viewforum.php?f=15
main.cpp
- Committer:
- SolderSplashLabs
- Date:
- 2013-11-12
- Revision:
- 2:8f5776c287c5
- Parent:
- 0:0bce3a738bcb
- Child:
- 3:15828ac052f1
File content as of revision 2:8f5776c287c5:
#include "mbed.h"
#include "cc3000.h"
#include "wifi.h"
#include "UDPSocket.h"
#include "tcpTests.h"
#include "main.h"
#include "USBSerial.h"
#include "NTPClient.h"
#include <time.h>
using namespace mbed_cc3000;
/* cc3000 module declaration specific for user's board. Check also init() */
#if (MY_BOARD == WIGO)
cc3000 wifi(PTA16, PTA13, PTD0, SPI(PTD2, PTD3, PTC5), PORTA_IRQn);
#elif (MY_BOARD == WIFI_DIPCORTEX)
cc3000 wifi(p28, p27, p30, SPI(p21, p14, p37));
Serial uart(p19, p20);
USBSerial pc; // USB CDC serial port
#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
const int ECHO_SERVER_PORT_UDP = 81;
uint8_t *HostToPing = (uint8_t *)"google.com";
tNetappIpconfigRetArgs ipinfo;
extern char tmpBuffer[512];
MENU_LEVEL currentMenu = MENU_TOP;
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Resolve a hostname and ping it
*/
// ------------------------------------------------------------------------------------------------------------
void PingTest ( void )
{
uint32_t ip;
int32_t resolveRetCode = 0;
pc.printf("Get an IP address for %s\r\n",HostToPing);
resolveRetCode = wifi._socket.gethostbyname(HostToPing,strlen((const char *)HostToPing), &ip);
pc.printf("gethostbyname Returned code : %i \r\n", resolveRetCode);
if (resolveRetCode > -1)
{
uint8_t add0 = (ip >> 24);
uint8_t add1 = (ip >> 16);
uint8_t add2 = (ip >> 8);
uint8_t add3 = (ip >> 0);
pc.printf("IP address of %s: %d.%d.%d.%d \r\n", HostToPing, add0, add1, add2, add3);
pc.printf("Sending ping\r\n");
uint32_t reply_count = wifi.ping(ip, 5, 500, 32);
pc.printf("Received %d replies\r\n", reply_count);
pc.printf("Ping complete.\r\n");
}
else
{
pc.printf("Failed to resolve\r\n");
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Test the NTP library
*/
// ------------------------------------------------------------------------------------------------------------
void NtpTest ( void )
{
NTPClient ntp;
struct tm *currentTime;
if (ntp.setTime("0.pool.ntp.org",123,10000) == 0)
{
pc.printf("\r\nGot the time successfully\r\n");
currentTime = localtime(&ntp.NTPLastResult);
pc.printf("NTP Response : %s\r\n", asctime(currentTime));
}
else
{
pc.printf("NTP Update Failed\r\n");
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Send a UDP Packet, wait for response
*/
// ------------------------------------------------------------------------------------------------------------
void UdpClientTest ( void )
{
UDPSocket socket;
int n = 0;
Endpoint outEndpoint;
Endpoint inEndpoint;
if (0 == socket.bind(ECHO_SERVER_PORT_UDP) )
{
// 2 second timeout
socket.set_blocking(false, 2000);
pc.printf("\r\n!! Press any key to stop !!\r\n\r\n");
while (1)
{
if( outEndpoint.set_address(ECHO_SERVER_ADDRESS, ECHO_SERVER_PORT_UDP) < 0 )
{
pc.printf("Failed to set endpoint address.\r\n");
break;
}
else
{
if ( socket.sendTo( outEndpoint, hello, sizeof(hello) ) < 0 )
{
pc.printf("Failed to send the packet.\r\n");
}
else
{
// Message sent, recv reply
pc.printf("UDP Socket Sent : %s \r\n", hello);
n = socket.receiveFrom( inEndpoint, tmpBuffer, sizeof(tmpBuffer) );
if ( n < 0 )
{
pc.printf("Failed to recv the UDP packet.\r\n");
}
else
{
tmpBuffer[n] = '\0';
pc.printf("UDP Socket Recv'd : %s \r\n", tmpBuffer);
}
}
}
// Should we stop?
