view Discovery/Src/logbook_miniLive.c @ 916:4832981f9af8 Evo_2_23

External sensor UART: Switch to DMA TX transfers: The previous version used polling tx function to transfer data. Because of the short command length of the protocols supported this was no big issue. New protocolls (like GNSS) have longer command sequence which have an impact to the program flow. That's why the implementation has been changed to DMA transmission.
author Ideenmodellierer
date Mon, 28 Oct 2024 20:34:58 +0100
parents 7bd347bdaa81
children
line wrap: on
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/**
  ******************************************************************************
	* @copyright heinrichs weikamp
  * @file   		logbook_miniLive.c
  * @author 		heinrichs weikamp gmbh
  * @date   		13-March-2015
  * @version		V0.0.1
  * @since			13-March-2015
  * @brief			little logbook for during the dive
	* @bug
	* @warning
  ******************************************************************************
  * @attention
  *
  * <h2><center>&copy; COPYRIGHT(c) 2015 heinrichs weikamp</center></h2>
  *
  ******************************************************************************
  */

/* Includes ------------------------------------------------------------------*/


#include <string.h>
#include "logbook_miniLive.h"
#include "data_exchange.h"
#include "logbook.h"
#include "tHome.h"

 /*
  ******************************************************************************
  * @brief   t7_updateMiniLiveLogbook. /  Create depth samples for view during dive
  * @author  heinrichs weikamp gmbh
  * @version V0.0.1
  * @date    13-March-2015
  ******************************************************************************
	*
  */
	
#define MLLsize (296)
static uint16_t MLLdataDepth[MLLsize];
static uint16_t MLLpointer  = 0;
static uint8_t MLLtickIntervallSeconds = 2;

/* Replay Block data storage */
#define DEPTH_DATA_LENGTH	(1800u)				/* Resolution: 1 hours dive, sampling every 2 seconds */
uint16_t ReplayDepthData[DEPTH_DATA_LENGTH];
uint8_t ReplayMarkerData[DEPTH_DATA_LENGTH];
uint16_t liveDepthData[DEPTH_DATA_LENGTH];
uint16_t liveDepthDataMod[DEPTH_DATA_LENGTH];	/* live data modified to fit to marker checks */
uint16_t liveDecoData[DEPTH_DATA_LENGTH];
uint16_t liveDecoDataMod[DEPTH_DATA_LENGTH];
static uint16_t liveDataIndex = 0;
static uint16_t liveDataIndexMod = 0;

static uint8_t	ReplayDataResolution = 2;		/* Time represented by one sample (second) */
static uint16_t ReplayDataLength = 0;			/* Number of data entries */
static uint16_t ReplayDataMaxDepth = 0;
static uint16_t ReplayDataMinutes = 0;
static uint16_t ReplayDataOffset = 0xFFFF;		/* Stepbackwards format used by log functions */
static uint16_t  ReplayMarkerIndex = 0;

uint16_t *getMiniLiveLogbookPointerToData(void)
{
	return MLLdataDepth;
}


uint16_t getMiniLiveLogbookActualDataLength(void)
{
	return MLLpointer;
}

uint16_t MiniLiveLogbook_getNextMarkerIndex(uint16_t curIndex)
{
	uint16_t index = 0;
	
	if((ReplayMarkerData[0] != 0xFF) && (curIndex < ReplayDataLength))
	{
		index = curIndex;
		do
		{
			index++;
			if (index == ReplayDataLength)
			{
				index = 0;
			}
			if(ReplayMarkerData[index] != 0)
			{
				break;
			}
		}while (index != curIndex);
	}
	return index;
}

static uint16_t workdata[DEPTH_DATA_LENGTH];
static void compressMarkerData(uint16_t* pSource, uint16_t* pTarget, float step, uint16_t startIndex, uint16_t stopIndex)
{
	uint16_t workIndex = startIndex;
	float nextStep = (float)workIndex;

