Example of AWS IoT connection and Web Dashboard thru STM32 Nucleo evaluation board and mbed OS.
Dependencies: X_NUCLEO_IKS01A1 mbed FP MQTTPacket DnsQuery ATParser
Introduction
The demo is aimed to STM32 Nucleo board with WiFi and sensors expansions. The board is a "thing" for the AWS IoT service. It updates IoT service shadow with sensors data every second and checks subscription messages.
Hardware Configuration
- NUCLEO-F401RE - Nucleo Development Board
- X-NUCLEO-IDW01M1 - Wi-Fi expansion board for STM32 Nucleo
- X-NUCLEO-IKS01A1 - Motion MEMS and environmental sensor expansion board for STM32 Nucleo
Software Configuration
- Import this Project to mbed online compiler
- Find the next part of code in main.cpp file ...
WiFi network credential
#include "mbed.h" // WiFi network credential #define SSID "" // Network must be visible otherwise it can't connect #define PASSW "" #error "Wifi SSID & password empty"
- ... And set it to your Network Name and Password. Do not forget to remove "#error" pragma line.
Information
Nucleo WiFi module is not the same as your smartphone or laptope - it is based on demo board. To avoid connection problems:
- Place Nucleo as close to WiFi hot spot as possible. Or...
- Turn on mobile hot spot in your laptop as close to the device as possible.
- Make sure that hot spot permits 2.4 GHz band communications
- Setup BackEnd and store certificates using this backend setup instruction
- Find AWS_IOT_MQTT_HOST define and change it to HTTPS point mentioned in your AWS IoT thing properties named "interact"
#define AWS_IOT_MQTT_HOST "xxxxxxxxxx.iot.us-east-1.amazonaws.com" //Use your own host.
- Find the certificate defines clientCRT and clientKey in main.cpp file and change it to ones provided by Amazon.
/********************************************************************************************** *********************************************************************************************** Device Identity Certificates: Modify for your AWS IoT Thing *********************************************************************************************** ***********************************************************************************************/ /**************************************** (somecode)-certificate.pem.crt - Amazon signed PEM sertificate. *****************************************/ //This Client cert is example. Use own instead. const uint8_t clientCRT[] = "\ -----BEGIN CERTIFICATE-----\n\ MIIDBjCCAe6gAwIBAgIUVph856omeIxW3UPioq+UrX1DbwowDQYJKoZIhvcNAQEL\ BQAwTTFLMEkGA1UECwxCQW1hem9uIFdlYiBTZXJ2aWNlcyBPPUFtYXpvbi5jb20g\ SW5jLiBMPVNlYXR0bGUgU1Q9V2FzaGluZ3RvbiBDPVVTMB4XDTE3MDUyNTExNTEy\ OVoXDTQ5MTIzMTIzNTk1OVowgZUxCzAJBgNVBAYTAkJZMQ4wDAYDVQQIDAVNaW5z\ azEOMAwGA1UEBwwFTWluc2sxFzAVBgNVBAoMDktsaWthLVRlY2ggTExDMRcwFQYD\ VQQLDA5LbGlrYS1UZWNoIExMQzEMMAoGA1UEAwwDUm5EMSYwJAYJKoZIhvcNAQkB\ FhdtdmF0YWxldUBrbGlrYS10ZWNoLmNvbTBZMBMGByqGSM49AgEGCCqGSM49AwEH\ A0IABCJgOQJmoTBJVPfli9Hm/JVixaxkY5rtlgrYO3hSl633A2hg0P/ue0wXDbF3\ aQ0X57IRFE4k4FEbr3UXjT/IczKjYDBeMB8GA1UdIwQYMBaAFK3YzTUPlYB2Li75\ i/z8rEogr1d6MB0GA1UdDgQWBBT18HXBaXFJuAR/0SwegnxJ+pyJ6TAMBgNVHRMB\ Af8EAjAAMA4GA1UdDwEB/wQEAwIHgDANBgkqhkiG9w0BAQsFAAOCAQEAb0Ux1aH5\ RLxjrfGqXN6rPVqh8QQRS+AyBfzmaQN8HaPZMkX5WxXLvcn0A3uWlwQxPPkcZ4zf\ 51GHtFFQWB4YZ8dx8mUQ0v/j7onHjCJgZ8iDgwOyKMGtnsDZWCakQw+a6cj+NrMZ\ tzhjwCzEEP6ePcbXwErI5OOzLuWns2L/JEr2wWNkokgRuS8ewr/SQ9OLWIWa2rFM\ ahPNTb3y/qBeWdjeJmhI+TOxdqIpsF8roWP25zwo/zkzCHCjXFBrL+0CA4MpxIl9\ x02i7aAhlJ6ys80lDxdeWeeQJXRKkGknP8mcmKn3iEqqJ5s1dQePj2b5d3ldatya\ wsxQBqqZXzIWEw==\ \n\ -----END CERTIFICATE-----\n"; /********************************************************************************************** *********************************************************************************************** Private Key: Modify for your AWS IoT Thing *********************************************************************************************** ***********************************************************************************************/ /********************************************************************8**************************************** nucleo.key.pem - client key generated according to readme. **************************************************************************************************************/ //This Client Key is example. Use own instead. const uint8_t clientKey[] ="\ -----BEGIN EC PARAMETERS-----\n\ BggqhkjOPQMBBw==\ -----END EC PARAMETERS-----\n\ -----BEGIN EC PRIVATE KEY-----\n\ MHcCAQEEIHPRfWSC8/k/BsqDWKuP15dXsI9fGwpkTIsLZe6mIrAAoAoGCCqGSM49\ AwEHoUQDQgAEImA5AmahMElU9+WL0eb8lWLFrGRjmu2WCtg7eFKXrfcDaGDQ/+57\ TBcNsXdpDRfnshEUTiTgURuvdReNP8hzMg==\ -----END EC PRIVATE KEY-----\n";
Build and Check
- Plugin your board to USB of your PC. USB Disk Drive and USB COM Port should appear in your system.
- Open any Serial Console, connect it to your USB Serial Port and setup speed equal to 115200.
- Compile this Project and save .bin file to USB Disk Drive
- After board reset you should see next log in serial console:
X-NUCLEO-IDW01M1 mbed Application connecting to AP LOG: int main() L#361 Connected to WiFI. LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#186 ===================================== LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#187 Connecting WiFi. LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#188 Nucleo IP ADDRESS: X.X.X.X LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#189 Nucleo MAC ADDRESS: 00:11:22:33:44:55 LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#190 Server Hostname: xxxxxxxx.iot.us-east-1.amazonaws.com port: 8883 LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#191 Client ID: Nucleo LOG: int connect(MQTT::Client<MQTTWiFi, Countdown, 350, 5> *, MQTTWiFi *) L#194 ===================================== LOG: int MQTTSocket::getNTPtime(int) L#58 Success receiving time from ntp server. Tick from 1 Jan 1970 is equal to 1505399292. --->TCP Connected --->MQTT Connected --->>>MQTT subscribed to: Nucleo/test Length - 245, Publishing {"state": {"reported": {"temperature": 23.690001, "humidity": 98.190002, "pressure": 982.869141, "accelerometer": [-0.009000, 0.030000, 0.971000], "gyroscope": [0.420000, -2.660000, 1.750000], "magnetometer": [-3.600000, -7.100000, 53.300000]}}} Length - 245, Publishing {"state": {"reported": {"temperature": 23.660000, "humidity": 98.010002, "pressure": 982.770264, "accelerometer": [-0.009000, 0.030000, 0.971000], "gyroscope": [0.770000, -2.310000, 1.470000], "magnetometer": [-3.100000, -8.300000, 54.200000]}}} Length - 245, Publishing {"state": {"reported": {"temperature": 23.670000, "humidity": 98.129997, "pressure": 982.724121, "accelerometer": [-0.008000, 0.029000, 0.971000], "gyroscope": [0.630000, -2.380000, 1.400000], "magnetometer": [-3.100000, -7.900000, 53.400000]}}} Length - 245, Publishing {"state": {"reported": {"temperature": 23.690001, "humidity": 98.019997, "pressure": 982.840088, "accelerometer": [-0.009000, 0.030000, 0.972000], "gyroscope": [0.700000, -2.450000, 1.540000], "magnetometer": [-3.700000, -7.900000, 53.400000]}}} Length - 245, Publishing {"state": {"reported": {"temperature": 23.709999, "humidity": 98.040001, "pressure": 982.828613, "accelerometer": [-0.009000, 0.030000, 0.971000], "gyroscope": [0.630000, -2.520000, 1.470000], "magnetometer": [-2.900000, -7.400000, 52.400000]}}} Length - 245, Publishing {"state": {"reported": {"temperature": 23.719999, "humidity": 97.860001, "pressure": 982.917236, "accelerometer": [-0.026000, 0.103000, 0.891000], "gyroscope": [1.050000, -2.310000, 1.260000], "magnetometer": [-3.300000, -7.100000, 53.500000]}}}
Information
Device connection state might be checked by Green Led on the board. Green light means that device is connected and transferring data to cloud.
