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Zigbee cli how to automatically deal with, discover, bind and other work, how to automatically bind multiple devices, is this way suitable for low power?I wrote a piece of code that handled it automatically, but it was very unstable.Ieee request not succes

/**
 * Copyright (c) 2018 - 2019, Nordic Semiconductor ASA
 *
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without modification,
 * are permitted provided that the following conditions are met:
 *
 * 1. Redistributions of source code must retain the above copyright notice, this
 *    list of conditions and the following disclaimer.
 *
 * 2. Redistributions in binary form, except as embedded into a Nordic
 *    Semiconductor ASA integrated circuit in a product or a software update for
 *    such product, must reproduce the above copyright notice, this list of
 *    conditions and the following disclaimer in the documentation and/or other
 *    materials provided with the distribution.
 *
 * 3. Neither the name of Nordic Semiconductor ASA nor the names of its
 *    contributors may be used to endorse or promote products derived from this
 *    software without specific prior written permission.
 *
 * 4. This software, with or without modification, must only be used with a
 *    Nordic Semiconductor ASA integrated circuit.
 *
 * 5. Any software provided in binary form under this license must not be reverse
 *    engineered, decompiled, modified and/or disassembled.
 *
 * THIS SOFTWARE IS PROVIDED BY NORDIC SEMICONDUCTOR ASA "AS IS" AND ANY EXPRESS
 * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 * OF MERCHANTABILITY, NONINFRINGEMENT, AND FITNESS FOR A PARTICULAR PURPOSE ARE
 * DISCLAIMED. IN NO EVENT SHALL NORDIC SEMICONDUCTOR ASA OR CONTRIBUTORS BE
 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE
 * GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 *
 */
/** @file
 *
 * @defgroup zigbee_examples_cli_agent_router main.c
 * @{
 * @ingroup zigbee_examples
 * @brief CLI agent for probing the Zigbee network.
 */
#include "zb_error_handler.h"
#include "sdk_config.h"
#include "zboss_api.h"

#ifdef ZIGBEE_MEM_CONFIG_MODEL
#if (ZIGBEE_MEM_CONFIG_MODEL == 0)
/* None of the files zb_mem_config_*.h included, use default memory settings */
#elif (ZIGBEE_MEM_CONFIG_MODEL == 1)
#include "zb_mem_config_min.h"
#elif (ZIGBEE_MEM_CONFIG_MODEL == 2)
#include "zb_mem_config_med.h"
#elif (ZIGBEE_MEM_CONFIG_MODEL == 3)
#include "zb_mem_config_max.h"
#else
#error ZIGBEE_MEM_CONFIG_MODEL unsupported value, please check sdk_config.h
#endif
#endif

#include "zb_ha_configuration_tool.h"
#include "zigbee_helpers.h"
#include "zigbee_cli.h"

#include "nrf_drv_clock.h"
#include "boards.h"
#include "app_timer.h"

#include "nrf_log.h"
#include "nrf_log_ctrl.h"
#include "nrf_log_default_backends.h"
#include "bsp.h"


#include "nrf_drv_swI2c.h"
#include "oledfont.h"
#include "nrf_delay.h"

#include "zboss_api_zdo.h"


#define MAX_CHILDREN                      10    
#define IEEE_CHANNEL_MASK                   (1l << ZIGBEE_CHANNEL)              /**< Scan only one, predefined channel to find the coordinator. */
#define ERASE_PERSISTENT_CONFIG             ZB_FALSE                              /**< Do not erase NVRAM to save the network parameters after device reboot or power-off. NOTE: If this option is set to ZB_TRUE then do full device erase for all network devices before running other samples. */
#define ZIGBEE_NETWORK_STATE_LED            BSP_BOARD_LED_2                     /**< LED indicating that light switch successfully joind ZigBee network. */
zb_ieee_addr_t        ieee_addr_req;



//my


#define ZIGBEE_CONFIGURE_REPORT_TSN                  3




// Defines how long to wait, in seconds, for Configure Reporting Response.
#define ZIGBEE_CLI_CONFIGURE_REPORT_RESP_TIMEOUT         5

// Defines default value for minimum interval inside configure reporting request.
#define ZIGBEE_CLI_CONFIGURE_REPORT_DEFAULT_MIN_INTERVAL 1
// Defines default value for maximum interval inside configure reporting request.
#define ZIGBEE_CLI_CONFIGURE_REPORT_DEFAULT_MAX_INTERVAL 60

// Defines default value for minimum value change inside configure reporting request.
#define ZIGBEE_CLI_CONFIGURE_REPORT_DEFAULT_VALUE_CHANGE NULL
#define NRF_LOG_SUBMODULE_NAME report



 zb_ieee_addr_t iees;
zb_uint16_t short_addr;
char ieee_addr_buf[17] = {0};
zb_ieee_addr_t dst_ieee_addr;

zb_ieee_addr_t ieee_addr;
zb_uint8_t param_sb;


#define BMS_TEMP_ENDPOINT                 10
#define ZIGBEE_CLI_BIND_RESP_TIMEOUT       5
#define MATCH_DESC_REQ_ROLE                 ZB_NWK_BROADCAST_ALL_DEVICES   
#define ZIGBEE_MANUAL_STEERING            ZB_FALSE   
#define MATCH_DESC_REQ_START_DELAY          (2 * ZB_TIME_ONE_SECOND)            //< Delay between the light switch startup and light bulb finding procedure.
#define MATCH_DESC_REQ_TIMEOUT              (5 * ZB_TIME_ONE_SECOND)  

#define BIND_DESC_REQ_START_DELAY          (4 * ZB_TIME_ONE_SECOND)            //< Delay between the light switch startup and light bulb finding procedure.
#define BIND_DESC_REQ_TIMEOUT              (7 * ZB_TIME_ONE_SECOND)  



static uint16_t iter = 0;

static zb_void_t find_timeout(zb_uint8_t param);
static zb_void_t bint_sensor_timeout(zb_uint8_t param);
static zb_void_t zb_subscribe_timeout(zb_uint8_t param);
typedef struct {
    zb_uint16_t profile_id;
    zb_uint16_t cluster_id;
    zb_uint16_t attr_id;
    zb_uint8_t  attr_type;
    zb_uint16_t interval_min;
    zb_uint16_t interval_max;
    zb_addr_u   remote_node;
    addr_type_t remote_addr_mode;
    zb_uint8_t  remote_ep;
} configure_reporting_req_t;

typedef struct sensor_params_s
{
	zb_uint8_t  bind_ret_ok;
  zb_uint8_t  endpoint;
  zb_uint16_t short_addr;
  zb_uint16_t mac_addr;
  zb_ieee_addr_t scr_ieee_addr;
  uint8_t           tsn;
} sensor_params_t;

typedef struct sensor_button_s
{
  zb_bool_t in_progress;
  zb_time_t timestamp;
} sensor_button_t;

typedef struct sensor_ctx_s
{
  sensor_params_t sensor_params;
  sensor_button_t      button;
} sensor_ctx_t;

static sensor_ctx_t m_device_ctx;



typedef struct {
    //nrf_cli_t const * p_cli;
    uint8_t           tsn;
    bool              taken;
    bool              is_broadcast;
} tsn_ctx_t_my;










uint16_t devList[500] = {0};

//my

zb_uint8_t zb_param;

static zb_void_t bind_sensor(zb_uint8_t param);
static zb_void_t zcl_device_cb(zb_uint8_t param);
static tsn_ctx_t_my m_tsn_ctx[ZIGBEE_CONFIGURE_REPORT_TSN];
static void sensor_subscribe(zb_uint8_t param);









#if !defined ZB_ROUTER_ROLE
#error Define ZB_ROUTER_ROLE to compile CLI agent (Router) source code.
#endif

static zb_uint8_t         m_attr_zcl_version   = ZB_ZCL_VERSION;
static zb_uint8_t         m_attr_power_source  = ZB_ZCL_BASIC_POWER_SOURCE_UNKNOWN;
static zb_uint16_t        m_attr_identify_time = 0;

/* Declare attribute list for Basic cluster. */
ZB_ZCL_DECLARE_BASIC_ATTRIB_LIST(basic_attr_list, &m_attr_zcl_version, &m_attr_power_source);

/* Declare attribute list for Identify cluster. */
ZB_ZCL_DECLARE_IDENTIFY_ATTRIB_LIST(identify_attr_list, &m_attr_identify_time);

/* Declare cluster list for CLI Agent device. */
/* Only clusters Identify and Basic have attributes. */
ZB_HA_DECLARE_CONFIGURATION_TOOL_CLUSTER_LIST(cli_agent_clusters,
                                              basic_attr_list,
                                              identify_attr_list);