	while (workIndex <= ReplayMarkerIndex)
	{
		workdata[workIndex] = *pSource++;
		nextStep += step;
		while(nextStep < workIndex + 1)
		{
			if(*pSource != 0xFFFF)					/* do not average "ignore" value */
			{
				if(workdata[workIndex] == 0xFFFF)	/* first value to be shown */
				{
					workdata[workIndex] = *pSource;
				}
				else
				{
					workdata[workIndex] += *pSource;
					workdata[workIndex] /= 2;
				}
			}
			pSource++;
			nextStep += step;
		}
		workIndex++;
	}
	memcpy(&pTarget[startIndex],&workdata[startIndex],(workIndex - startIndex -1) * 2);
	while(workIndex < DEPTH_DATA_LENGTH)
	{
		pTarget[workIndex] = 0xFFFF;
		workIndex++;
	}
}
static void stretchMarkerData(uint16_t* pSource, uint16_t* pTarget, float step, uint16_t startIndex, uint16_t stopIndex)
{
	uint16_t workIndex = startIndex;
	float nextStep = (float)workIndex;

	while (workIndex <= stopIndex)
	{
		nextStep += step;
		if(nextStep > stopIndex)
		{
			nextStep = stopIndex;
		}
		while(workIndex <= (uint16_t)nextStep)
		{
			workdata[workIndex++] = *pSource;
		}
		pSource++;
	}
	memcpy(&pTarget[startIndex],&workdata[startIndex],(workIndex - startIndex) * 2);
	while(workIndex < DEPTH_DATA_LENGTH)
	{
		pTarget[workIndex] = 0xFFFF;
		workIndex++;
	}
}

void MiniLiveLogbook_checkMarker(void)
{
	static uint16_t lastLifeIndex = 0;
	uint16_t* pDepthData;
	uint16_t* pDecoData;
	float step;
	uint16_t lastMarkerIndex = ReplayMarkerIndex;

	ReplayMarkerIndex = MiniLiveLogbook_getNextMarkerIndex(ReplayMarkerIndex);
	if(ReplayMarkerIndex <= lastMarkerIndex)		/* no other marker found or last marker checked => reset marker to 0 to deactivate check function */
	{
		ReplayMarkerIndex = 0;
		lastLifeIndex = 0;
		liveDataIndexMod = liveDataIndex;
	}
	else
	{
		if(lastMarkerIndex == 0)	/* use real live data */
		{
			pDepthData = &liveDepthData[0];
			pDecoData = &liveDecoData[0];
			lastLifeIndex = 0;
		}
		else
		{
			pDepthData = &liveDepthDataMod[lastMarkerIndex];  /* work with already modified data */
			pDecoData = &liveDecoDataMod[lastMarkerIndex];
		}
		if(lastLifeIndex == liveDataIndex)					/* repeated button press before new data was generated => draw straight line */
		{
			step = ReplayMarkerIndex-lastMarkerIndex;
		}
		else
		{
			step = (ReplayMarkerIndex-lastMarkerIndex) / (float)(liveDataIndex - lastLifeIndex); /* the live data shall be modified to match the history data */
		}

		lastLifeIndex = liveDataIndex;

		if(step < 1)		/* compression needed */
		{
			compressMarkerData(pDepthData, liveDepthDataMod, step, lastMarkerIndex, ReplayMarkerIndex);
			compressMarkerData(pDecoData, liveDecoDataMod, step, lastMarkerIndex, ReplayMarkerIndex);
		}
		else				/* stretch data */
		{
			stretchMarkerData(pDepthData, liveDepthDataMod, step, lastMarkerIndex, ReplayMarkerIndex);
			stretchMarkerData(pDecoData, liveDecoDataMod, step, lastMarkerIndex, ReplayMarkerIndex);
		}
		liveDataIndexMod = ReplayMarkerIndex;
	}
}