if ( pc.readable() )
{
pc.getc();
break;
}
}
if ( wifi.is_connected() )
{
socket.close();
}
}
else
{
// Failed to bind to the socket
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Listen on a UDP port for messages
*/
// ------------------------------------------------------------------------------------------------------------
void UdpServerTest ( void )
{
UDPSocket socket;
Endpoint client;
int n = 0;
if (0 == socket.bind(ECHO_SERVER_PORT_UDP) )
{
pc.printf("\r\n!! Press any key to stop listening !!\r\n\r\n");
while (true)
{
pc.printf("Waiting for packet...\r\n");
n = socket.receiveFrom(client, tmpBuffer, sizeof(tmpBuffer));
pc.printf("Received packet from: %s\n", client.get_address());
socket.sendTo(client, tmpBuffer, n);
// Should we stop?
if ( pc.readable() )
{
pc.getc();
break;
}
}
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Print menu header
*/
// ------------------------------------------------------------------------------------------------------------
void Menu_PrintHeader ( void )
{
if (( wifi.is_enabled() ) && ( wifi.is_dhcp_configured() ))
{
wifi.get_ip_config(&ipinfo);
}
pc.printf("\r\n");
pc.printf("+-------------------------------------------+\r\n");
pc.printf("| WiFi DipCortex / CC3000 Kitchen Sink |\r\n");
pc.printf("+-------------------------------------------+\r\n");
if (! wifi.is_enabled() )
{
pc.printf("| CC3000 Disabled |\r\n");
}
else if ( wifi.is_dhcp_configured() )
{
pc.printf("| SSID : %-33s|\r\n", ipinfo.uaSSID);
pc.printf("| IP : %-35s|\r\n", wifi.getIPAddress());
}
else if ( wifi.is_connected() )
{
pc.printf("| Connecting, waiting for DHCP |\r\n");
}
else
{
pc.printf("| Not Connected |\r\n");
}
pc.printf("+-------------------------------------------+\r\n");
pc.printf("\r\n");
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Control the wifi connection
*/
// ------------------------------------------------------------------------------------------------------------
char WaitForSerialCommand ( void )
{
char charIn = 0;
char prevCharIn;
pc.printf("Enter command character : ");
while (1)
{
prevCharIn = charIn;
charIn = pc.getc();
pc.printf("%c", charIn);
if ((charIn == '\n') || (charIn == '\r'))
{
break;
}
}
return ( prevCharIn );
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Configure the module for smart connect mode allow configuration over the air
*/
// ------------------------------------------------------------------------------------------------------------
void SmartConfig ( void )
{
pc.printf("\r\nStarting Smart config, waiting for message from smartphone app ....\r\n");
// We dont want to auto reconnect to an access point
wifi._wlan.ioctl_set_connection_policy(0, 0, 0);
// start smart config will disconnect, set the prefix
// wait for a message via a SmartConfig app, store it to the profile list
// finally it will reenable auto connection, triggering the module to connect to the new access point
wifi.start_smart_config(0);
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Print cc3000 information
*/
// ------------------------------------------------------------------------------------------------------------
void print_cc3000_info() {
uint8_t myMAC[8];
uint8_t buffer[2];
int32_t status = 0;
tNetappIpconfigRetArgs ipinfo2;
tUserFS cc_user_info;
const char * WIFI_STATUS[] = {"Disconnected", "Scanning", "Connecting", "Connected"};