/* Declare endpoint for CLI Agent device. */
ZB_HA_DECLARE_CONFIGURATION_TOOL_EP(cli_agent_ep,
                                    ZIGBEE_CLI_ENDPOINT,
                                    cli_agent_clusters);

/* Declare application's device context (list of registered endpoints) for CLI Agent device. */
ZB_HA_DECLARE_CONFIGURATION_TOOL_CTX(cli_agent_ctx, cli_agent_ep);






static void log_init(void)
{
    ret_code_t err_code = NRF_LOG_INIT(NULL);
    APP_ERROR_CHECK(err_code);

    NRF_LOG_DEFAULT_BACKENDS_INIT();
}



//my

//�ϱ�

//oled

#define OLED_CMD  0	//���
#define OLED_DATA 1	//���
#define Max_Column	128



void Write_IIC_Command(unsigned char IIC_Command)
{
   nrf_drv_swI2c_start();
   nrf_drv_swI2c_writeByte(0x78);            //Slave address,SA0=0
	nrf_drv_swI2c_wait_ack();	
   nrf_drv_swI2c_writeByte(0x00);			//write command
	nrf_drv_swI2c_wait_ack();	
   nrf_drv_swI2c_writeByte(IIC_Command); 
	nrf_drv_swI2c_wait_ack();	
   nrf_drv_swI2c_stop();
}
/**********************************************
// IIC Write Data
**********************************************/
void Write_IIC_Data(unsigned char IIC_Data)
{
   nrf_drv_swI2c_start();
   nrf_drv_swI2c_writeByte(0x78);			//D/C#=0; R/W#=0
	nrf_drv_swI2c_wait_ack();	
   nrf_drv_swI2c_writeByte(0x40);			//write data
	nrf_drv_swI2c_wait_ack();	
   nrf_drv_swI2c_writeByte(IIC_Data);
	nrf_drv_swI2c_wait_ack();	
   nrf_drv_swI2c_stop();
}
void OLED_WR_Byte(unsigned dat,unsigned cmd)
{
	if(cmd)
			{

		Write_IIC_Data(dat);
   
		}
	else {
   Write_IIC_Command(dat);
		
	}


}

void OLED_Init(void)
{
	OLED_WR_Byte(0xAE,OLED_CMD);//--display off
	OLED_WR_Byte(0x02,OLED_CMD);//---set low column address
	OLED_WR_Byte(0x10,OLED_CMD);//---set high column address
	OLED_WR_Byte(0x40,OLED_CMD);//--set start line address  
	OLED_WR_Byte(0xB0,OLED_CMD);//--set page address
	OLED_WR_Byte(0x81,OLED_CMD); // contract control
	OLED_WR_Byte(0xFF,OLED_CMD);//--128   
	OLED_WR_Byte(0xA1,OLED_CMD);//set segment remap 
	OLED_WR_Byte(0xA6,OLED_CMD);//--normal / reverse
	OLED_WR_Byte(0xA8,OLED_CMD);//--set multiplex ratio(1 to 64)
	OLED_WR_Byte(0x3F,OLED_CMD);//--1/32 duty
	OLED_WR_Byte(0xC8,OLED_CMD);//Com scan direction
	OLED_WR_Byte(0xD3,OLED_CMD);//-set display offset
	OLED_WR_Byte(0x00,OLED_CMD);//
	
	OLED_WR_Byte(0xD5,OLED_CMD);//set osc division
	OLED_WR_Byte(0x80,OLED_CMD);//
	
	OLED_WR_Byte(0xD8,OLED_CMD);//set area color mode off
	OLED_WR_Byte(0x05,OLED_CMD);//
	
	OLED_WR_Byte(0xD9,OLED_CMD);//Set Pre-Charge Period
	OLED_WR_Byte(0xF1,OLED_CMD);//
	
	OLED_WR_Byte(0xDA,OLED_CMD);//set com pin configuartion
	OLED_WR_Byte(0x12,OLED_CMD);//
	
	OLED_WR_Byte(0xDB,OLED_CMD);//set Vcomh
	OLED_WR_Byte(0x30,OLED_CMD);//
	
	OLED_WR_Byte(0x8D,OLED_CMD);//set charge pump enable
	OLED_WR_Byte(0x14,OLED_CMD);//
	
	OLED_WR_Byte(0xAF,OLED_CMD);//--turn on oled panel
}

//��������

	void OLED_Set_Pos(unsigned char x, unsigned char y) 
{ 
	OLED_WR_Byte(0xb0+y,OLED_CMD);
	OLED_WR_Byte((((x+2)&0xf0)>>4)|0x10,OLED_CMD);
	OLED_WR_Byte(((x+2)&0x0f),OLED_CMD); 
}   	  
//����OLED��ʾ    
void OLED_Display_On(void)
{
	OLED_WR_Byte(0X8D,OLED_CMD);  //SET DCDC����
	OLED_WR_Byte(0X14,OLED_CMD);  //DCDC ON
	OLED_WR_Byte(0XAF,OLED_CMD);  //DISPLAY ON
}
//�ر�OLED��ʾ     
void OLED_Display_Off(void)
{
	OLED_WR_Byte(0X8D,OLED_CMD);  //SET DCDC����
	OLED_WR_Byte(0X10,OLED_CMD);  //DCDC OFF
	OLED_WR_Byte(0XAE,OLED_CMD);  //DISPLAY OFF
}		   			 
//��������,������,������Ļ�Ǻ�ɫ��!��û����һ��!!!
void OLED_Clear(void)  
{  
	uint8_t i,n;		    
	for(i=0;i<8;i++)  
	{  
		OLED_WR_Byte (0xb0+i,OLED_CMD);    //����ҳ��ַ��0~7��
		OLED_WR_Byte (0x02,OLED_CMD);      //������ʾλ�á��е͵�ַ
		OLED_WR_Byte (0x10,OLED_CMD);      //������ʾλ�á��иߵ�ַ   
		for(n=0;n<128;n++)OLED_WR_Byte(0,OLED_DATA); 
	} //������ʾ
}
void OLED_On(void)  
{  
	uint8_t i,n;		    
	for(i=0;i<8;i++)  
	{  
		OLED_WR_Byte (0xb0+i,OLED_CMD);    //����ҳ��ַ��0~7��
		OLED_WR_Byte (0x02,OLED_CMD);      //������ʾλ�á��е͵�ַ
		OLED_WR_Byte (0x10,OLED_CMD);      //������ʾλ�á��иߵ�ַ   
		for(n=0;n<128;n++)OLED_WR_Byte(1,OLED_DATA); 
	} //������ʾ
}


void OLED_ShowChar(uint8_t x,uint8_t y,uint8_t chr,uint8_t Char_Size)
{      	
	unsigned char c=0,i=0;	
		c=chr-' ';//�õ�ƫ�ƺ��ֵ			
		if(x>Max_Column-1){x=0;y=y+2;}
		if(Char_Size ==16)
			{
			OLED_Set_Pos(x,y);	
			for(i=0;i<8;i++)
			OLED_WR_Byte(F8X16[c*16+i],OLED_DATA);
			OLED_Set_Pos(x,y+1);
			for(i=0;i<8;i++)
			OLED_WR_Byte(F8X16[c*16+i+8],OLED_DATA);
			}
			else {	
				OLED_Set_Pos(x,y);
				for(i=0;i<6;i++)
				OLED_WR_Byte(F6x8[c][i],OLED_DATA);
				
			}
}
void OLED_ShowString(uint8_t x,uint8_t y,uint8_t *chr,uint8_t Char_Size)
{
	unsigned char j=0;
	while (chr[j]!='\0')
	{		OLED_ShowChar(x,y,chr[j],Char_Size);
			x+=8;
		if(x>120){x=0;y+=2;}
			j++;
	}
}

uint32_t oled_pow(uint8_t m,uint8_t n)
{
	uint32_t result=1;	 
	while(n--)result*=m;    
	return result;
}				  
//��ʾ2������
//x,y :�������	 
//len :���ֵ�λ��
//size:�����С
//mode:ģʽ	0,���ģʽ;1,����ģʽ
//num:��ֵ(0~4294967295);	 		  
void OLED_ShowNum(uint8_t x,uint8_t y,uint32_t num,uint8_t len,uint8_t size2)
{         	
	uint8_t t,temp;
	uint8_t enshow=0;						   
	for(t=0;t<len;t++)
	{
		temp=(num/oled_pow(10,len-t-1))%10;
		if(enshow==0&&t<(len-1))
		{
			if(temp==0)
			{
				OLED_ShowChar(x+(size2/2)*t,y,' ',size2);
				continue;
			}else enshow=1; 
		 	 
