04_zumbach/11_m644p_WIZNET_HTTPServer_FLASH_pages/main.c

/*
 * main.c
 *
 *  Created on: 22 нояб. 2018 г.
 *      Author: maxx
 */
#include <avr/io.h>
#include <util/delay.h>
#include <avr/interrupt.h>
#include <avr/pgmspace.h>
#include <compat/deprecated.h>  //sbi, cbi etc..
#include "avr/wdt.h" // WatchDog
#include <stdio.h>  // printf etc..
#include "uart_extd.h"
#include "spi.h"

#include "globals.h" //Global definitions for project

#include "stdbool.h"
#include "Ethernet/socket.h"
#include "Ethernet/wizchip_conf.h"
#include "Internet/httpServer_avr/httpServer.h"
#include "webpage.h"

#define _MAIN_DEBUG_

//#include "Application/loopback/loopback.h"
//#include "Application/webserver_simple/webserver_simple.h"

//#include <stdlib.h> // itoa etc..
/*
 * (11) Try move all pages saved at <webpage.h> from RAM to FLASH address space
 * Example of flash data access look at:
 * <01_m1284p_bb00_minimum_PSTR_webpage_test>
 * <09_m1284p_WIZNET_simple_webserver>
 *
 * Success initial porting on 10/12/2018 - FREE RAM on webserver: 7936 bytes (From total 16kbytes)!
 * NEED further optimization to AVR_RAM->AVR_FLASH point (damn Harvard architecture :( )!
 *
 * It works on AtMega1284p(16kbytes RAM), but need TODO finish (DONE on v2.3b 12/12/2018)!!
 *
 * TODO DONE:
 * After v2.3 optimization:
 * 	(+4kb HTTP Buffers READ-WRITE(with HTTPD_MAX_BUF_SIZE	2048 see <globals.h>)) : FREE RAM on webserver: 10372 bytes - much better! (RAM enough for AtMega1284/AtMega2560 ie. AVR with 8-16Kb RAM)
 * 	(+1kb HTTP Buffers READ-WRITE(with HTTPD_MAX_BUF_SIZE	 512 see <globals.h>)) : FREE RAM on webserver: 13444 bytes - awesome! 	   (RAM enough for AtMega644/AtMega128   ie. AVR with 4Kb RAM)
 *
 * OK 1) Father optimization <httpParser.c> / <httpParser.h> (v2.3 12/12/2018)
 * OK 2) Father optimization <httpUtil.c> / <httpUtil.h> (v2.3 12/12/2018)
 * OK 3) Rename httpServer.*->httpServer_avr.*, httpParser.*->httpParser_avr.*, httpUtil.*->httpUtil_avr.* (v2.3b 12/12/2018)
 * 		 Actually made another way: rename parent folder <http> to <http_avr>
 * OK 4) Fix not correct showed value on <ain_gauge.html> (v2.2 12/12/2018)
 * OK 5) Correct indentation in all <*.html> and <*.js> sources and repack it again in <webpage.h>. (v2.2 12/12/2018)
 * OK 6) Add <favicon.ico> to webserver (v2.1 12/12/2018) + also added binary files support in webserver via: <reg_httpServer_binContent_avr()..>, bin2hex_v2.py
 * 7) Publish sources in my github, wiznetmuseim, avrfreaks etc.. (optional)
 *
 * (10) Try repeat example HTTPServer_LPC11E36_LPCXpresso on AVR Mega1284p (All pages still in RAM)
 * Here used to WEB-server handle cgi-like requests, with AJAX + JSON
 * Description here:
 * http://wiznetmuseum.com/portfolio-items/w5500-evb-web-server/
 *
 * To better undestand AJAX look here (actually here used AJAX + XHTML):
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/web-server-read-switch-using-AJAX/
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/web-server-read-switch-automatically-using-AJAX/
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/AJAX-read-switches-analog/
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/SD-card-AJAX-web-server/
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/SD-card-AJAX-XML-web-server/
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/SD-card-gauge/
 * https://startingelectronics.org/tutorials/arduino/ethernet-shield-web-server-tutorial/SD-card-IO/
 *
 * To online encode text file to C source use online utility (Text->Cpp):
 * https://tomeko.net/online_tools/cpp_text_escape.php?lang=en
 * add option <split output into multiple lines> (this is for good reading into browser, as source code)
 * after that insert in any text editor and replace <\n"> sequence to <\n"\> (this is for recognize multiple string into C-source headers)
 *
 * For prepare binary data (some image data, like favicon.ico) use <bin2hex_v2.py> script.
 * Example usage:
 * >bin2hex_v2.py favicon.ico
 * >out favicon_ico.h
 * After that insert into end <webpage.h> content from favicon.ico;
 * Then use this resource in www server like (look in <main.c>):
 * reg_httpServer_binContent_avr(PSTR("favicon.ico"),favicon_ico, (uint32_t)sizeof(favicon_ico));				// favicon.ico 		: webserver icon
 *
 *
 *
 * Also can use File->HEX (BIN2HEX) - for prepare images for example (bin2hex_v2.py BETTER SUIT for AVR!!):
 * https://tomeko.net/online_tools/file_to_hex.php?lang=en
 *
 * (9) Simple webserver, based on <wiznetweb.c> code from:
 * http://www.ermicro.com/blog/?p=1773
 * Article: Integrating Wiznet W5100, WIZ811MJ network module with Atmel AVR Microcontroller
 *
 * (3) Trying WIZNET5500 init with using official Wiznet ioLibrary_Driver
 * working ping on static IP
 * LED1 = ON when phy_link detected
 * and loopback test on TCP-IP:5000 and UDP:3000 ports.
 * use Hercules terminal utility to check network connection see:
 *
 * https://wizwiki.net/wiki/doku.php?id=osh:cookie:loopback_test
 * https://www.hw-group.com/software/hercules-setup-utility
 *
 *
 * Author of porting to AVR Mega:
 * Ibragimov Maxim, Russia Togliatty ~10..12.2018
 */