- Configure and start your dashboard using instruction and corresponding sources from github
- Use Blue button to set up markers to charts.
- Use AWS IoT console MQTT Client to test device subscription to "Nucleo/test". Just publish any message to this topic and serial port output.
- PROFIT!
NetworkSocketAPI/SocketAddress.cpp
- Committer:
- PavelSavyhin
- Date:
- 2017-09-27
- Revision:
- 0:4cdaf9b1e7d0
File content as of revision 0:4cdaf9b1e7d0:
/* Socket * Copyright (c) 2015 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 "SocketAddress.h" #include "NetworkStack.h" #include <string.h> #include "mbed.h" static bool ipv4_is_valid(const char *addr) { int i = 0; // Check each digit for [0-9.] for (; addr[i]; i++) { if (!(addr[i] >= '0' && addr[i] <= '9') && addr[i] != '.') { return false; } } // Ending with '.' garuntees host if (i > 0 && addr[i-1] == '.') { return false; } return true; } static bool ipv6_is_valid(const char *addr) { // Check each digit for [0-9a-fA-F:] for (int i = 0; addr[i]; i++) { if (!(addr[i] >= '0' && addr[i] <= '9') && !(addr[i] >= 'a' && addr[i] <= 'f') && !(addr[i] >= 'A' && addr[i] <= 'F') && addr[i] != ':') { return false; } } return true; } static void ipv4_from_address(uint8_t *bytes, const char *addr) { int count = 0; int i = 0; for (; count < NSAPI_IPv4_BYTES; count++) { int scanned = sscanf(&addr[i], "%hhu", &bytes[count]); if (scanned < 1) { return; } for (; addr[i] != '.'; i++) { if (!addr[i]) { return; } } i++; } } static int ipv6_scan_chunk(uint16_t *shorts, const char *chunk) { int count = 0; int i = 0; for (; count < NSAPI_IPv6_BYTES/2; count++) { int scanned = sscanf(&chunk[i], "%hx", &shorts[count]); if (scanned < 1) { return count; } for (; chunk[i] != ':'; i++) { if (!chunk[i]) { return count+1; } } i++; } return count; } static void ipv6_from_address(uint8_t *bytes, const char *addr) { // Start with zeroed address uint16_t shorts[NSAPI_IPv6_BYTES/2]; memset(shorts, 0, sizeof shorts); int suffix = 0; // Find double colons and scan suffix for (int i = 0; addr[i]; i++) { if (addr[i] == ':' && addr[i+1] == ':') { suffix = ipv6_scan_chunk(shorts, &addr[i+2]); break; } } // Move suffix to end memmove(&shorts[NSAPI_IPv6_BYTES/2-suffix], &shorts[0], suffix*sizeof(uint16_t)); // Scan prefix ipv6_scan_chunk(shorts, &addr[0]); // Flip bytes for (int i = 0; i < NSAPI_IPv6_BYTES/2; i++) { bytes[2*i+0] = (uint8_t)(shorts[i] >> 8); bytes[2*i+1] = (uint8_t)(shorts[i] >> 0); } } static void ipv4_to_address(char *addr, const uint8_t *bytes) { sprintf(addr, "%d.%d.%d.