		}
	 	OLED_ShowChar(x+(size2/2)*t,y,temp+'0',size2); 
	}
} 
//��ʾһ���ַ��Ŵ�

int zcl_attr_tostr(char * p_str_buf, uint16_t buf_len, zb_uint16_t attr_type, zb_uint8_t * p_attr)
{
    int bytes_written = 0;
    int string_len;
    int i;

    if ((p_str_buf == NULL) || (p_attr == NULL))
    {
        return -1;
    }

    switch (attr_type)
    {
        /* Boolean */
        case ZB_ZCL_ATTR_TYPE_BOOL:
            bytes_written = snprintf(p_str_buf, buf_len, "%s", *((zb_bool_t *)p_attr) ? "True" : "False");
            break;

        /* 1 byte */
        case ZB_ZCL_ATTR_TYPE_8BIT:
        case ZB_ZCL_ATTR_TYPE_8BITMAP:
        case ZB_ZCL_ATTR_TYPE_U8:
        case ZB_ZCL_ATTR_TYPE_8BIT_ENUM:
            bytes_written = snprintf(p_str_buf, buf_len, "%hu", *((zb_uint8_t*)p_attr));
            break;

        case ZB_ZCL_ATTR_TYPE_S8:
            bytes_written = snprintf(p_str_buf, buf_len, "%hd", *((zb_int8_t*)p_attr));
            break;

        /* 2 bytes */
        case ZB_ZCL_ATTR_TYPE_16BIT:
        case ZB_ZCL_ATTR_TYPE_16BITMAP:
        case ZB_ZCL_ATTR_TYPE_U16:
        case ZB_ZCL_ATTR_TYPE_16BIT_ENUM:
            bytes_written = snprintf(p_str_buf, buf_len, "%hu", *((zb_uint16_t*)p_attr));
            break;

        case ZB_ZCL_ATTR_TYPE_S16:
            bytes_written = snprintf(p_str_buf, buf_len, "%hd", *((zb_int16_t*)p_attr));
            break;

        /* 4 bytes */
        case ZB_ZCL_ATTR_TYPE_32BIT:
        case ZB_ZCL_ATTR_TYPE_32BITMAP:
        case ZB_ZCL_ATTR_TYPE_U32:
            bytes_written = snprintf(p_str_buf, buf_len, "%u", *((zb_uint32_t*)p_attr));
            break;

        case ZB_ZCL_ATTR_TYPE_S32:
            bytes_written = snprintf(p_str_buf, buf_len, "%d", *((zb_int32_t*)p_attr));
            break;

        /* String */
        case ZB_ZCL_ATTR_TYPE_CHAR_STRING:
            string_len = p_attr[0];
            p_attr++;

            if ((buf_len - bytes_written) < (string_len + 1))
            {
                return -1;
            }

            for (i = 0; i < string_len; i++)
            {
                /*lint -save -e661 */
                p_str_buf[bytes_written + i] = ((char *)p_attr)[i];
                /*lint -restore */
            }
            p_str_buf[bytes_written + i] = '\0';
            bytes_written += string_len + 1;
            break;

        case ZB_ZCL_ATTR_TYPE_IEEE_ADDR:
            /*lint -e661 -e662 -save */
            bytes_written = to_hex_str(p_str_buf, buf_len, (const uint8_t *)p_attr, sizeof(zb_64bit_addr_t), true);
            /*lint -restore */
            break;

        default:
            bytes_written = snprintf(p_str_buf, buf_len, "Value type 0x%x unsupported", attr_type);
            break;
    }

    return bytes_written;
}

static void print_attr(zb_zcl_parsed_hdr_t * p_zcl_hdr, zb_uint8_t param)
{
      zb_buf_t                 * p_buf         = ZB_BUF_FROM_REF(param);
    zb_zcl_report_attr_req_t * p_attr_resp   = NULL;
    int                        bytes_written = 0;
    char                       print_buf[255];

    if (p_zcl_hdr->addr_data.common_data.source.addr_type == ZB_ZCL_ADDR_TYPE_SHORT)
    {
        NRF_LOG_INFO( "Received value  node 0x%04x",
                         p_zcl_hdr->addr_data.common_data.source.u.short_addr);
    }
    else
    {
        bytes_written = ieee_addr_to_str(print_buf, sizeof(print_buf), p_zcl_hdr->addr_data.common_data.source.u.ieee_addr);
        if (bytes_written < 0)
        {
           NRF_LOG_INFO( "Received value updates from the remote node (unknown address)");
        }
        else
        {
            NRF_LOG_INFO( "Received value updates from node 0x%s", nrf_log_push(print_buf));
        }
    }

//
    ZB_ZCL_GENERAL_GET_NEXT_REPORT_ATTR_REQ(p_buf, p_attr_resp);


    NRF_LOG_INFO("Profile: 0x%04x Cluster: 0x%04x Attribute: 0x%04x Type: %hu Valuesss: %s",
                p_zcl_hdr->profile_id, p_zcl_hdr->cluster_id, p_attr_resp->attr_id,
               p_attr_resp->attr_type, nrf_log_push(print_buf));
    bytes_written = 0;
    while (p_attr_resp != NULL)
    {
        bytes_written = zcl_attr_tostr(&print_buf[bytes_written],
                                        sizeof(print_buf) - bytes_written,
                                        p_attr_resp->attr_type,
                                        p_attr_resp->attr_value);

        if (bytes_written < 0)
        {
            NRF_LOG_ERROR("Unable to print updated attribute value");
        }
        else
        {    //NRF_LOG_INFO
            NRF_LOG_INFO("Profile: 0x%04x Cluster: 0x%04x Attribute: 0x%04x Type: %hu Value: %s",
                p_zcl_hdr->profile_id, p_zcl_hdr->cluster_id, p_attr_resp->attr_id,
               p_attr_resp->attr_type, nrf_log_push(print_buf));
        }

        ZB_ZCL_GENERAL_GET_NEXT_REPORT_ATTR_REQ(p_buf, p_attr_resp);
    }
    




}



















static void zb_subscribe_unsubscribe_cb(zb_uint8_t param)
{
    zb_ret_t                           zb_err_code;
    zb_buf_t                         * p_buf  = ZB_BUF_FROM_REF(param);
    zb_zcl_configure_reporting_res_t * p_resp = NULL;
    zb_bool_t                          failed = ZB_FALSE;
   


     NRF_LOG_INFO("  reporting  callback ");
    zb_err_code = ZB_SCHEDULE_ALARM_CANCEL(zb_subscribe_timeout, ZB_ALARM_ANY_PARAM);
    if (zb_err_code != RET_OK)
    {
    //    print_error(p_tsn_ctx->p_cli, "Unable to cancel timeout timer");
      //  goto free_tsn_ctx;

       NRF_LOG_INFO("Unable to cancel timeout timer");

    }

    // Check if response contains only status code.
    if (sizeof(zb_zcl_configure_reporting_res_t) > ZB_BUF_LEN(p_buf))
    {
        p_resp = (zb_zcl_configure_reporting_res_t*)ZB_BUF_BEGIN(p_buf);
        if (p_resp->status == ZB_ZCL_STATUS_SUCCESS)
        {
          

          NRF_LOG_INFO("  reporting   is ok ");
           

        }
        else
        {
           NRF_LOG_INFO( "Error: Unable to configure reporting. Status: %d", p_resp->status);
        }
     
    }


    // Received a full Configure Reporting Response frame.
    ZB_ZCL_GENERAL_GET_NEXT_CONFIGURE_REPORTING_RES(p_buf, p_resp);
    if (p_resp == NULL)
    {
       

      NRF_LOG_INFO("Unable to parse configure reporting response");

    }


    while (p_resp != NULL)
    {
        if (p_resp->status == ZB_ZCL_STATUS_SUCCESS)
        {
            switch (p_resp->direction)
            {
                case ZB_ZCL_CONFIGURE_REPORTING_SEND_REPORT:
                 NRF_LOG_INFO("Local subscription to attribute ID %hx updated\r\n",p_resp->attr_id);
                    break;

                case ZB_ZCL_CONFIGURE_REPORTING_RECV_REPORT:
              NRF_LOG_INFO( "Remote node subscription to receive attribute ID %hx updated\r\n",   p_resp->attr_id);
                    break;

                default:
                    NRF_LOG_INFO( "Unknown reporting configuration direction for attribute %hx",p_resp->attr_id);
                    failed = ZB_TRUE;
                    break;
            }
        }
        else
        {
            NRF_LOG_INFO( "Unable to configure attribute %hx reporting. Status: %hd\r\n",  p_resp->attr_id, p_resp->status);


            failed = ZB_TRUE;
        }
        ZB_ZCL_GENERAL_GET_NEXT_CONFIGURE_REPORTING_RES(p_buf, p_resp);
    }

    if (failed == ZB_TRUE)
    {
       

        NRF_LOG_INFO("One or more attributes reporting were not configured successfully");