#ifdef IP_WORK
//NIC metrics for WORK PC
wiz_NetInfo netInfo = { .mac  = {0x00, 0x08, 0xdc, 0xab, 0xcd, 0xef}, // Mac address
		.ip   = {192, 168, 0, 199},         // IP address
		.sn   = {255, 255, 255, 0},         // Subnet mask
		.dns =  {8,8,8,8},			  // DNS address (google dns)
		.gw   = {192, 168, 0, 1}, // Gateway address
		.dhcp = NETINFO_STATIC};    //Static IP configuration
#else
//NIC metrics for another PC (second IP configuration)
wiz_NetInfo netInfo = { .mac  = {0x00, 0x08, 0xdc, 0xab, 0xcd, 0xef}, // Mac address
		.ip   = {192, 168, 1, 199},         // IP address
		.sn   = {255, 255, 255, 0},         // Subnet mask
		.dns =  {8,8,8,8},			  // DNS address (google dns)
		.gw   = {192, 168, 1, 1}, // Gateway address
		.dhcp = NETINFO_STATIC};    //Static IP configuration
#endif

//*********Program metrics
const char compile_date[] PROGMEM    = __DATE__;     // Mmm dd yyyy - Дата компиляции
const char compile_time[] PROGMEM    = __TIME__;     // hh:mm:ss - Время компиляции
const char str_prog_name[] PROGMEM   = "\r\nAtMega644p v2.3d Static IP HTTP_server FLASH Pages WIZNET_5500 ETHERNET 12/12/2018\r\n"; // Program name

/*
 * m1284p minimum template, with one button & one led
 */

//M644P/M1284p Users LEDS:
//LED1/PORTC.4- m644p/m1284p maxxir
#define led1_conf()      DDRC |= (1<<DDC4)
#define led1_high()      PORTC |= (1<<PORTC4)
#define led1_low()       PORTC &= ~(1<<PORTC4)
#define led1_tgl()     PORTC ^= (1<<PORTC4)
#define led1_read()     (PORTC & (1<<PORTC4))

#define sw1_conf()      {DDRC &= ~(1<<DDC5); PORTC |= (1<<PORTC5);}
#define sw1_read()     (PINC & (1<<PINC5))

//***********Prologue for fast WDT disable & and save reason of reset/power-up: BEGIN
uint8_t mcucsr_mirror __attribute__ ((section (".noinit")));

// This is for fast WDT disable & and save reason of reset/power-up
void get_mcusr(void) \
  __attribute__((naked)) \
  __attribute__((section(".init3")));
void get_mcusr(void)
{
  mcucsr_mirror = MCUSR;
  MCUSR = 0;
  wdt_disable();
}
//***********Prologue for fast WDT disable & and save reason of reset/power-up: END