void compressBuffer_uint16(uint16_t* pdata, uint16_t size)
{
	uint16_t* pTarget = pdata;
	uint16_t* pSource = pdata;
	uint16_t  result = 0;
	uint16_t index = 0;
	
	for(index = 0; index < size/2; index++)
	{
		*pTarget = *pSource++;
		*pTarget += *pSource++;
		result = *pTarget /= 2;
		if((*pTarget != 0) && (result == 0))	/* avoid termination of information by round up to 1 */
		{
			*pTarget++ = 1;
		}
		else
		{
			*pTarget++ = result;
		}
	}
	memset(pTarget,0,size/2);
}

void updateMiniLiveLogbook( _Bool checkOncePerSecond)
{
	static uint8_t bDiveMode = 0;
	static uint32_t last_second = 0;
	static uint8_t secondsCount = 0;
	static uint8_t lifesecondsCount = 0;

	const SDecoinfo* pDecoinfo;
	uint8_t stopDepth = 0;
	uint16_t stopTime = 0;

	if(checkOncePerSecond)
	{
		uint32_t now =  current_second();
		if( last_second == now)
				return;
		last_second = now;
	}
	secondsCount++;
	lifesecondsCount++;
	
	if(!bDiveMode)
	{
		if((stateUsed->mode == MODE_DIVE) && (stateUsed->lifeData.dive_time_seconds >= 5))
		{
			secondsCount = 0;
			MLLtickIntervallSeconds = 2;
			bDiveMode = 1;
			MLLpointer = 1;
			for(int i=0;i<MLLsize;i++)
				MLLdataDepth[i] = 0;

			for(liveDataIndex = 0; liveDataIndex < DEPTH_DATA_LENGTH; liveDataIndex++)
			{
				liveDepthData[liveDataIndex] = 0xFFFF;
				liveDecoData[liveDataIndex] = 0xFFFF;
			}
			lifesecondsCount = 0;
			liveDataIndex = 0;
			liveDataIndexMod = 0;
			liveDepthData[liveDataIndex++] = 0;	/* start at 0 */
		}
	}
	else if(stateUsed->mode == MODE_DIVE)
	{
		bDiveMode = 3;
		//
		if(secondsCount >= MLLtickIntervallSeconds)
		{
			secondsCount = 0;
			/* in case of a buffer overrun the buffer is divided and the first half is filled with a compressed image of the complete buffer */
			if((MLLpointer >= MLLsize) && (MLLtickIntervallSeconds < 127))
			{
				MLLpointer = 0;
				MLLtickIntervallSeconds *= 2;

				compressBuffer_uint16(MLLdataDepth,MLLsize);
				MLLpointer = MLLsize/2;
			}
			if(MLLpointer < MLLsize)
				MLLdataDepth[MLLpointer++] = (int)(stateUsed->lifeData.depth_meter * 10);
		}
		if(lifesecondsCount >= ReplayDataResolution)
		{
			lifesecondsCount = 0;

			if(liveDataIndex >= DEPTH_DATA_LENGTH)		/* compress data */
			{
				ReplayDataResolution *= 2;
				compressBuffer_uint16(liveDepthData,DEPTH_DATA_LENGTH);
				compressBuffer_uint16(liveDepthDataMod, DEPTH_DATA_LENGTH);
				compressBuffer_uint16(ReplayDepthData,DEPTH_DATA_LENGTH);		/* also compress Replay data to simplify mapping between live and replay data */
				liveDataIndex = DEPTH_DATA_LENGTH / 2;
				liveDataIndexMod /= 2;
			}
			liveDepthData[liveDataIndex] = (int)(stateUsed->lifeData.depth_meter * 100);
			liveDepthDataMod[liveDataIndexMod] = liveDepthData[liveDataIndex];