    }
    else
    {
        //print_done(p_tsn_ctx->p_cli, ZB_FALSE);
    }

//free_tsn_ctx:
  //  invalidate_ctx(p_tsn_ctx);
    ZB_FREE_BUF_BY_REF(param);





}

static void zb_ieee_addr_req(zb_uint8_t param);

static void zb_ieee_addr_timeout(zb_uint8_t param)
{
    zb_ret_t                  zb_err_code;


if(param)
{
  
  
         NRF_LOG_INFO("ieee addrss req timeout ");
  
        zb_err_code = ZB_SCHEDULE_ALARM(zb_ieee_addr_req, param, MATCH_DESC_REQ_START_DELAY);
        ZB_ERROR_CHECK(zb_err_code);
        zb_err_code = ZB_SCHEDULE_ALARM(zb_ieee_addr_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
        ZB_ERROR_CHECK(zb_err_code);



}
else
{

       zb_err_code = ZB_GET_OUT_BUF_DELAYED(zb_ieee_addr_timeout);
        ZB_ERROR_CHECK(zb_err_code);



}






}











zb_void_t ieee_addr_callback(zb_uint8_t param)
{




    NRF_LOG_INFO("ieee addrss callback  ");
    zb_buf_t                * p_buf  = ZB_BUF_FROM_REF(param);
    zb_zdo_ieee_addr_resp_t * p_resp = (zb_zdo_ieee_addr_resp_t *)ZB_BUF_BEGIN(p_buf);
    zb_ret_t                  zb_err_code;
    if (p_resp->status == ZB_ZDP_STATUS_SUCCESS)
    {
        zb_address_ieee_ref_t addr_ref_req;
        
        zb_uint16_t           nwk_addr_req;
        zb_ret_t              ret;

        ZB_LETOH64(ieee_addr_req, p_resp->ieee_addr_remote_dev);

        
        ZB_LETOH16(&nwk_addr_req, &(p_resp->nwk_addr_remote_dev));
        NRF_LOG_INFO("ieee req :%d",(const uint8_t *)ieee_addr_req);
			

			
        ret = zb_address_update(ieee_addr_req, nwk_addr_req, ZB_TRUE, &addr_ref_req);
        if (ret == RET_OK)
        {
					
	 NRF_LOG_INFO("ieee req is ok");
					
          NRF_LOG_INFO("ieee req :%d",(const uint8_t *)ieee_addr_req);
          zb_err_code = ZB_SCHEDULE_ALARM_CANCEL(zb_ieee_addr_timeout, ZB_ALARM_ANY_PARAM);         
        
        }else{

          NRF_LOG_INFO("ieee req :%d", p_resp->status);


        }
        




     }
   

   ZB_FREE_BUF_BY_REF(param);
		 
		 //sensor_subscribe
		 
		//zb_subscribe_timeout




		 
      if(m_device_ctx.sensor_params.short_addr != 0x0000)
								 {
									 
	    NRF_LOG_INFO("bind    .........");
					
        zb_err_code = ZB_SCHEDULE_ALARM(bind_sensor, param, MATCH_DESC_REQ_START_DELAY);
        ZB_ERROR_CHECK(zb_err_code);
        zb_err_code = ZB_SCHEDULE_ALARM(bint_sensor_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
        ZB_ERROR_CHECK(zb_err_code);
      			 
								 }
		 
		 
		 
		 
		 
		 
		 
		 
		 
   


}


static void zb_ieee_addr_req(zb_uint8_t param)
{

       zb_buf_t   * p_buf=NULL;
       p_buf=ZB_GET_OUT_BUF();
       if(p_buf==NULL)
       {

         NRF_LOG_INFO("not bind command ");
       
       }
	   
	
   zb_zdo_ieee_addr_req_t *req_t=ZB_GET_BUF_PARAM(p_buf, zb_zdo_ieee_addr_req_t);



   NRF_LOG_INFO("ieee addrss req");

  // zb_buf_t * buf=ZB_GET_OUT_BUF();
   //zb_zdo_ieee_addr_req_t *req_t=NULL;
   //ZB_BUF_INITIAL_ALLOC(buf,sizeof(zb_zdo_ieee_addr_req_t),req_t);
   
  
   req_t->start_index=0;
   req_t->request_type=0;
   req_t->nwk_addr=m_device_ctx.sensor_params.short_addr;
    
   m_device_ctx.sensor_params.tsn=zb_zdo_ieee_addr_req(ZB_REF_FROM_BUF(p_buf), ieee_addr_callback);
	
    NRF_LOG_INFO("ieee command req start  ");
  if(m_device_ctx.sensor_params.tsn==ZB_ZDO_INVALID_TSN)
  {
      NRF_LOG_INFO("ieee command   ZB_ZDO_INVALID_TSN");
  }
	
	

    ZB_FREE_BUF(p_buf);

}














static zb_uint8_t ep_report(zb_uint8_t param)
{
    zb_buf_t            * p_zcl_cmd_buf = (zb_buf_t *)ZB_BUF_FROM_REF(param);
    zb_zcl_parsed_hdr_t * p_cmd_info    = ZB_GET_BUF_PARAM(p_zcl_cmd_buf, zb_zcl_parsed_hdr_t);
    zb_uint8_t          p_tsn_ctx;

    if (p_cmd_info->cmd_id == ZB_ZCL_CMD_REPORT_ATTRIB)
    {
        print_attr(p_cmd_info, param);
        ZB_FREE_BUF_BY_REF(param);
        return ZB_TRUE;
    }
    else if (p_cmd_info->cmd_id == ZB_ZCL_CMD_CONFIG_REPORT_RESP)
    {
        // Find command context by ZCL sequence number.
        p_tsn_ctx = p_cmd_info->seq_number;
        if (p_tsn_ctx != NULL)
        {
            zb_subscribe_unsubscribe_cb(param);
            return ZB_TRUE;
        }
    }

    return ZB_FALSE;
}













static void sensor_subscribe(zb_uint8_t param)
{

    configure_reporting_req_t   req;
    zb_buf_t                  * p_buf;
    zb_uint8_t                * p_cmd_ptr;
    zb_ret_t                    zb_err_code;
    zb_bool_t                   subscribe;

    NRF_LOG_INFO("sensor_subscribe");
   // OLED_ShowString(35,0,"sensor_subscribe  in!",16);nrf_delay_ms(1);


   
     OLED_Clear();nrf_delay_us(100) ;
	    OLED_ShowString(35,0,"sensor_subscribe",26);nrf_delay_ms(1);


    req.remote_addr_mode = parse_address(ieee_addr_buf, &req.remote_node, ADDR_ANY);
     if (req.remote_addr_mode == ADDR_INVALID)
    {
       //"Invalid remote address"


       NRF_LOG_INFO("Invalid remote address");
        return;
    }


    //type for subscribe  
    
    req.remote_ep=10;
    req.cluster_id=ZB_ZCL_CLUSTER_ID_PRESSURE_MEASUREMENT;
    req.profile_id=ZB_AF_HA_PROFILE_ID;
    req.attr_id=0;
    req.attr_type=41;

    //

    req.interval_min = ZIGBEE_CLI_CONFIGURE_REPORT_DEFAULT_MIN_INTERVAL;
    req.interval_max = ZIGBEE_CLI_CONFIGURE_REPORT_DEFAULT_MAX_INTERVAL;
    //��������

    p_buf = ZB_GET_OUT_BUF();
    if(p_buf==NULL)
    {

     NRF_LOG_INFO("not sensor subscribe command *****");
   
    }




    ZB_ZCL_GENERAL_INIT_CONFIGURE_REPORTING_SRV_REQ(p_buf,
                                                    p_cmd_ptr,
                                                    ZB_ZCL_ENABLE_DEFAULT_RESPONSE);
    ZB_ZCL_GENERAL_ADD_SEND_REPORT_CONFIGURE_REPORTING_REQ(p_cmd_ptr,
        req.attr_id, req.attr_type, req.interval_min, req.interval_max,
        ZIGBEE_CLI_CONFIGURE_REPORT_DEFAULT_VALUE_CHANGE);
    ZB_ZCL_GENERAL_SEND_CONFIGURE_REPORTING_REQ(p_buf, p_cmd_ptr,
        req.remote_node, req.remote_addr_mode, req.remote_ep, 64,
        req.profile_id, req.cluster_id, NULL);
    //
   zb_err_code = ZB_SCHEDULE_ALARM(zb_subscribe_timeout, 0,ZIGBEE_CLI_CONFIGURE_REPORT_RESP_TIMEOUT * ZB_TIME_ONE_SECOND);

    if (zb_err_code != RET_OK)
    {
       NRF_LOG_INFO("Unable to schedule timeout timer");
        