//*********Global vars
#define TICK_PER_SEC 1000UL
volatile unsigned long _millis; // for millis tick !! Overflow every ~49.7 days


#if defined(__AVR_ATmega128__)
const char PROGMEM str_mcu[] = "ATmega128"; //CPU is m128
#elif defined (__AVR_ATmega2560__)
const char PROGMEM str_mcu[] = "ATmega2560"; //CPU is m2560
#elif defined (__AVR_ATmega2561__)
const char PROGMEM str_mcu[] = "ATmega2561"; //CPU is m2561
#elif defined (__AVR_ATmega328P__)
const char PROGMEM str_mcu[] = "ATmega328P"; //CPU is m328p
#elif defined (__AVR_ATmega32U4__)
const char PROGMEM str_mcu[] = "ATmega32u4"; //CPU is m32u4
#elif defined (__AVR_ATmega644P__)
const char PROGMEM str_mcu[] = "ATmega644p"; //CPU is m644p
#elif defined (__AVR_ATmega1284P__)
const char PROGMEM str_mcu[] = "ATmega1284p"; //CPU is m1284p
#else
const char PROGMEM str_mcu[] = "Unknown CPU"; //CPU is unknown
#endif


//FUNC headers
static void avr_init(void);
void timer0_init(void);

//Wiznet FUNC headers
void print_network_information(void);

// RAM Memory usage test
int freeRam (void)
{
	extern int __heap_start, *__brkval;
	int v;
	int _res = (int) &v - (__brkval == 0 ? (int) &__heap_start : (int) __brkval);
	return _res;
}


//******************* MILLIS ENGINE: BEGIN
//ISR (TIMER0_COMP_vect )
ISR (TIMER0_COMPA_vect)
{
	// Compare match Timer0
	// Here every 1ms
	_millis++; // INC millis tick
	// Тест мигаем при в ходе в прерывание
	// 500Hz FREQ OUT
	// LED_TGL;
}

inline unsigned long millis(void)
{
	unsigned long i;
	cli();
	// Atomic tick reading
	i = _millis;
	sei();
	return i;
}
//******************* MILLIS ENGINE: END

//***************** UART0: BEGIN
// Assign I/O stream to UART
/* define CPU frequency in Mhz here if not defined in Makefile */
//#ifndef F_CPU
//#define F_CPU 16000000UL
//#endif

/* 19200 baud */
//#define UART_BAUD_RATE      19200
//#define UART_BAUD_RATE      38400
#define UART_BAUD_RATE      115200

static int uart0_putchar(char ch,FILE *stream);
static void uart0_rx_flash(void);

static FILE uart0_stdout = FDEV_SETUP_STREAM(uart0_putchar, NULL, _FDEV_SETUP_WRITE);
//PS. stdin не переназначаю, т.к. удобнее с ним работать через uart.h - api:

/*
 * Т.е. например так
        c = uart1_getc();
        if (( c & UART_NO_DATA ) == 0)
        {
           uart1_putc( (unsigned char)c );
        }
 При этом чекаем что буфер приема не пуст и опрос идет неблокирующий (+ работаем через UART RX RINGBUFFER),
 а если работаем в стиле stdin->getchar() там опрос блокируется пока символ не будет принят (поллинг)
 через UART1_RX, т.е. неудобно.
 */

// STDOUT UART0 TX handler
static int uart0_putchar(char ch,FILE *stream)
{
	uart_putc(ch);
	return 0;
}

// Очищаем буфер приема UART1 RX (иногда нужно)
static void uart0_rx_flash(void)
{
	// Считываем все из ring-buffer UART1 RX
	unsigned int c;
	do
	{
		c = uart_getc();
	} while (( c & UART_NO_DATA ) == 0); // Check RX1 none-empty

}
//***************** UART0: END

//***************** ADC: BEGIN

#ifndef ADC_DIV
//12.5MHz or over use this ADC reference clock
#define ADC_DIV (1<<ADPS2)|(1<<ADPS1)|(1<<ADPS0) //:128 ADC Prescaler
#endif

