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Buelmann: new implementation for ceiling Since my first functional fix in the ceiling computation in commit ceecabfddb57, I noticed that the computation used a linear search, that became rather computational expensive after that commit. The simple question is: why not a binary search? So, this commit implements the binary search. But there is a long story attached to this. Comparing ceiling results from hwOS and this OSTC4 code were very different. Basically, the original OSTC4 algorithm computed the ceiling using the same GFlow to GFhigh slope, in such a way, that the ceiling was in sync with the presented deco stops, where the hwOS code presents a GFhigh based ceiling. This said, it is more logical when the OSTC4 and hwOS code give similar results. This new recursive algorithm gives very similar results for the ceiling compared to hwOS. To be complete here, the Buelmann ceiling is the depth to which you can ascend, so that the leading tissue reaches GFhigh. This also explains why the deepest deco stop is normally deeper than the ceiling (unless one dives with GF like 80/80). The code implemented here is rather straightforward recursion. Signed-off-by: Jan Mulder <jlmulder@xs4all.nl>
author Jan Mulder <jlmulder@xs4all.nl>
date Thu, 11 Apr 2019 17:48:48 +0200
parents 7801c5d8a562
children
line wrap: on
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/**
  ******************************************************************************
  * @file    data_exchange_main.c
  * @author  heinrichs weikamp gmbh
  * @date    13-Oct-2014
  * @version V0.0.2
  * @since   27-May-2015

	* @brief   Communication with the second CPU == RTE system
  *
  @verbatim
  ==============================================================================
                        ##### How to use #####
  ==============================================================================

  ==============================================================================
                        ##### Device Data #####
  ==============================================================================
	
	main CPU always sends the device data info that it has at the moment

		on start it is INT32_MIN, INT32_MAX and 0 
		as initialized  in data_central.c variable declaration
	
	second small CPU gets request to send its device data
		
		on receiption the data is merged with the data in externLogbookFlash,
		stored on the externLogbookFlash and from now on send to small CPU

	@endverbatim
  ******************************************************************************
  * @attention
  *
  * <h2><center>&copy; COPYRIGHT(c) 2014 heinrichs weikamp</center></h2>
  *
  ******************************************************************************
  */

/* Includes ------------------------------------------------------------------*/
#include <string.h> // for memcopy
#include "stm32f4xx_hal.h"
#include "stdio.h"
#include "ostc.h"
#include "data_central.h"
#include "data_exchange_main.h"
#include "base.h"
#include "externLogbookFlash.h"


/* Expoted variables --------------------------------------------------------*/

/* Private variables ---------------------------------------------------------*/

SDataReceiveFromMaster dataOut;
SDataExchangeSlaveToMaster dataIn;

uint8_t data_old__lost_connection_to_slave_counter_temp = 0;
/* Private types -------------------------------------------------------------*/

uint8_t DataEX_check_header_and_footer_ok(void);
void DataEX_control_connection_while_asking_for_sleep(void);

/* Exported functions --------------------------------------------------------*/

uint8_t DataEX_call(void)
{
	DataEX_control_connection_while_asking_for_sleep();
	
	for(int i=0;i<EXCHANGE_BUFFERSIZE;i++)
		*(uint8_t *)(((uint32_t)&dataOut) + i)  = 0;

	dataOut.mode = MODE_SHUTDOWN;

	dataOut.header.checkCode[0] = 0xBB;
	dataOut.header.checkCode[1] = 0x01;
	dataOut.header.checkCode[2] = 0x01;
	dataOut.header.checkCode[3] = 0xBB;

	dataOut.footer.checkCode[0] = 0xF4;
	dataOut.footer.checkCode[1] = 0xF3;
	dataOut.footer.checkCode[2] = 0xF2;
	dataOut.footer.checkCode[3] = 0xF1;

	HAL_GPIO_WritePin(SMALLCPU_CSB_GPIO_PORT,SMALLCPU_CSB_PIN,GPIO_PIN_SET);
	delayMicros(10);

	if(data_old__lost_connection_to_slave_counter_temp >= 3)
	{
		data_old__lost_connection_to_slave_counter_temp = 0;
	}
	else
	{
		HAL_GPIO_WritePin(SMALLCPU_CSB_GPIO_PORT,SMALLCPU_CSB_PIN,GPIO_PIN_RESET);
	}

	HAL_SPI_TransmitReceive_DMA(&cpu2DmaSpi, (uint8_t *)&dataOut, (uint8_t *)&dataIn, EXCHANGE_BUFFERSIZE+1);
	return 1;
}


void DataEX_control_connection_while_asking_for_sleep(void)
{
 	if(!DataEX_check_header_and_footer_ok())
	{
		data_old__lost_connection_to_slave_counter_temp += 1;
	}
}

uint8_t DataEX_check_header_and_footer_ok(void)
{
	if(dataIn.header.checkCode[0] != 0xA1)
		return 0;
	if(dataIn.header.checkCode[1] != 0xA2)
		return 0;
	if(dataIn.header.checkCode[2] != 0xA3)
		return 0;
	if(dataIn.header.checkCode[3] != 0xA4)
		return 0;
	if(dataIn.footer.checkCode[0] != 0xE1)
		return 0;
	if(dataIn.footer.checkCode[1] != 0xE2)
		return 0;
	if(dataIn.footer.checkCode[2] != 0xE3)
		return 0;
	if(dataIn.footer.checkCode[3] != 0xE4)
		return 0;

	return 1;
}