wifi.get_user_file_info((uint8_t *)&cc_user_info, sizeof(cc_user_info));
wifi.get_mac_address(myMAC);
pc.printf(" MAC address : %02x:%02x:%02x:%02x:%02x:%02x\r\n", myMAC[0], myMAC[1], myMAC[2], myMAC[3], myMAC[4], myMAC[5]);
if (! wifi._nvmem.read_sp_version( (unsigned char*)&buffer ) )
{
pc.printf(" CC3000 Firmware Version : %u.%u \r\n", buffer[0], buffer[1]);
}
else
{
pc.printf(" CC3000 Read nvmem failed!");
}
status = wifi._wlan.ioctl_statusget();
if (( status > -1 ) && ( status < 4 ))
{
pc.printf(" Wifi Status : %s\r\n", WIFI_STATUS[status]);
}
else
{
pc.printf(" Wifi Status : %d\r\n", status);
}
if ( wifi.is_dhcp_configured() )
{
wifi.get_ip_config(&ipinfo2);
pc.printf(" Connected to : %s \r\n", ipinfo2.uaSSID);
pc.printf(" IP : %d.%d.%d.%d \r\n", ipinfo2.aucIP[3], ipinfo2.aucIP[2], ipinfo2.aucIP[1], ipinfo2.aucIP[0]);
pc.printf(" Gateway : %d.%d.%d.%d \r\n", ipinfo2.aucDefaultGateway[3], ipinfo2.aucDefaultGateway[2], ipinfo2.aucDefaultGateway[1], ipinfo2.aucDefaultGateway[0]);
pc.printf(" Subnet : %d.%d.%d.%d \r\n", ipinfo2.aucSubnetMask[3], ipinfo2.aucSubnetMask[2], ipinfo2.aucSubnetMask[1], ipinfo2.aucSubnetMask[0]);
pc.printf(" DNS : %d.%d.%d.%d \r\n", ipinfo2.aucDNSServer[3], ipinfo2.aucDNSServer[2], ipinfo2.aucDNSServer[1], ipinfo2.aucDNSServer[0]);
pc.printf(" Cached IP : %s \r\n", wifi.getIPAddress());
pc.printf(" Cached Gateway : %s \r\n", wifi.getGateway());
pc.printf(" Cached Subnet : %s \r\n", wifi.getNetworkMask());
}
else
{
pc.printf(" Not connected \r\n");
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Control the wifi connection
*/
// ------------------------------------------------------------------------------------------------------------
void Menu_ConnectionControl ( void )
{
uint32_t ip = 0;
Menu_PrintHeader();
pc.printf(" 1 - Enable auto connect to any previous access point\r\n");
pc.printf(" 2 - Disable auto connect \r\n");
pc.printf(" 3 - Connect to %s \r\n", SSID);
pc.printf(" 4 - Disconnect \r\n");
pc.printf(" 5 - Start SmartConfig \r\n");
pc.printf(" 6 - Erase profiles \r\n");
pc.printf(" 7 - Get Status \r\n");
pc.printf(" x - Top Menu \r\n");
pc.printf("\r\n");
switch(WaitForSerialCommand())
{
case '1':
wifi._wlan.ioctl_set_connection_policy(0, 0, 1);
break;
case '2':
wifi._wlan.ioctl_set_connection_policy(0, 0, 0);
break;
case '3':
//wifi.start(0);
// Enable DHCP
wifi._netapp.dhcp(&ip, &ip, &ip, &ip);
if ( AP_SECURITY == NONE )
{
wifi.connect_non_blocking((uint8_t *)SSID, 0, AP_SECURITY);
}
else
{
pc.printf("\r\n Connecting to : %s key : %s", SSID, AP_KEY );
wifi.connect_non_blocking((uint8_t *)SSID, (uint8_t *)AP_KEY, AP_SECURITY);
}
break;
case '4' :
// Stop the module re-connecting
wifi._wlan.ioctl_set_connection_policy(0, 0, 0);
// Then disconnect
wifi.disconnect();
break;
case '5' :
SmartConfig();
break;
case '6' :
wifi._wlan.ioctl_del_profile(255);
break;
case '7' :
print_cc3000_info();
break;
case '8':
//wifi._spi.manualIrqCheck();
break;
case 'x':
currentMenu = MENU_TOP;
break;
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief
*/
// ------------------------------------------------------------------------------------------------------------
void Menu_UdpControl ( void )
{
Menu_PrintHeader();
pc.printf(" 1 - UDP Client, Connect to %s:%d\r\n", ECHO_SERVER_ADDRESS, ECHO_SERVER_PORT_UDP);
pc.printf(" 2 - UDP Server \r\n");
pc.printf(" 3 - NTP Client \r\n");
pc.printf(" x - Exit to top menu \r\n");