			if(stateUsed->diveSettings.deco_type.ub.standard == VPM_MODE)
			{
				pDecoinfo = &stateUsed->decolistVPM;
			}
			else
			{
				pDecoinfo = &stateUsed->decolistBuehlmann;
			}
			tHome_findNextStop(pDecoinfo->output_stop_length_seconds, &stopDepth, &stopTime);
			if(stopDepth)
			{
				liveDecoData[liveDataIndex] = stopDepth * 100;
				liveDecoDataMod[liveDataIndexMod] = stopDepth * 100;
			}
			else
			{
				liveDecoData[liveDataIndex] = 0xFFFF;
				liveDecoDataMod[liveDataIndexMod] = 0xFFFF;
			}
			liveDataIndex++;
			liveDataIndexMod++;
		}
	}
	else if(bDiveMode == 3)
	{
		//End of Dive
		for(int i=0;i<MLLsize;i++)
			MLLdataDepth[i] = 0;
		bDiveMode = 0;
	}
}

uint8_t prepareReplayLog(uint8_t StepBackwards)
{
	uint8_t retVal = 0;
	uint16_t index = 0;
	uint16_t dataLength = 0;
	uint8_t markerDetected = 0;

    SLogbookHeader logbookHeader;

    if(ReplayDataOffset == StepBackwards)				/* Entry already selected => reset selection */
    {
    	ReplayDataOffset = 0xFFFF;
    	ReplayDataResolution = 2;
		ReplayDataLength = 0;
		ReplayDataMaxDepth = 0;
		ReplayDataMinutes =  0;

    	retVal = 1;
    }
    else
    {
    	ReplayDataOffset = StepBackwards;
		logbook_getHeader(StepBackwards ,&logbookHeader);

		dataLength = logbook_readSampleData(StepBackwards, DEPTH_DATA_LENGTH, ReplayDepthData,NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, ReplayMarkerData);

	/* check if a marker is provided. If not disable marker functionality for the replay block */
		for(index = 0; index < dataLength; index++)
		{
			if(ReplayMarkerData[index] != 0)
			{
				markerDetected = 1;
				break;
			}
		}
		if(markerDetected == 0)
		{
			ReplayMarkerData[0] = 0xFF;
		}

		ReplayDataResolution = logbookHeader.total_diveTime_seconds / dataLength;
		ReplayDataLength = dataLength;
		ReplayDataMaxDepth = logbookHeader.maxDepth;
		ReplayDataMinutes =  logbookHeader.diveTimeMinutes;
		if(dataLength != 0)
		{
			retVal = 1;
		}
    }
	return retVal;
}

uint8_t getReplayInfo(uint16_t** pReplayData, uint8_t** pReplayMarker, uint16_t* DataLength, uint16_t* MaxDepth, uint16_t* diveMinutes)
{
	uint8_t retVal = 0;

	if((ReplayDataOffset != 0xFFFF) && (pReplayData != NULL) && (DataLength != NULL) && (MaxDepth != NULL) && (pReplayMarker != 0))
	{
		*pReplayData = ReplayDepthData;
		*pReplayMarker = ReplayMarkerData;
		*DataLength = ReplayDataLength;
		*MaxDepth = ReplayDataMaxDepth;
		*diveMinutes = ReplayDataMinutes;
		retVal = 1;
	}

	return retVal;
}

uint16_t *getMiniLiveReplayPointerToData(void)
{
	if(ReplayMarkerIndex == 0)
	{
		return liveDepthData;
	}
	else
	{
		return liveDepthDataMod;
	}
}
uint16_t *getMiniLiveDecoPointerToData(void)
{
	if(ReplayMarkerIndex == 0)
	{
		return liveDecoData;
	}
	else
	{
		return liveDecoDataMod;
	}
}
uint16_t getMiniLiveReplayLength(void)
{
	return liveDataIndex;
}

uint16_t getReplayOffset(void)
{
	return ReplayDataOffset;
}

uint16_t getReplayDataResolution(void)
{
	return ReplayDataResolution;
}

/************************ (C) COPYRIGHT heinrichs weikamp *****END OF FILE****/