init readme | init well codebase

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 # | Opportunistic ZigBee |
 ## I. Overview
 This project aims to design and optimize a solution for an optimistic network using Arduino and [XBee](https://www.digi.com/xbee).
 The base scenario takes place in a mesh network of similar <u>nodes</u> ; each being subject to real-time motion. Every node has to transmit logging data (*i.e. periodically*) to a special node : the **well ** ; the well is unique in the network and is the only one that actually receives data, every other node has the same source code and behavior.
 **Main goals :**
 1. Optimize network usage : limit duplicates and retransmissions
 2. Maximize relative space-awareness throughout time : avoid losses and retransmissions
 3. [TODO]
 **Vocabulary**
 - **distance** - the relative distance to the well. The well has a distance of 0, its direct neighbors a distance of 1 and so on.  
 - **wave** - a distance propagation of distances throughout the network that share a common source.
 ----
 ## II. File structure
 The code is split over 2 sub-projects :
 - the **well**, located inside `well/main/`.
 - **nodes**, located in the `node/main` folder.
 > The project bundles its required libraries - for compatibility purposes - inside the `libraries/` folder. Symbolic links make them available for each sub-project.
 ----
 ## III. Algorithm
 #### 1) Data structure
 Every communication follows a consistent data format which can be split into 2 types ; the first *byte* (*i.e. called opcode*) allows receivers to identity the data type.
 ##### Discover Request
 The `discover` data format is used to propagate the relative distances throughout the network. The **well** is the only node that can initiate a discover request, other nodes only make sure of the propagation.
 ```c++
 struct discover {
    uint8_t opcode; // opcode = 0
    uint8_t wave;   // id de la wave
    uint8_t dist;   // current node's distance
 };
 ```
 ##### Data Message
 The `data` format is sent by nodes to submit messagesca to the well.
 ```c++
 struct data {
    uint8_t opcode;    // opcode = 1
    uint8_t dist;      // distance of the last sender
    uint8_t ttl;       // time to live default = 10
    uint8_t size;      // size of message in bytes
    uint8_t message[]; // actual message
 };
 ```
 #### 2) Well
 The well features 2 routines :
 1. Send <u>[discover](#discover-request)</u> requests periodically
 2. Listen for incoming [data](#data-message).
 #### 3) Nodes
 [TODO]
--- a/well/main/libraries
+++ b/well/main/libraries
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 ../../libraries
--- a/well/main/main.ino
+++ b/well/main/main.ino
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 #include <Wire.h>
 #include <XBee.h>
 #include "protocol.h"
 #include <LiquidCrystal_I2C.h>
 // CONSTANTS
 #define WAVE_TIMEOUT 5000 // send wave every (in ms)
 // Peripherals
 LiquidCrystal_I2C screen(0x27, 16, 2);
 XBee xbee = XBee();
 // ACTUAL DATA
 uint8_t wave_id = 250;
 struct discover req = {0,0,0};
 void setup() {
  Serial.begin(38400);
  Serial.println("+ ready");
  screen.begin();
  screen.backlight();
  xbee.setSerial(Serial1);
  Serial1.begin(38400);
  // xbee.begin(38400);
 }
 void loop() {
  delay(WAVE_TIMEOUT);
  // increment wave id (will overflow from 255 to 0)
  req.wave = ++wave_id; // set wave id
  screen.clear();
  screen.print("+ wave");
  screen.print(req.wave);
  uint8_t payload[3] = {req.opcode, req.wave, req.dist};
  XBeeAddress64 addr64 = XBeeAddress64(0x00000000, 0x0000FFFF);
  Tx64Request tx = Tx64Request(addr64, payload, sizeof(payload));
  xbee.send(tx);
  /* Check the status of our sent payload (not mandatory)
    TxStatusResponse txStatus = TxStatusResponse();
    xbee.readPacket();
    if( xbee.getResponse().isAvailable() ){
      if( xbee.getResponse().getApiId() == TX_STATUS_RESPONSE ){
            xbee.getResponse().getTxStatusResponse(txStatus);
            txStatus.isSuccess() && Serial.println(" ... sent") || Serial.println(" ... failed");
      }
    }
  */
 }
--- a/well/main/protocol.h
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 #ifndef _PROTOCOL_H_
 	#define _PROTOCOL_H_
 	#define DISCOVER_TTL 10000
 	#define DISCOVER_SIZE sizeof(int)*2
 	// discover request (c.f. class node)
 	struct discover {
 		uint8_t opcode; // opcode = 0
 		uint8_t wave;   // id de la wave
 		uint8_t dist;   // current node's distance
 	};
 	struct data {
 		uint8_t opcode;    // opcode = 1
 		uint8_t dist;      // distance of the last sender
 		uint8_t ttl;       // time to live default = 10
 		uint8_t size;      // size of message in bytes
 		uint8_t message[]; // actual message
 	};
 	// A <node> object is held by each node which values are determined thanks
 	// to the DISCOVER requests it receives; each node broadcasts a DISCOVER
 	// request every DISCOVER_TTL milliseconds
    class node{
 		private:
 			// unique id of the node : MAC ADDR
 			int id;
 			// last received wave id
 			uint8_t last_wave;
 			// relative node-distance to the well
 			// WELL                  : dist = 0
 			// NODE1 can reach WELL  : dist = 1
 			// NODE2 can reach NODE1 : dist = 2
 			// and so on...
 			uint8_t dist;
 		public:
 			// send a discover request
 			bool discover();
 			// update the current node according to a (received)
 			// discover request
 			bool update(struct discover req);
    };
 #endif