#ifndef ADC_REF
// vcc voltage ref default
#define ADC_REF (1<<REFS0)
#endif

void adc_init(void)
{
	ADCSRA = 0;
	ADCSRA |= (ADC_DIV);    // ADC reference clock
	ADMUX |= (ADC_REF);     // Voltage reference
	ADCSRA |= (1<<ADEN);    // Turn on ADC
	ADCSRA |= (1<<ADSC);    // Do an initial conversion because this one is the
	// slowest and to ensure that everything is up
	// and running
}

uint16_t adc_read(uint8_t channel)
{
	ADMUX &= 0b11100000;                    //Clear the older channel that was read
	ADMUX |= channel;                //Defines the new ADC channel to be read
	ADCSRA |= (1<<ADSC);                //Starts a new conversion
	while(ADCSRA & (1<<ADSC));            //Wait until the conversion is done

	return ADCW;                    //Returns the ADC value of the chosen channel
}
//***************** ADC: END


//***************** WIZCHIP INIT: BEGIN
#define ETH_MAX_BUF_SIZE	2048

/*
unsigned char ethBuf0[ETH_MAX_BUF_SIZE];
unsigned char ethBuf1[ETH_MAX_BUF_SIZE];
unsigned char ethBuf2_WEBSRV[WEBSRV_DATA_BUF_SIZE];
*/

void cs_sel() {
	SPI_WIZNET_ENABLE();
}

void cs_desel() {
	SPI_WIZNET_DISABLE();
}

uint8_t spi_rb(void) {
	uint8_t rbuf;
	//HAL_SPI_Receive(&hspi1, &rbuf, 1, HAL_MAX_DELAY);
	SPI_READ(rbuf);
	return rbuf;
}

void spi_wb(uint8_t b) {
	//HAL_SPI_Transmit(&hspi1, &b, 1, HAL_MAX_DELAY);
	SPI_WRITE(b);
}

void spi_rb_burst(uint8_t *buf, uint16_t len) {
	//HAL_SPI_Receive_DMA(&hspi1, buf, len);
	//while(HAL_SPI_GetState(&hspi1) == HAL_SPI_STATE_BUSY_RX);
	for (uint16_t var = 0; var < len; var++) {
		SPI_READ(*buf++);
	}
}

void spi_wb_burst(uint8_t *buf, uint16_t len) {
	//HAL_SPI_Transmit_DMA(&hspi1, buf, len);
	//while(HAL_SPI_GetState(&hspi1) == HAL_SPI_STATE_BUSY_TX);
	for (uint16_t var = 0; var < len; var++) {
		SPI_WRITE(*buf++);
	}
}

void IO_LIBRARY_Init(void) {
	uint8_t bufSize[] = {2, 2, 2, 2, 2, 2, 2, 2};

	reg_wizchip_cs_cbfunc(cs_sel, cs_desel);
	reg_wizchip_spi_cbfunc(spi_rb, spi_wb);
	reg_wizchip_spiburst_cbfunc(spi_rb_burst, spi_wb_burst);

	wizchip_init(bufSize, bufSize);
	wizchip_setnetinfo(&netInfo);
	//wizchip_setinterruptmask(IK_SOCK_0);
}
//***************** WIZCHIP INIT: END
//////////////////////////////////////////////////
// Socket & Port number definition for Examples //
//////////////////////////////////////////////////
//#define SOCK_TCPS       0
//#define SOCK_UDPS       1
//#define PORT_TCPS		5000
//#define PORT_UDPS       3000

////////////////////////////////////////////////
//HTTPD  Sockets Definition  				  //
////////////////////////////////////////////////
#define MAX_HTTPSOCK	6
uint8_t socknumlist[] = {2, 3, 4, 5, 6, 7};
//#define MAX_HTTPSOCK	2
//uint8_t socknumlist[] = {0, 1};

////////////////////////////////////////////////
//HTTPD  Shared Buffer Definition  				  //
////////////////////////////////////////////////
uint8_t RX_BUF[HTTPD_MAX_BUF_SIZE];
uint8_t TX_BUF[HTTPD_MAX_BUF_SIZE];

int main()
{
	uint8_t prev_sw1 = 1; // VAR for sw1 pressing detect

	// INIT MCU
	avr_init();
	spi_init(); //SPI Master, MODE0, 4Mhz(DIV4), CS_PB.3=HIGH - suitable for WIZNET 5x00(1/2/5)


