Osamu Nakamura
mbed-os-example-client which can run on GR-PEACH as-is
main.cpp
- Committer:
- Osamu Nakamura
- Date:
- 2017-09-04
- Revision:
- 1:297185d9bb5e
- Parent:
- 0:c0b64bdd4f07
File content as of revision 1:297185d9bb5e:
/*
* Copyright (c) 2015, 2016 ARM Limited. All rights reserved.
* SPDX-License-Identifier: Apache-2.0
* 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.
*/
#define __STDC_FORMAT_MACROS
#include <inttypes.h>
#include "simpleclient.h"
#include <string>
#include <sstream>
#include <vector>
#include "mbed-trace/mbed_trace.h"
#include "mbedtls/entropy_poll.h"
#include "security.h"
#include "mbed.h"
// easy-connect compliancy, it has 2 sets of wifi pins we have only one
#define MBED_CONF_APP_ESP8266_TX MBED_CONF_APP_WIFI_TX
#define MBED_CONF_APP_ESP8266_RX MBED_CONF_APP_WIFI_RX
#include "easy-connect/easy-connect.h"
#ifdef TARGET_STM
#define RED_LED (LED3)
#define GREEN_LED (LED1)
#define BLUE_LED (LED2)
#define LED_ON (1)
#elif TARGET_RZ_A1H
#define RED_LED (LED1)
#define GREEN_LED (LED3)
#define BLUE_LED (LED3)
#define USER_LED (LED4)
#define LED_ON (1)
#else // !TARGET_STM
#define RED_LED (LED1)
#define GREEN_LED (LED2)
#define BLUE_LED (LED3)
#define LED_ON (0)
#endif // !TARGET_STM
#define LED_OFF (!LED_ON)
// Status indication
DigitalOut red_led(RED_LED);
DigitalOut green_led(GREEN_LED);
DigitalOut blue_led(BLUE_LED);
DigitalOut user_led(USER_LED);
Ticker status_ticker;
void blinky() {
green_led = !green_led;
}
#ifdef TARGET_RZ_A1H
void blinky_status() {
user_led = !user_led;
}
#endif // TARGET_RZ_A1H
// These are example resource values for the Device Object
struct MbedClientDevice device = {
"Manufacturer_String", // Manufacturer
"Type_String", // Type
"ModelNumber_String", // ModelNumber
"SerialNumber_String" // SerialNumber
};
// Instantiate the class which implements LWM2M Client API (from simpleclient.h)
MbedClient mbed_client(device);
// In case of K64F board , there is button resource available
// to change resource value and unregister
#ifdef TARGET_K64F
// Set up Hardware interrupt button.
InterruptIn obs_button(SW2);
InterruptIn unreg_button(SW3);
#elif TARGET_RZ_A1H
InterruptIn obs_button(USER_BUTTON0);
#else // TARGET_RZ_A1H
//In non K64F boards , set up a timer to simulate updating resource,
// there is no functionality to unregister.
Ticker timer;
#endif
/*
* Arguments for running "blink" in it's own thread.
*/
class BlinkArgs {
public:
BlinkArgs() {
clear();
}
void clear() {
position = 0;
blink_pattern.clear();
}
uint16_t position;
std::vector<uint32_t> blink_pattern;
};
/*
* The Led contains one property (pattern) and a function (blink).
* When the function blink is executed, the pattern is read, and the LED
* will blink based on the pattern.
*/
class LedResource {
public:
LedResource() {
// create ObjectID with metadata tag of '3201', which is 'digital output'
led_object = M2MInterfaceFactory::create_object("3201");
M2MObjectInstance* led_inst = led_object->create_object_instance();
// 5853 = Multi-state output
M2MResource* pattern_res = led_inst->create_dynamic_resource("5853", "Pattern",
M2MResourceInstance::STRING, false);
// read and write
pattern_res->set_operation(M2MBase::GET_PUT_ALLOWED);
// set initial pattern (toggle every 200ms. 7 toggles in total)
pattern_res->set_value((const uint8_t*)"500:500:500:500:500:500:500", 27);
// there's not really an execute LWM2M ID that matches... hmm...
M2MResource* led_res = led_inst->create_dynamic_resource("5850", "Blink",
M2MResourceInstance::OPAQUE, false);
// we allow executing a function here...