pc.printf("\r\n");
switch(WaitForSerialCommand())
{
case '1':
UdpClientTest();
break;
case '2':
UdpServerTest();
break;
case '3':
NtpTest();
break;
case '0':
case 'x':
currentMenu = MENU_TOP;
break;
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief
*/
// ------------------------------------------------------------------------------------------------------------
void Menu_TcpControl ( void )
{
Menu_PrintHeader();
pc.printf(" 1 - TCP Client, Connect to %s:%d\r\n", ECHO_SERVER_ADDRESS, ECHO_SERVER_PORT_TCP);
pc.printf(" 2 - TCP Server, listen on %d.%d.%d.%d:%d\r\n", ipinfo.aucIP[3], ipinfo.aucIP[2], ipinfo.aucIP[1], ipinfo.aucIP[0], ECHO_SERVER_PORT_TCP);
pc.printf(" 3 - Web Socket Write \r\n");
pc.printf(" 4 - Web Socket Read \r\n");
pc.printf(" 5 - HTTP Client \r\n");
pc.printf(" 6 - Xively Post ADC's \r\n");
pc.printf(" x - Exit to top menu ");
pc.printf("\r\n");
switch(WaitForSerialCommand())
{
case '1':
TcpClientTest();
break;
case '2':
TcpServerTest();
break;
case '3':
WebSocketTest();
break;
case '4':
WebSocketReadTest();
break;
case '5':
HttpClientTest();
break;
case '6':
XivelySimpleTest();
break;
case '0':
case 'x':
currentMenu = MENU_TOP;
break;
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Display a menu to the user
*/
// ------------------------------------------------------------------------------------------------------------
void Menu_Top ( void )
{
Menu_PrintHeader();
pc.printf(" 1 - Connection control menu \r\n" );
pc.printf(" 2 - TCP test menu \r\n" );
pc.printf(" 3 - UDP test menu \r\n" );
pc.printf(" 4 - Connection status \r\n");
pc.printf(" 5 - Ping - %s \r\n", HostToPing);
pc.printf(" x - Top Menu \r\n");
pc.printf("\r\n");
switch(WaitForSerialCommand())
{
case '1':
currentMenu = MENU_CONNECTION;
break;
case '2':
currentMenu = MENU_TCP;
break;
case '3':
currentMenu = MENU_UDP;
break;
case '4':
print_cc3000_info();
break;
case '5':
PingTest();
break;
case 'x':
currentMenu = MENU_TOP;
break;
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Pick which menu to display
*/
// ------------------------------------------------------------------------------------------------------------
void MenuSwitch ( void )
{
bool connected = false;
if ( wifi.is_dhcp_configured() )
{
connected = true;
}
switch ( currentMenu )
{
case MENU_TOP :
Menu_Top();
break;
case MENU_CONNECTION :
Menu_ConnectionControl();
break;
case MENU_TCP :
if (connected)
{
Menu_TcpControl();
}
else
{
currentMenu = MENU_TOP;
}
break;
case MENU_UDP :
if (connected)
{
Menu_UdpControl();
}
else
{
currentMenu = MENU_TOP;
}
break;
default :
pc.printf("Unknown command\r\n");
break;
}
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief Init
*/
// ------------------------------------------------------------------------------------------------------------
void init()
{
NVIC_SetPriority(SSP1_IRQn, 0x0);
NVIC_SetPriority(PIN_INT0_IRQn, 0x1);
// SysTick set to lower priority than Wi-Fi SPI bus interrupt
NVIC_SetPriority(SysTick_IRQn, 0x2);
}
// ------------------------------------------------------------------------------------------------------------
/*!
@brief main loop
*/
// ------------------------------------------------------------------------------------------------------------
int main( void )
{
// Initalise the WiFi Module
init();
uart.baud(SERIAL_BAUD_RATE);
wait(1);
wifi.start(0);
wait_ms(750);
while (1)
{
MenuSwitch();
}
}