	// Print program metrics
	PRINTF("%S", str_prog_name);// Название программы
	PRINTF("Compiled at: %S %S\r\n", compile_time, compile_date);// Время Дата компиляции
	PRINTF(">> MCU is: %S; CLK is: %luHz\r\n", str_mcu, F_CPU);// MCU Name && FREQ
	PRINTF(">> Free RAM is: %d bytes\r\n", freeRam());

	//Short Blink LED 3 times on startup
	unsigned char i = 3;
	while(i--)
	{
		led1_high();
		_delay_ms(100);
		led1_low();
		_delay_ms(400);
		wdt_reset();
	}

	//Wizchip WIZ5500 Ethernet initialize
	IO_LIBRARY_Init(); //After that ping must working
	print_network_information();

//**************************************HTTPD init: BEGIN
	/* HTTP Server Initialization  */
	httpServer_init(TX_BUF, RX_BUF, MAX_HTTPSOCK, socknumlist);		// Tx/Rx buffers (1kB) / The number of W5500 chip H/W sockets in use
	//reg_httpServer_cbfunc(NVIC_SystemReset, NULL); 					// Callback: NXP MCU Reset
	reg_httpServer_cbfunc(NULL, NULL); 					// Callback: Still not used here ARV System reset, AVR WDT reset
	if(1)
	{
		/* Web content registration (web content in webpage.h, Example web pages) */

		// Index page and netinfo / base64 image demo
		reg_httpServer_webContent_avr(PSTR("index.html"), PSTR(index_page));				// index.html 		: Main page example

		//favicon.ico
		reg_httpServer_binContent_avr(PSTR("favicon.ico"),favicon_ico, (uint32_t)sizeof(favicon_ico));				// favicon.ico 		: webserver icon

		//brd_wiznet.png
		reg_httpServer_binContent_avr(PSTR("brd_wiznet.png"),brd_wiznet_png, (uint32_t)sizeof(brd_wiznet_png));				// brd_wiznet.png 		: webserver image

		/*
		//m1284p.png
		reg_httpServer_binContent_avr(PSTR("m1284p.png"),m1284p_png, (uint32_t)sizeof(m1284p_png));				// m1284p.png 		: webserver image
		*/

		reg_httpServer_webContent_avr(PSTR("netinfo.html"), PSTR(netinfo_page));			// netinfo.html 	: Network information example page
		reg_httpServer_webContent_avr(PSTR("netinfo.js"), PSTR(wiz550web_netinfo_js));	// netinfo.js 		: JavaScript for Read Network configuration 	(+ ajax.js)
		//reg_httpServer_webContent((uint8_t *)"netinfo.html", (uint8_t *)netinfo_page);			// netinfo.html 	: Network information example page
		//reg_httpServer_webContent((uint8_t *)"netinfo.js", (uint8_t *)wiz550web_netinfo_js);	// netinfo.js 		: JavaScript for Read Network configuration 	(+ ajax.js)

		// AJAX JavaScript functions
		reg_httpServer_webContent_avr(PSTR("ajax.js"), PSTR(wiz550web_ajax_js));			// ajax.js			: JavaScript for AJAX request transfer
		//reg_httpServer_webContent((uint8_t *)"ajax.js", (uint8_t *)wiz550web_ajax_js);			// ajax.js			: JavaScript for AJAX request transfer

		//Device info page && related ajax script
		reg_httpServer_webContent_avr(PSTR("info.html"), PSTR(info_page)); //info.html
		reg_httpServer_webContent_avr(PSTR("info.js"), PSTR(wiz550web_info_js)); // info.js 			: JavaScript for Device information	(+ ajax.js)
		//reg_httpServer_webContent((uint8_t *)"info.html", (uint8_t *)info_page); //info.html
		//reg_httpServer_webContent((uint8_t *)"info.js", (uint8_t *)wiz550web_info_js); // info.js 			: JavaScript for Device information	(+ ajax.js)

		reg_httpServer_webContent_avr(PSTR("img.html"), PSTR(img_page));					// img.html 		: Base64 Image data example page
		//reg_httpServer_webContent((uint8_t *)"img.html", (uint8_t *)img_page);					// img.html 		: Base64 Image data example page