    }
     



   
}

 















static zb_void_t find_sensor_cb(zb_uint8_t param)
{

  //eui64
  /*
    zb_uint16_t short_addr;
    zb_ieee_addr_t addr;
    char ieee_addr_buf[17] = {0};
    zb_get_long_address(addr);
    ieee_addr_to_str(ieee_addr_buf, sizeof(ieee_addr_buf), addr);
    NRF_LOG_INFO("eui64 out addr: %s ",NRF_LOG_PUSH(ieee_addr_buf) );

    short_addr = zb_address_short_by_ieee(addr);
     
    NRF_LOG_INFO("short out addr: %04x ", short_addr);*/
 
 //end eui64


    
    
    zb_buf_t                   * p_buf  = ZB_BUF_FROM_REF(param);                              // Resolve buffer number to buffer address
    zb_zdo_match_desc_resp_t   * p_resp = (zb_zdo_match_desc_resp_t *) ZB_BUF_BEGIN(p_buf);    // Get the begining of the response
    zb_apsde_data_indication_t * p_ind  = ZB_GET_BUF_PARAM(p_buf, zb_apsde_data_indication_t); // Get the pointer to the parameters buffer, which stores APS layer response
    zb_uint8_t                 * p_match_ep;
    zb_ret_t                     zb_err_code;
     if ((p_resp->status == ZB_ZDP_STATUS_SUCCESS) && (p_resp->match_len > 0) && (!m_device_ctx.sensor_params.short_addr))
    {
        /* Match EP list follows right after response header */
        p_match_ep = (zb_uint8_t *)(p_resp + 1);

        /* We are searching for exact cluster, so only 1 EP may be found */
        m_device_ctx.sensor_params.endpoint   = *p_match_ep;
        m_device_ctx.sensor_params.short_addr = p_ind->src_addr;
        m_device_ctx.sensor_params.mac_addr = p_ind->mac_src_addr;


        NRF_LOG_INFO("Found sensor short_addr: %04x", m_device_ctx.sensor_params.short_addr);

       

        ZB_SCHEDULE_ALARM_CANCEL(find_timeout, ZB_ALARM_ANY_PARAM);


        if(m_device_ctx.sensor_params.short_addr != 0x0000){
         NRF_LOG_INFO("IEEE  REQ sensor1 ");
					
        zb_err_code = ZB_SCHEDULE_ALARM(zb_ieee_addr_req, param, MATCH_DESC_REQ_START_DELAY);
        ZB_ERROR_CHECK(zb_err_code);
        zb_err_code = ZB_SCHEDULE_ALARM(zb_ieee_addr_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
        ZB_ERROR_CHECK(zb_err_code);



        }
       // ZB_ERROR_CHECK(zb_err_code);

      //  bsp_board_led_on(BULB_FOUND_LED);
    }

    if (param)
    {
        ZB_FREE_BUF_BY_REF(param);
    }
    






      if(m_device_ctx.sensor_params.short_addr != 0x0000)
								 {
									 
	  NRF_LOG_INFO("IEEE.......... ");
					
        zb_err_code = ZB_SCHEDULE_ALARM(zb_ieee_addr_req, param, MATCH_DESC_REQ_START_DELAY);
        ZB_ERROR_CHECK(zb_err_code);
        zb_err_code = ZB_SCHEDULE_ALARM(zb_ieee_addr_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
        ZB_ERROR_CHECK(zb_err_code);
									 
								 }






}




static zb_void_t bind_sensor_cb(zb_uint8_t param)
{


    zb_buf_t           * p_buf  = ZB_BUF_FROM_REF(param);
    zb_zdo_bind_resp_t * p_resp = (zb_zdo_bind_resp_t *)ZB_BUF_BEGIN(p_buf);
    zb_ret_t             zb_err_code;
   

    


		    m_device_ctx.sensor_params.bind_ret_ok =p_resp->status; 
		
    if (p_resp->status == ZB_ZDP_STATUS_SUCCESS)
    {
			
       ZB_FREE_BUF_BY_REF(param);	
			sensor_subscribe(param);
       
      NRF_LOG_INFO("bind_sensor is ok");
      zb_err_code = ZB_SCHEDULE_ALARM_CANCEL(bint_sensor_timeout, ZB_ALARM_ANY_PARAM);
		  
      }
    else
    {
       
     NRF_LOG_INFO("bind status %d",p_resp->status);

    }

   ZB_FREE_BUF_BY_REF(param);


}





static zb_void_t bind_sensor(zb_uint8_t param)
{ 
       //zb_buf_t                  * p_buf = ZB_BUF_FROM_REF(param); // Resolve buffer number to buffer address
    //zb_zdo_match_desc_param_t * p_req;

    /* Initialize pointers inside buffer and reserve space for zb_zdo_match_desc_param_t request */
    //UNUSED_RETURN_VALUE(ZB_BUF_INITIAL_ALLOC(p_buf, sizeof(zb_zdo_match_desc_param_t) + (1) * sizeof(zb_uint16_t), p_req));
      zb_buf_t                * p_buf=NULL;
       p_buf=ZB_GET_OUT_BUF();
       if(p_buf==NULL)
       {

         NRF_LOG_INFO("not bind command ");
       
       }
	   
	
    zb_zdo_bind_req_param_t * p_req=ZB_GET_BUF_PARAM(p_buf, zb_zdo_bind_req_param_t);
	 //UNUSED_RETURN_VALUE(ZB_BUF_INITIAL_ALLOC(p_buf, sizeof(zb_zdo_bind_req_param_t) + (1) * sizeof(zb_uint16_t), p_req));
	
	
	//=ZB_GET_BUF_PARAM(p_buf, zb_zdo_bind_req_param_t);
     zb_ret_t                  zb_err_code;
    //bind req type 
    //ZIGBEE_CLI_ENDPOINT
    // zb_apsme_binding_req_t req;
    // req = ZB_GET_BUF_PARAM(p_buf, zb_apsme_binding_req_t);

    p_req->dst_addr_mode=ZB_BIND_DST_ADDR_MODE_64_BIT_EXTENDED;//
    // p_req->dst_addr_mode= ZB_APS_ADDR_MODE_64_ENDP_PRESENT;
    //req->addr_mode = ZB_APS_ADDR_MODE_64_ENDP_PRESENT;
   NRF_LOG_INFO("bind sensor addr: %04x", m_device_ctx.sensor_params.short_addr);
   p_req->src_endp=m_device_ctx.sensor_params.endpoint;
  // p_req->src_address = parse_long_address(m_device_ctx.sensor_params.mac_addr, p_req->src_address);
 
   p_req->dst_endp=ZIGBEE_CLI_ENDPOINT;
   
   p_req->cluster_id=ZB_ZCL_CLUSTER_ID_PRESSURE_MEASUREMENT;
	 
	 
	
  
  
  

 
    ZB_MEMCPY(p_req->src_address, &ieee_addr_req, sizeof(zb_ieee_addr_t));
  
   ZB_MEMCPY(p_req->dst_address.addr_long, &ieee_addr, sizeof(zb_ieee_addr_t));
         p_req->req_dst_addr= zb_address_short_by_ieee(ieee_addr_req);

   
   
   m_device_ctx.sensor_params.tsn=zb_zdo_bind_req(ZB_REF_FROM_BUF(p_buf), bind_sensor_cb);

    NRF_LOG_INFO("bind sensor main ");
  if(m_device_ctx.sensor_params.tsn==ZB_ZDO_INVALID_TSN)
  {
    NRF_LOG_INFO("bind sensor ZB_ZDO_INVALID_TSN");
   }



   //zb_err_code = ZB_SCHEDULE_ALARM(bint_sensor_timeout,m_device_ctx.sensor_params.tsn,ZIGBEE_CLI_BIND_RESP_TIMEOUT * ZB_TIME_ONE_SECOND);
   //ZB_ERROR_CHECK(zb_err_code);
	//NRF_LOG_INFO("bind_sensor. 2");
	
	

}
static zb_void_t bint_sensor_timeout(zb_uint8_t param)

{

   zb_ret_t                  zb_err_code;
   
	
	  
	
	
	

    if(param)
    {
    
    
        NRF_LOG_INFO("bind sensor timeout ");
        zb_err_code = ZB_SCHEDULE_ALARM(bind_sensor, param, MATCH_DESC_REQ_START_DELAY );
        ZB_ERROR_CHECK(zb_err_code);
        zb_err_code = ZB_SCHEDULE_ALARM(bint_sensor_timeout, 0, MATCH_DESC_REQ_TIMEOUT );
        ZB_ERROR_CHECK(zb_err_code);
       
    
    }
    else
    {
     zb_err_code = ZB_GET_OUT_BUF_DELAYED(bint_sensor_timeout);
     ZB_ERROR_CHECK(zb_err_code);