led_res->set_operation(M2MBase::POST_ALLOWED);
// when a POST comes in, we want to execute the led_execute_callback
led_res->set_execute_function(execute_callback(this, &LedResource::blink));
// Completion of execute function can take a time, that's why delayed response is used
led_res->set_delayed_response(true);
blink_args = new BlinkArgs();
}
~LedResource() {
delete blink_args;
}
M2MObject* get_object() {
return led_object;
}
void blink(void *argument) {
#ifndef TARGET_RZ_A1H
// read the value of 'Pattern'
status_ticker.detach();
green_led = LED_OFF;
#endif // TARGET_RZ_A1H
M2MObjectInstance* inst = led_object->object_instance();
M2MResource* res = inst->resource("5853");
// Clear previous blink data
blink_args->clear();
// values in mbed Client are all buffers, and we need a vector of int's
uint8_t* buffIn = NULL;
uint32_t sizeIn;
res->get_value(buffIn, sizeIn);
// turn the buffer into a string, and initialize a vector<int> on the heap
std::string s((char*)buffIn, sizeIn);
free(buffIn);
printf("led_execute_callback pattern=%s\n", s.c_str());
// our pattern is something like 500:200:500, so parse that
std::size_t found = s.find_first_of(":");
while (found!=std::string::npos) {
blink_args->blink_pattern.push_back(atoi((const char*)s.substr(0,found).c_str()));
s = s.substr(found+1);
found=s.find_first_of(":");
if(found == std::string::npos) {
blink_args->blink_pattern.push_back(atoi((const char*)s.c_str()));
}
}
// check if POST contains payload
if (argument) {
M2MResource::M2MExecuteParameter* param = (M2MResource::M2MExecuteParameter*)argument;
String object_name = param->get_argument_object_name();
uint16_t object_instance_id = param->get_argument_object_instance_id();
String resource_name = param->get_argument_resource_name();
int payload_length = param->get_argument_value_length();
uint8_t* payload = param->get_argument_value();
printf("Resource: %s/%d/%s executed\n", object_name.c_str(), object_instance_id, resource_name.c_str());
printf("Payload: %.*s\n", payload_length, payload);
}
// do_blink is called with the vector, and starting at -1
blinky_thread.start(callback(this, &LedResource::do_blink));
}
private:
M2MObject* led_object;
Thread blinky_thread;
BlinkArgs *blink_args;
void do_blink() {
for (;;) {
// blink the LED
red_led = !red_led;
// up the position, if we reached the end of the vector
if (blink_args->position >= blink_args->blink_pattern.size()) {
// send delayed response after blink is done
M2MObjectInstance* inst = led_object->object_instance();
M2MResource* led_res = inst->resource("5850");
led_res->send_delayed_post_response();
#ifndef TARGET_RZ_A1H
red_led = LED_OFF;
status_ticker.attach_us(blinky, 250000);
#endif // TARGET_RZ_A1H
return;
}
// Wait requested time, then continue prosessing the blink pattern from next position.
Thread::wait(blink_args->blink_pattern.at(blink_args->position));
blink_args->position++;
}
}
};
/*
* The button contains one property (click count).
* When `handle_button_click` is executed, the counter updates.
*/
class ButtonResource {
public:
ButtonResource(): counter(0) {
// create ObjectID with metadata tag of '3200', which is 'digital input'
btn_object = M2MInterfaceFactory::create_object("3200");
M2MObjectInstance* btn_inst = btn_object->create_object_instance();
// create resource with ID '5501', which is digital input counter
M2MResource* btn_res = btn_inst->create_dynamic_resource("5501", "Button",
M2MResourceInstance::INTEGER, true /* observable */);
// we can read this value
btn_res->set_operation(M2MBase::GET_ALLOWED);
// set initial value (all values in mbed Client are buffers)
// to be able to read this data easily in the Connector console, we'll use a string
btn_res->set_value((uint8_t*)"0", 1);
}
~ButtonResource() {
}
M2MObject* get_object() {
return btn_object;
}
/*
* When you press the button, we read the current value of the click counter
* from mbed Device Connector, then up the value with one.