		// Example #1
		reg_httpServer_webContent_avr(PSTR("dio.html"), PSTR(dio_page));					// dio.html 		: Digital I/O control example page
		reg_httpServer_webContent_avr(PSTR("dio.js"), PSTR(wiz550web_dio_js));			// dio.js 			: JavaScript for digital I/O control 	(+ ajax.js)
		//reg_httpServer_webContent((uint8_t *)"dio.html", (uint8_t *)dio_page);					// dio.html 		: Digital I/O control example page
		//reg_httpServer_webContent((uint8_t *)"dio.js", (uint8_t *)wiz550web_dio_js);			// dio.js 			: JavaScript for digital I/O control 	(+ ajax.js)

		// Example #2
		reg_httpServer_webContent_avr(PSTR("ain.html"), PSTR(ain_page));					// ain.html 		: Analog input monitor example page
		reg_httpServer_webContent_avr(PSTR("ain.js"), PSTR(wiz550web_ain_js));			// ain.js 			: JavaScript for Analog input monitor	(+ ajax.js)
		//reg_httpServer_webContent((uint8_t *)"ain.html", (uint8_t *)ain_page);					// ain.html 		: Analog input monitor example page
		//reg_httpServer_webContent((uint8_t *)"ain.js", (uint8_t *)wiz550web_ain_js);			// ain.js 			: JavaScript for Analog input monitor	(+ ajax.js)

		// Example #3
		reg_httpServer_webContent_avr(PSTR("ain_gauge.html"), PSTR(ain_gauge_page));		// ain_gauge.html 	: Analog input monitor example page; using Google Gauge chart
		reg_httpServer_webContent_avr(PSTR("ain_gauge.js"), PSTR(ain_gauge_js));			// ain_gauge.js 	: JavaScript for Google Gauge chart		(+ ajax.js)
		//reg_httpServer_webContent((uint8_t *)"ain_gauge.html", (uint8_t *)ain_gauge_page);		// ain_gauge.html 	: Analog input monitor example page; using Google Gauge chart
		//reg_httpServer_webContent((uint8_t *)"ain_gauge.js", (uint8_t *)ain_gauge_js);			// ain_gauge.js 	: JavaScript for Google Gauge chart		(+ ajax.js)

#ifdef _MAIN_DEBUG_
		//display_reg_webContent_list();
		display_reg_webContent_list_avr();
#endif
	}
//**************************************HTTPD init: END

	/* Loopback Test: TCP Server and UDP */
	// Test for Ethernet data transfer validation
	//uint32_t timer_link_1sec = millis();
	uint32_t timer_httpd_1sec = millis();
	bool run_user_applications = true;
	while(1)
	{
		//Here at least every 1sec
		wdt_reset(); // WDT reset at least every sec

    	/* HTTPD */
		/*HTTPD timer 1 sec interval tick*/
    	if((millis()-timer_httpd_1sec)> 1000)
		{
    		//here every 1 sec
    		timer_httpd_1sec = millis();
    		////////////////////////////////////////////////////////
    		// SHOULD BE Added HTTP Server Time Handler to your 1s tick timer
    		httpServer_time_handler(); 	// for HTTP server time counter
    		////////////////////////////////////////////////////////
    		//Printout RAM usage every 1 minute
    		static uint16_t j_ram = 0;
    		if(j_ram++%60 == 0)
    		{
    			PRINTF(">> Free RAM is: %d bytes\r\n", freeRam());
    		}
		}

    	// TODO: insert user's code here
    	if(run_user_applications)
    	{
    		//for(i = 0; i < MAX_HTTPSOCK; i++)	httpServer_run(i); 	// HTTP Server handler
    		for(i = 0; i < MAX_HTTPSOCK; i++)	httpServer_run_avr(i); 	// HTTP Server handler avr optimized

    		//loopback_tcps(SOCK_TCPS, RX_BUF, 5000); //not used here

    	} // End of user's code

		//Use Hercules Terminal to check loopback tcp:5000 and udp:3000
		/*
		 * https://www.hw-group.com/software/hercules-setup-utility
		 * */
		//loopback_tcps(0,ethBuf0,5000);
		//loopback_udps(1, ethBuf1, 3000);

		//Use WEBbrowser to connect to webserver: http://192.168.0.199/index.html
		//websrv_simple(2, ethBuf2_WEBSRV, 80);


		//loopback_ret = loopback_tcpc(SOCK_TCPS, gDATABUF, destip, destport);
		//if(loopback_ret < 0) printf("loopback ret: %ld\r\n", loopback_ret); // TCP Socket Error code