    }



}




static zb_void_t find_sensor(zb_uint8_t param)
{


    zb_buf_t                  * p_buf = ZB_BUF_FROM_REF(param); // Resolve buffer number to buffer address
    zb_zdo_match_desc_param_t * p_req;

    /* Initialize pointers inside buffer and reserve space for zb_zdo_match_desc_param_t request */
    UNUSED_RETURN_VALUE(ZB_BUF_INITIAL_ALLOC(p_buf, sizeof(zb_zdo_match_desc_param_t) + (1) * sizeof(zb_uint16_t), p_req));

    p_req->nwk_addr         = MATCH_DESC_REQ_ROLE;              // Send to devices specified by MATCH_DESC_REQ_ROLE
    p_req->addr_of_interest = MATCH_DESC_REQ_ROLE;              // Get responses from devices specified by MATCH_DESC_REQ_ROLE
    p_req->profile_id       = ZB_AF_HA_PROFILE_ID;              // Look for Home Automation profile clusters
    // Ҫ��
    /* We are searching for 2 clusters: On/Off and Level Control Server */
    p_req->num_in_clusters  = 1;
    p_req->num_out_clusters = 0;
    /*lint -save -e415 // Suppress warning 415 "likely access of out-of-bounds pointer" */
   // p_req->cluster_list[0]  = ZB_ZCL_CLUSTER_ID_DOOR_LOCK;
    p_req->cluster_list[1]  = ZB_ZCL_CLUSTER_ID_PRESSURE_MEASUREMENT;
    /*lint -restore */
     
    NRF_LOG_INFO(" sensor short addr  %04x",m_device_ctx.sensor_params.short_addr);
    //NRF_LOG_INFO(" sensor  nwk_addr  %s",p_req->nwk_addr);

   // m_device_ctx.sensor_params.short_addr = 0x00; // Reset short address in order to parse only one response.
    UNUSED_RETURN_VALUE(zb_zdo_match_desc_req(param, find_sensor_cb));


  


}


static zb_void_t zb_subscribe_timeout(zb_uint8_t param)
{

   
    if(param)
    {
     
     NRF_LOG_INFO("zb_subscribe_timeout   time out");


    
    }
    else
    {

     
    }




}


static zb_void_t find_timeout(zb_uint8_t param)
{


 zb_ret_t zb_err_code;

    if (param)
    {  

        NRF_LOG_INFO("Found sensor addr: %04x", m_device_ctx.sensor_params.short_addr);
        NRF_LOG_INFO("sensor not found, try again");
        zb_err_code = ZB_SCHEDULE_ALARM(find_sensor, param, MATCH_DESC_REQ_START_DELAY);
        ZB_ERROR_CHECK(zb_err_code);
        zb_err_code = ZB_SCHEDULE_ALARM(find_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
        ZB_ERROR_CHECK(zb_err_code);
    }
    else
    {
        zb_err_code = ZB_GET_OUT_BUF_DELAYED(find_timeout);
        ZB_ERROR_CHECK(zb_err_code);
    }





}







/**@brief Callback used in order to visualise network steering period.
 *
 * @param[in]   param   Not used. Required by callback type definition.
 */
static zb_void_t steering_finished(zb_uint8_t param)
{
    UNUSED_PARAMETER(param);
    NRF_LOG_INFO("Network steering finished");
   // bsp_board_led_off(ZIGBEE_NETWORK_STATE_LED);
}




/**@brief Retry to form a Zigbee network. */
static zb_void_t bdb_restart_top_level_commissioning(zb_uint8_t param)
{
    UNUSED_RETURN_VALUE(bdb_start_top_level_commissioning(ZB_BDB_NETWORK_STEERING));
}

//ez mode callback























/*
static zb_void_t zcl_device_cb(zb_uint8_t param)
{
    NRF_LOG_INFO("zcl_device_cb");
   
    zb_uint8_t                       cluster_id;
    zb_uint8_t                       attr_id;
    zb_buf_t                       * p_buffer = ZB_BUF_FROM_REF(param);
    zb_zcl_device_callback_param_t * p_device_cb_param = ZB_GET_BUF_PARAM(p_buffer, zb_zcl_device_callback_param_t);

    NRF_LOG_INFO("zcl_device_cb id %hd", p_device_cb_param->device_cb_id);

   
    p_device_cb_param->status = RET_OK;
    NRF_LOG_INFO("device_cb_id: %d", p_device_cb_param->device_cb_id);

    switch (p_device_cb_param->device_cb_id)
    {
        case ZB_ZCL_SHADE_GET_VALUE_CB_ID:
            cluster_id = p_device_cb_param->cb_param.set_attr_value_param.cluster_id;
            attr_id    = p_device_cb_param->cb_param.set_attr_value_param.attr_id;
            NRF_LOG_INFO("cluster_id: %d", cluster_id);
            NRF_LOG_INFO("attr_id: %d", attr_id);
            switch (attr_id)
            {
              case ZB_ZCL_ATTR_TEMP_MEASUREMENT_VALUE_ID:
                NRF_LOG_INFO("Get temp value: %d", attr_id);
              break;
              case ZB_ZCL_ATTR_POWER_CONFIG_BATTERY_VOLTAGE_ID:
                NRF_LOG_INFO("Get bat volt value: %d", attr_id);
              break;
              default:
                NRF_LOG_INFO("Unhandled cluster attribute id: %d", cluster_id);
              break;
            }
        break;
        case ZB_ZCL_SET_ATTR_VALUE_CB_ID:
            cluster_id = p_device_cb_param->cb_param.set_attr_value_param.cluster_id;
            attr_id    = p_device_cb_param->cb_param.set_attr_value_param.attr_id;

            if (cluster_id == ZB_ZCL_CLUSTER_ID_TEMP_MEASUREMENT)
            {
                uint8_t value = p_device_cb_param->cb_param.set_attr_value_param.values.data8;

                NRF_LOG_INFO("attribute id %d", attr_id);
                if (attr_id == ZB_ZCL_ATTR_TEMP_MEASUREMENT_VALUE_ID)
                {
                    NRF_LOG_INFO("Get temp value: %d", value);
                }
            }
        default:
            p_device_cb_param->status = RET_ERROR;
            break;
    }

    NRF_LOG_INFO("zcl_device_cb status: %hd", p_device_cb_param->status);
}
*/
/*
static void buttons_handler(bsp_event_t evt)
{
    zb_ret_t   zb_err_code;
    zb_int32_t button;

    switch(evt)
    {
        case BSP_EVENT_KEY_0:
            //button = LIGHT_SWITCH_BUTTON_ON;
            break;

        case BSP_EVENT_KEY_1:
            //button = LIGHT_SWITCH_BUTTON_OFF;
            break;

        case BSP_EVENT_KEY_2:
                NRF_LOG_INFO("go to find sensor ");
                zb_err_code = ZB_SCHEDULE_ALARM(find_sensor, param_sb, MATCH_DESC_REQ_START_DELAY);
                ZB_ERROR_CHECK(zb_err_code);
                zb_err_code = ZB_SCHEDULE_ALARM(find_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
                ZB_ERROR_CHECK(zb_err_code);
            return;

        case BSP_EVENT_KEY_3:
             

       
               NRF_LOG_INFO("go to report attr");
               zb_err_code = ZB_SCHEDULE_ALARM(sensor_subscribe, param_sb, MATCH_DESC_REQ_START_DELAY);
               ZB_ERROR_CHECK(zb_err_code);
               zb_err_code = ZB_SCHEDULE_ALARM(zb_subscribe_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
               ZB_ERROR_CHECK(zb_err_code);
				
				
				
				
            return;


        case BSP_EVENT_KEY_4:
            //cycle_endpoint(ZB_FALSE);
            return;

        default:
            NRF_LOG_INFO("Unhandled BSP Event received: %d", evt);
            return;
    }

   
}


*/













//my

  static zb_void_t zcl_device_cb(zb_uint8_t param)
{
    zb_uint8_t                       cluster_id;
    zb_uint8_t                       attr_id;
    zb_buf_t                       * p_buffer = ZB_BUF_FROM_REF(param);
    zb_zcl_device_callback_param_t * p_device_cb_param =
                     ZB_GET_BUF_PARAM(p_buffer, zb_zcl_device_callback_param_t);

    NRF_LOG_INFO("zcl_device_cb id %hd", p_device_cb_param->device_cb_id);

    /* Set default response value. */
    p_device_cb_param->status = RET_OK;

    switch (p_device_cb_param->device_cb_id)
    {  


        
        case ZB_ZCL_LEVEL_CONTROL_SET_VALUE_CB_ID:
            NRF_LOG_INFO("Level control setting to %d", p_device_cb_param->cb_param.level_control_set_value_param.new_value);
          
            break;

        case ZB_ZCL_SET_ATTR_VALUE_CB_ID:
            cluster_id = p_device_cb_param->cb_param.set_attr_value_param.cluster_id;
            attr_id    = p_device_cb_param->cb_param.set_attr_value_param.attr_id;

            if (cluster_id == ZB_ZCL_CLUSTER_ID_ON_OFF)
            {
                uint8_t value = p_device_cb_param->cb_param.set_attr_value_param.values.data8;