*/
void handle_button_click() {
if (mbed_client.register_successful()) {
M2MObjectInstance* inst = btn_object->object_instance();
M2MResource* res = inst->resource("5501");
// up counter
counter++;
#if TARGET_K64F || TARGET_RZ_A1H
printf("handle_button_click, new value of counter is %d\n", counter);
#else
printf("simulate button_click, new value of counter is %d\n", counter);
#endif
// serialize the value of counter as a string, and tell connector
char buffer[20];
int size = sprintf(buffer,"%d",counter);
res->set_value((uint8_t*)buffer, size);
} else {
printf("simulate button_click, device not registered\n");
}
}
private:
M2MObject* btn_object;
uint16_t counter;
};
class BigPayloadResource {
public:
BigPayloadResource() {
big_payload = M2MInterfaceFactory::create_object("1000");
M2MObjectInstance* payload_inst = big_payload->create_object_instance();
M2MResource* payload_res = payload_inst->create_dynamic_resource("1", "BigData",
M2MResourceInstance::STRING, true /* observable */);
payload_res->set_operation(M2MBase::GET_PUT_ALLOWED);
payload_res->set_value((uint8_t*)"0", 1);
payload_res->set_incoming_block_message_callback(
incoming_block_message_callback(this, &BigPayloadResource::block_message_received));
payload_res->set_outgoing_block_message_callback(
outgoing_block_message_callback(this, &BigPayloadResource::block_message_requested));
}
M2MObject* get_object() {
return big_payload;
}
void block_message_received(M2MBlockMessage *argument) {
if (argument) {
if (M2MBlockMessage::ErrorNone == argument->error_code()) {
if (argument->is_last_block()) {
printf("Last block received\n");
}
printf("Block number: %d\n", argument->block_number());
// First block received
if (argument->block_number() == 0) {
// Store block
// More blocks coming
} else {
// Store blocks
}
} else {
printf("Error when receiving block message! - EntityTooLarge\n");
}
printf("Total message size: %" PRIu32 "\n", argument->total_message_size());
}
}
void block_message_requested(const String& resource, uint8_t *&/*data*/, uint32_t &/*len*/) {
printf("GET request received for resource: %s\n", resource.c_str());
// Copy data and length to coap response
}
private:
M2MObject* big_payload;
};
// Network interaction must be performed outside of interrupt context
Semaphore updates(0);
volatile bool registered = false;
volatile bool clicked = false;
osThreadId mainThread;
void unregister() {
registered = false;
updates.release();
}
void button_clicked() {
clicked = true;
updates.release();
}
// set mac address
void mbed_mac_address(char *mac) {
mac[0] = 0x00;
mac[1] = 0x11;
mac[2] = 0x22;
mac[3] = 0x33;
mac[4] = 0x44;
mac[5] = 0x55;
}
// Entry point to the program
int main() {
unsigned int seed;
size_t len;
#ifdef MBEDTLS_ENTROPY_HARDWARE_ALT
// Used to randomize source port
mbedtls_hardware_poll(NULL, (unsigned char *) &seed, sizeof seed, &len);
#elif defined MBEDTLS_TEST_NULL_ENTROPY
#warning "mbedTLS security feature is disabled. Connection will not be secure !! Implement proper hardware entropy for your selected hardware."
// Used to randomize source port
mbedtls_null_entropy_poll( NULL,(unsigned char *) &seed, sizeof seed, &len);
#else
#error "This hardware does not have entropy, endpoint will not register to Connector.\
You need to enable NULL ENTROPY for your application, but if this configuration change is made then no security is offered by mbed TLS.\
Add MBEDTLS_NO_DEFAULT_ENTROPY_SOURCES and MBEDTLS_TEST_NULL_ENTROPY in mbed_app.json macros to register your endpoint."
#endif
srand(seed);
red_led = LED_OFF;
blue_led = LED_OFF;
#ifndef TARGET_RZ_A1H
status_ticker.attach_us(blinky, 250000);
#else
status_ticker.attach_us(blinky_status, 250000);
#endif
// Keep track of the main thread
mainThread = osThreadGetId();
printf("\nStarting mbed Client example in ");
#if defined (MESH) || (MBED_CONF_LWIP_IPV6_ENABLED==true)
printf("IPv6 mode\n");
#else
printf("IPv4 mode\n");
#endif
mbed_trace_init();
NetworkInterface* network = easy_connect(true);
if(network == NULL) {
printf("\nConnection to Network Failed - exiting application...\n");
return -1;
}
// we create our button and LED resources
ButtonResource button_resource;
LedResource led_resource;
BigPayloadResource big_payload_resource;
#ifdef TARGET_K64F
// On press of SW3 button on K64F board, example application
// will call unregister API towards mbed Device Connector
//unreg_button.fall(&mbed_client,&MbedClient::test_unregister);
unreg_button.fall(&unregister);
// Observation Button (SW2) press will send update of endpoint resource values to connector
obs_button.fall(&button_clicked);
#elif TARGET_RZ_A1H
// Observation Button (USER_BUTTON0) press will send update of endpoint resource values to connector
obs_button.fall(&button_clicked);
#else
// Send update of endpoint resource values to connector every 15 seconds periodically
timer.attach(&button_clicked, 15.0);
#endif
// Create endpoint interface to manage register and unregister
mbed_client.create_interface(MBED_SERVER_ADDRESS, network);
// Create Objects of varying types, see simpleclient.h for more details on implementation.
M2MSecurity* register_object = mbed_client.create_register_object(); // server object specifying connector info
M2MDevice* device_object = mbed_client.create_device_object(); // device resources object
// Create list of Objects to register
M2MObjectList object_list;
// Add objects to list
object_list.push_back(device_object);
object_list.push_back(button_resource.get_object());
object_list.push_back(led_resource.get_object());
object_list.push_back(big_payload_resource.get_object());
// Set endpoint registration object
mbed_client.set_register_object(register_object);
// Register with mbed Device Connector
mbed_client.test_register(register_object, object_list);
registered = true;
while (true) {
updates.wait(25000);
if(registered) {
if(!clicked) {
mbed_client.test_update_register();
}
}else {
break;
}
if(clicked) {
clicked = false;
button_resource.handle_button_click();
}
}
mbed_client.test_unregister();
status_ticker.detach();
}