%d", bytes[0], bytes[1], bytes[2], bytes[3]); } static void ipv6_to_address(char *addr, const uint8_t *bytes) { for (int i = 0; i < NSAPI_IPv6_BYTES/2; i++) { sprintf(&addr[5*i], "%02x%02x", bytes[2*i], bytes[2*i+1]); addr[5*i+4] = ':'; } addr[NSAPI_IPv6_SIZE-1] = '\0'; } SocketAddress::SocketAddress(NetworkStack *iface, const char *host, uint16_t port) { memset(&_ip_address, 0, sizeof _ip_address); // Check for valid IP addresses if (host && ipv4_is_valid(host)) { _ip_version = NSAPI_IPv4; ipv4_from_address(_ip_bytes, host); set_port(port); } else if (host && ipv6_is_valid(host)) { _ip_version = NSAPI_IPv6; ipv6_from_address(_ip_bytes, host); set_port(port); } else { // DNS lookup int err = iface->gethostbyname(this, host); if (!err) { set_port(port); } else { _ip_version = NSAPI_IPv4; memset(_ip_bytes, 0, NSAPI_IPv4_BYTES); set_port(0); } } } SocketAddress::SocketAddress(const char *addr, uint16_t port) { memset(&_ip_address, 0, sizeof _ip_address); set_ip_address(addr); set_port(port); } SocketAddress::SocketAddress(const void *bytes, nsapi_version_t version, uint16_t port) { memset(&_ip_address, 0, sizeof _ip_address); set_ip_bytes(bytes, version); set_port(port); } SocketAddress::SocketAddress(const SocketAddress &addr) { memset(&_ip_address, 0, sizeof _ip_address); set_ip_bytes(addr.get_ip_bytes(), addr.get_ip_version()); set_port(addr.get_port()); } void SocketAddress::set_ip_address(const char *addr) { _ip_address[0] = '\0'; if (addr && ipv4_is_valid(addr)) { _ip_version = NSAPI_IPv4; ipv4_from_address(_ip_bytes, addr); } else if (addr && ipv6_is_valid(addr)) { _ip_version = NSAPI_IPv6; ipv6_from_address(_ip_bytes, addr); } else { _ip_version = NSAPI_IPv4; memset(_ip_bytes, 0, NSAPI_IPv4_BYTES); } } void SocketAddress::set_ip_bytes(const void *bytes, nsapi_version_t version) { _ip_address[0] = '\0'; if (version == NSAPI_IPv4) { _ip_version = NSAPI_IPv4; memcpy(_ip_bytes, bytes, NSAPI_IPv4_BYTES); } else if (version == NSAPI_IPv6) { _ip_version = NSAPI_IPv6; memcpy(_ip_bytes, bytes, NSAPI_IPv6_BYTES); } else { _ip_version = NSAPI_IPv4; memset(_ip_bytes, 0, NSAPI_IPv4_BYTES); } } void SocketAddress::set_port(uint16_t port) { _port = port; } const char *SocketAddress::get_ip_address() const { char *ip_address = (char *)_ip_address; if (!ip_address[0]) { if (_ip_version == NSAPI_IPv4) { ipv4_to_address(ip_address, _ip_bytes); } else if (_ip_version == NSAPI_IPv6) { ipv6_to_address(ip_address, _ip_bytes); } } return ip_address; } const void *SocketAddress::get_ip_bytes() const { return _ip_bytes; } nsapi_version_t SocketAddress::get_ip_version() const { return _ip_version; } uint16_t SocketAddress::get_port() const { return _port; } SocketAddress::operator bool() const { int count = 0; if (_ip_version == NSAPI_IPv4) { count = NSAPI_IPv4_BYTES; } else if (_ip_version == NSAPI_IPv6) { count = NSAPI_IPv6_BYTES; } for (int i = 0; i < count; i++) { if (_ip_bytes[i]) { return true; } } return false; }