                NRF_LOG_INFO("on/off attribute setting to %hd", value);
                if (attr_id == ZB_ZCL_ATTR_ON_OFF_ON_OFF_ID)
                {
                   
                }
            }
            else if (cluster_id == ZB_ZCL_CLUSTER_ID_LEVEL_CONTROL)
            {
                uint16_t value = p_device_cb_param->cb_param.set_attr_value_param.values.data16;

                NRF_LOG_INFO("level control attribute setting to %hd", value);
                if (attr_id == ZB_ZCL_ATTR_LEVEL_CONTROL_CURRENT_LEVEL_ID)
                {
                    
                }
            }
            else
            {
                /* Other clusters can be processed here */
                NRF_LOG_INFO("Unhandled cluster attribute id: %d", cluster_id);
            }
            break;

        default:
            p_device_cb_param->status = RET_ERROR;
            break;
    }

    NRF_LOG_INFO("zcl_device_cb status: %hd", p_device_cb_param->status);
}







/**@brief ZigBee stack event handler.
 *
 * @param[in]   param   Reference to ZigBee stack buffer used to pass arguments (signal).
 */
void zboss_signal_handler(zb_uint8_t param)
{
    zb_zdo_app_signal_hdr_t                  * p_sg_p             = NULL;
    zb_zdo_app_signal_type_t                   sig                = zb_get_app_signal(param, &p_sg_p);
    zb_ret_t                                   status             = ZB_GET_APP_SIGNAL_STATUS(param);
   // zb_nwk_device_type_t                       role               = ZB_NWK_DEVICE_TYPE_COORDINATOR;
	zb_param=param;
                
    zb_ret_t                       zb_err_code;
    zb_bool_t                 comm_status;
    switch (sig)
    {



          
        case ZB_BDB_SIGNAL_STEERING:
            if (status == RET_OK)
            {



                 memset(devList, 0, sizeof(devList));
                /* Schedule an alarm to notify about the end of steering period */
                NRF_LOG_INFO("Network steering started");
                bsp_board_led_on(ZIGBEE_NETWORK_STATE_LED);
                zb_err_code = ZB_SCHEDULE_ALARM(steering_finished, 0, ZB_TIME_ONE_SECOND * ZB_ZGP_DEFAULT_COMMISSIONING_WINDOW);
                ZB_ERROR_CHECK(zb_err_code);
            }
            else
            {
                NRF_LOG_INFO("Network steering failed to start. Status: %d. Retry network formation after 1 second.", status);
                bsp_board_led_off(ZIGBEE_NETWORK_STATE_LED);
                zb_err_code = ZB_SCHEDULE_ALARM(bdb_restart_top_level_commissioning, 0, ZB_TIME_ONE_SECOND);
                ZB_ERROR_CHECK(zb_err_code);
            }
            break;









           case ZB_ZDO_SIGNAL_SKIP_STARTUP:
            if (zb_bdb_is_factory_new())
            {
                NRF_LOG_INFO("Start network steering & formation.");
                comm_status = bdb_start_top_level_commissioning(ZB_BDB_NETWORK_STEERING | ZB_BDB_NETWORK_FORMATION);
                ZB_COMM_STATUS_CHECK(comm_status);
            }
            else
            {
                comm_status = bdb_start_top_level_commissioning(ZB_BDB_INITIALIZATION);
                ZB_COMM_STATUS_CHECK(comm_status);
            }
            break;     




        case ZB_BDB_SIGNAL_DEVICE_FIRST_START:
      
         if (status == RET_OK)
            {
                if (ZIGBEE_MANUAL_STEERING == ZB_FALSE)
                {
                    NRF_LOG_INFO("Start network steering.");
                    comm_status = bdb_start_top_level_commissioning(ZB_BDB_NETWORK_STEERING);
                    ZB_COMM_STATUS_CHECK(comm_status);
                }
            }
            else
            {
                NRF_LOG_ERROR("Failed to form network.");
            }
            break;



        case ZB_BDB_SIGNAL_DEVICE_REBOOT:
            if (status == RET_OK)
            {
                         
                         
                         
                         
                         //ZB_NWK_DEVICE_TYPE_COORDINATOR

                  

                NRF_LOG_INFO("Device started OK. Start network steering. Reason: %d", sig);
                bsp_board_led_on(ZIGBEE_NETWORK_STATE_LED);
                UNUSED_RETURN_VALUE(bdb_start_top_level_commissioning(ZB_BDB_NETWORK_STEERING));

                zb_err_code = ZB_SCHEDULE_ALARM(bdb_restart_top_level_commissioning, 0, ZB_TIME_ONE_SECOND);
                ZB_ERROR_CHECK(zb_err_code);
					
							
             if (m_device_ctx.sensor_params.short_addr == 0x0000)  				  
                {
                NRF_LOG_INFO("go to find sensor ");
                zb_err_code = ZB_SCHEDULE_ALARM(find_sensor, param, MATCH_DESC_REQ_START_DELAY);
                ZB_ERROR_CHECK(zb_err_code);
                zb_err_code = ZB_SCHEDULE_ALARM(find_timeout, 0, MATCH_DESC_REQ_TIMEOUT);
                ZB_ERROR_CHECK(zb_err_code);
									
									param=0;
                  }       //bind_sensor
												 
			
                 


                         //bint_sensor_timeout

                       //sensor_subscribe
							
								
								
						
            // ZB_SCHEDULE_ALARM(req_rum(),0,MATCH_DESC_REQ_TIMEOUT);
                //agent_ep_handler_report

             //  zb_err_code = ZB_SCHEDULE_ALARM(handlerreport, param, MATCH_DESC_REQ_START_DELAY);
               //ZB_ERROR_CHECK(zb_err_code);
              



                // NRF_ZIGBEE_EP_HANDLER_REGISTER(NULL, agent_ep_handler_report);



                      




     
            }
            else
            {
              
                bsp_board_led_off(ZIGBEE_NETWORK_STATE_LED);
               
            }
            break;

        case ZB_ZDO_SIGNAL_LEAVE:
            if (status == RET_OK)
            {
                zb_zdo_signal_leave_params_t * p_leave_params;
                bsp_board_led_off(ZIGBEE_NETWORK_STATE_LED);
                p_leave_params = ZB_ZDO_SIGNAL_GET_PARAMS(p_sg_p, zb_zdo_signal_leave_params_t);
                NRF_LOG_INFO("Network left. Leave type: %d", p_leave_params->leave_type);
            }
            else
            {
                NRF_LOG_ERROR("Unable to leave network. Status: %d", status);
            }
            break;

        case ZB_ZDO_SIGNAL_PRODUCTION_CONFIG_READY:
            if (status != RET_OK)
            {
                NRF_LOG_WARNING("Production config is not present or invalid");
            }
            break;

     

        case ZB_NWK_SIGNAL_NO_ACTIVE_LINKS_LEFT:
            NRF_LOG_WARNING("Parent is unreachable");
            break;

        case ZB_ZDO_SIGNAL_DEVICE_UPDATE:
            {
                char ieee_addr_buf[17] = {0};
                zb_zdo_signal_device_update_params_t * p_update_params;
                p_update_params = ZB_ZDO_SIGNAL_GET_PARAMS(p_sg_p, zb_zdo_signal_device_update_params_t);
               
                ZB_LETOH64(iees,p_update_params->long_addr);
                UNUSED_RETURN_VALUE(ieee_addr_to_str(ieee_addr_buf, sizeof(ieee_addr_buf), p_update_params->long_addr));
        
                NRF_LOG_INFO("Device has updated its status in the network, short address: %04x, long address: %s, status: %d", 
                             p_update_params->short_addr, NRF_LOG_PUSH(ieee_addr_buf), p_update_params->status);
            }
            break;

        case ZB_ZDO_SIGNAL_DEVICE_AUTHORIZED:
            {
                char ieee_addr_buf[17] = {0};
                zb_zdo_signal_device_authorized_params_t * p_authorize_params;
                p_authorize_params = ZB_ZDO_SIGNAL_GET_PARAMS(p_sg_p, zb_zdo_signal_device_authorized_params_t);
		   ZB_LETOH64(iees,p_authorize_params->long_addr);					
                UNUSED_RETURN_VALUE(ieee_addr_to_str(ieee_addr_buf, sizeof(ieee_addr_buf), p_authorize_params->long_addr));
                