		//Not used here, because led1 handle via websrv
		/*
		if((millis()-timer_link_1sec)> 1000)
		{
			//here every 1 sec
			timer_link_1sec = millis();
			if(wizphy_getphylink() == PHY_LINK_ON)
			{
				led1_high();
			}
			else
			{
				led1_low();
			}
		}
		*/

	}
	return 0;
}

// Timer0
// 1ms IRQ
// Used for millis() timing
void timer0_init(void)
{
	/*
	 *
	 * For M128
	TCCR0 = (1<<CS02)|(1<<WGM01); //TIMER0 SET-UP: CTC MODE & PS 1:64
	OCR0 = 249; // 1ms reach for clear (16mz:64=>250kHz:250-=>1kHz)
	TIMSK |= 1<<OCIE0;	 //IRQ on TIMER0 output compare
	 */
	//For M664p
	TCCR0A = (1<<WGM01); //TIMER0 SET-UP: CTC MODE
	TCCR0B = (1<<CS01)|(1<<CS00); // PS 1:64
	OCR0A = 249; // 1ms reach for clear (16mz:64=>250kHz:250-=>1kHz)
	TIMSK0 |= 1<<OCIE0A;	 //IRQ on TIMER0 output compareA
}

static void avr_init(void)
{
	// Initialize device here.
	// WatchDog INIT
	wdt_enable(WDTO_8S);  // set up wdt reset interval 2 second
	wdt_reset(); // wdt reset ~ every <2000ms

	timer0_init();// Timer0 millis engine init

	// Initial UART Peripheral
	/*
	 *  Initialize uart11 library, pass baudrate and AVR cpu clock
	 *  with the macro
	 *  uart1_BAUD_SELECT() (normal speed mode )
	 *  or
	 *  uart1_BAUD_SELECT_DOUBLE_SPEED() ( double speed mode)
	 */
#if	(UART_BAUD_RATE == 115200)
	uart_init( UART_BAUD_SELECT_DOUBLE_SPEED(UART_BAUD_RATE,F_CPU) ); // To works without error on 115200 bps/F_CPU=16Mhz
#else
	uart_init( UART_BAUD_SELECT(UART_BAUD_RATE,F_CPU) );
#endif
	// Define Output/Input Stream
	stdout = &uart0_stdout;

	//ADC init
	adc_init();
	adc_read(6); //Dummy read


	led1_conf();
	led1_low();// LED1 is OFF


	sw1_conf();//SW1 internal pull-up

	sei(); //re-enable global interrupts

	return;
}

void print_network_information(void)
{

	uint8_t tmpstr[6] = {0,};
	ctlwizchip(CW_GET_ID,(void*)tmpstr); // Get WIZCHIP name
    PRINTF("\r\n=======================================\r\n");
    PRINTF(" WIZnet chip:  %s \r\n", tmpstr);
    PRINTF("=======================================\r\n");

	wiz_NetInfo gWIZNETINFO;
	wizchip_getnetinfo(&gWIZNETINFO);
	if (gWIZNETINFO.dhcp == NETINFO_STATIC)
		PRINTF("STATIC IP\r\n");
	else
		PRINTF("DHCP IP\r\n");
	PRINTF("Mac address: %02x:%02x:%02x:%02x:%02x:%02x\n\r",gWIZNETINFO.mac[0],gWIZNETINFO.mac[1],gWIZNETINFO.mac[2],gWIZNETINFO.mac[3],gWIZNETINFO.mac[4],gWIZNETINFO.mac[5]);
	PRINTF("IP address : %d.%d.%d.%d\n\r",gWIZNETINFO.ip[0],gWIZNETINFO.ip[1],gWIZNETINFO.ip[2],gWIZNETINFO.ip[3]);
	PRINTF("SM Mask	   : %d.%d.%d.%d\n\r",gWIZNETINFO.sn[0],gWIZNETINFO.sn[1],gWIZNETINFO.sn[2],gWIZNETINFO.sn[3]);
	PRINTF("Gate way   : %d.%d.%d.%d\n\r",gWIZNETINFO.gw[0],gWIZNETINFO.gw[1],gWIZNETINFO.gw[2],gWIZNETINFO.gw[3]);
	PRINTF("DNS Server : %d.%d.%d.%d\n\r",gWIZNETINFO.dns[0],gWIZNETINFO.dns[1],gWIZNETINFO.dns[2],gWIZNETINFO.dns[3]);
}