                NRF_LOG_INFO("Device authorization event happened, short address: %04x, long address: %s, authorization type: %d, authorization status: %d", 
                             p_authorize_params->short_addr, NRF_LOG_PUSH(ieee_addr_buf), p_authorize_params->authorization_type, p_authorize_params->authorization_status);
            }
            break;


   //



      case ZB_ZDO_SIGNAL_DEVICE_ANNCE:
        {
             NRF_LOG_INFO("JOIND! \r\n");
              zb_buf_t                    * p_buf = ZB_BUF_FROM_REF(param);
              zb_apsde_data_indication_t * p_ind  = ZB_GET_BUF_PARAM(p_buf, zb_apsde_data_indication_t); // Get the pointer to the parameters buffer, which stores APS layer response
             devList[iter] = p_ind->src_addr;
             NRF_LOG_INFO("Addr = 0x%02x\r\n", devList[iter]);

              param = 0; 
             iter++;
         }


     break;

   case ZB_BDB_SIGNAL_FINDING_AND_BINDING_INITIATOR_FINISHED:
            {
                zb_zdo_signal_fb_initiator_finished_params_t * f_n_b_status = ZB_ZDO_SIGNAL_GET_PARAMS(p_sg_p, zb_zdo_signal_fb_initiator_finished_params_t);
                switch(f_n_b_status->status)
                {
                    case ZB_ZDO_FB_INITIATOR_STATUS_SUCCESS:
                        NRF_LOG_INFO("F&B: Remote peer has been bound.");
                        sensor_subscribe(param);
                        ep_report(param);


                        break;

                    case ZB_ZDO_FB_INITIATOR_STATUS_CANCEL:
                        NRF_LOG_INFO("F&B: Initiator process was cancelled.");
                        break;

                    case ZB_ZDO_FB_INITIATOR_STATUS_ALARM:
                        NRF_LOG_INFO("F&B: Initiator process was timed out.");
                        break;

                    case ZB_ZDO_FB_INITIATOR_STATUS_ERROR:
                        NRF_LOG_ERROR("F&B: Error.");
                        break;

                    default:
                        NRF_LOG_ERROR("F&B: Unknown error, status %d.", f_n_b_status->status);
                        break;
                }
            }
           // bsp_board_led_off(FINDING_N_BINDING_STATE_LED);
            break;


    //



        default:
            /* Unhandled signal. For more information see: zb_zdo_app_signal_type_e and zb_ret_e */
            NRF_LOG_INFO("Unhandled signal %d. Status: %d", sig, status);
    }

    if (param)
    {
        ZB_FREE_BUF_BY_REF(param);
    }
}

/**@brief Function for application main entry.
 */
int main(void)
{
    ret_code_t     ret;
   
    ret_code_t     err_code;
    
    /* Intiialise the leds */

     //leds_buttons_init();

     bsp_board_init(BSP_INIT_LEDS);
     bsp_board_leds_off();
	
	    nrf_drv_swI2c_init();
	    OLED_Init();	
	    OLED_Clear();nrf_delay_us(100) ;
	    OLED_ShowString(35,0,"HELLO!",16);nrf_delay_ms(1);
	    
	
	

	
	  
    /* Initialize loging system and GPIOs. */
    log_init();



    ret = app_timer_init();
    APP_ERROR_CHECK(ret);

    /* Initialize the Zigbee CLI subsystem */
    //zb_cli_init(ZIGBEE_CLI_ENDPOINT);

    /* Set ZigBee stack logging level and traffic dump subsystem. */
    ZB_SET_TRACE_LEVEL(ZIGBEE_TRACE_LEVEL);
    ZB_SET_TRACE_MASK(ZIGBEE_TRACE_MASK);
    ZB_SET_TRAF_DUMP_OFF();

    /* Initialize ZigBee stack. */
    ZB_INIT("cli_agent_router");

    /* Set device address to the value read from FICR registers. */
    zb_osif_get_ieee_eui64(ieee_addr);
    zb_set_long_address(ieee_addr);
   
     
    ieee_addr_to_str(ieee_addr_buf, sizeof(ieee_addr_buf), ieee_addr);
    //NRF_LOG_INFO("eui64 out addr: %s ",NRF_LOG_PUSH(ieee_addr_buf) );
    short_addr = zb_address_short_by_ieee(ieee_addr);
    //NRF_LOG_INFO("short out addr: %04x ", short_addr);
     zb_set_network_coordinator_role(IEEE_CHANNEL_MASK);
    zb_set_max_children(MAX_CHILDREN);

   // zb_set_bdb_primary_channel_set(IEEE_CHANNEL_MASK);
    zigbee_erase_persistent_storage(ERASE_PERSISTENT_CONFIG);

    /* Register CLI Agent device context (endpoints). */

   /* Register callback for handling ZCL commands. */
     

    ZB_ZCL_REGISTER_DEVICE_CB(zcl_device_cb);
   
     

    //ZB_AF_REGISTER_DEVICE_CTX();
    ZB_AF_REGISTER_DEVICE_CTX(&cli_agent_ctx);

    /* Set the endpoint receive hook */
   ZB_AF_SET_ENDPOINT_HANDLER(ZIGBEE_CLI_ENDPOINT, cli_agent_ep_handler);

  

    


   

    if (ZIGBEE_MANUAL_STEERING == ZB_TRUE)
    {
        ret = zboss_start_no_autostart();
    }
    else
    {
        ret = zboss_start();
    }

   // ZB_ERROR_CHECK(ret);

    /* Start ZigBee stack. */
    while(1)
    {
        zboss_main_loop_iteration();
        UNUSED_RETURN_VALUE(NRF_LOG_PROCESS());
    }
}


/**
 * @}
 */

Parents Reply Children
  • Hi.

    I still do not understand your question, unfortunately.

    If your problem is that the IEEE request is not working, have you either looked at the CLI example or zboss_api_zdo.h?

    You can find an example of how to call there;

    ** @brief IEEE_addr_req primitive.
      *
      * @param param - index of buffer with primitive parameters \ref zb_zdo_ieee_addr_req_s.
      * Parameters must be put into the buffer as data (allocated).
      * @param cb    - user's function to call when got response from the remote.
      * @return        - ZDP transaction sequence number or 0xFF if operation cannot be
      *                performed now (nor enough memory, resources, etc.)
      *
      * @b Example:
      * @code
      * {
      *   zb_zdo_ieee_addr_req_t *req = NULL;
      *   zb_uint8_t tsn;
      *
      *   ZB_BUF_INITIAL_ALLOC(buf, sizeof(zb_zdo_ieee_addr_req_t), req);
      *
      *   req->nwk_addr = ind->src_addr;
      *   req->request_type = ZB_ZDO_SINGLE_DEV_RESPONSE;
      *   req->start_index = 0;
      *   tsn = zb_zdo_ieee_addr_req(ZB_REF_FROM_BUF(buf), ieee_addr_callback);
      *
      *   if (tsn == ZB_ZDO_INVALID_TSN)
      *   {
      *     TRACE_MSG(TRACE_ZDO2, "request failed", (FMT__0));
      *   }
      * }
      *
      * void ieee_addr_callback(zb_uint8_t param)
      * {
      *   zb_buf_t *buf = ZB_BUF_FROM_REF(param);
      *   zb_zdo_nwk_addr_resp_head_t *resp;
      *   zb_ieee_addr_t ieee_addr;
      *   zb_uint16_t nwk_addr;
      *   zb_address_ieee_ref_t addr_ref;
      *
      *   TRACE_MSG(TRACE_ZDO2, "zb_get_peer_short_addr_cb param %hd", (FMT__H, param));
      *
      *   resp = (zb_zdo_nwk_addr_resp_head_t*)ZB_BUF_BEGIN(buf);
      *   TRACE_MSG(
      *       TRACE_ZDO2, "resp status %hd, nwk addr %d", (FMT__H_D, resp->status, resp->nwk_addr));
      *   ZB_DUMP_IEEE_ADDR(resp->ieee_addr);
      *   if (resp->status == ZB_ZDP_STATUS_SUCCESS)
      *   {
      *     ZB_LETOH64(ieee_addr, resp->ieee_addr);
      *     ZB_LETOH16(&nwk_addr, &resp->nwk_addr);
      *     zb_address_update(ieee_addr, nwk_addr, ZB_TRUE, &addr_ref);
      *   }
          zb_free_buf(buf);
      * }
      *
      * @endcode

    Best regards,

    Andreas

  • Request timeout, look at CIL?I don't know why, this company's products are so difficult to develop.The documentation is too sloppy.

  • Request timeout, look at CIL?I don't know why, this company's products are so difficult to develop.The documentation is too sloppy.

  • Hi.

    Can you please explain more in details what you mean?

    Best regards,

    Andreas

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