Mercurial > public > ostc4
view Discovery/Src/externLogbookFlash.c @ 626:3e1a0e267f38
Added option to select sensitivity of focus detection:
Depending on the location the computer is equiped during dive (arm wet/ dry suite, glove...) it is usefull to adapt the sensitivity of the focus detection. Technical it means the radius of the spot in which direction ray is projected may be changed in size.
The option has been added to the motion control menu.
author | Ideenmodellierer |
---|---|
date | Fri, 12 Feb 2021 21:37:50 +0100 |
parents | 2702bfa7b177 |
children | bc6c90e20d9e |
line wrap: on
line source
/** ****************************************************************************** * @copyright heinrichs weikamp * @file externLogbookFlash.c * @author heinrichs weikamp gmbh * @date 07-Aug-2014 * @version V0.0.4 * @since 29-Sept-2015 * @brief Main File to access the new 1.8 Volt Spansion S25FS256S 256 Mbit (32 Mbyte) * @bug * @warning * @verbatim ============================================================================== ##### Logbook Header (TOC) ##### ============================================================================== [..] Memory useage: NEW: Spansion S25FS-S256S only 8x 4KB and 1x 32KB, remaining is 64KB or 256KB Sector Size (kbyte) Sector Count Sector Range Address Range (Byte Address) Notes 4 8 SA00 00000000h-00000FFFh : : SA07 00007000h-00007FFFh 32 1 SA08 00008000h-0000FFFFh 64 511 SA09 00010000h-0001FFFFh : : SA519 01FF0000h-01FFFFFFh OLD: 1kB each header with predive header at beginning and postdive header with 0x400 HEADER2OFFSET 4kB (one erase) has two dives with 4 headers total total of 512 kB (with 256 header ids (8 bit)) Size is 280 Byte (as of 25.Nov. 2014) [..] Output to PC / UART is postdive header [..] Block Protection Lock-Down is to erase logbook only [..] Timing (see page 137 of LOGBOOK_V3_S25FS-S_00-271247.pdf bulk erase is 2 minutes typ., 6 minutes max. ============================================================================== ##### DEMOMODE ##### ============================================================================== 151215: ext_flash_write_settings() is DISABLED! ============================================================================== ##### bug fixes ##### ============================================================================== 150917: end in header and length of sample was one byte too long as stated by Jef Driesen email 15.09.2015 @endverbatim ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2015 heinrichs weikamp</center></h2> * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "stm32f4xx_hal.h" #include "externLogbookFlash.h" #include "ostc.h" #include "settings.h" #include "gfx_engine.h" #ifndef BOOTLOADER_STANDALONE #include "logbook.h" #endif /* Private types -------------------------------------------------------------*/ #define FLASHSTART 0x000000 //#define FLASHSTOP 0x01FFFFFF all 32 MB with 4byte addressing #define FLASHSTOP 0x00FFFFFF //#define FLASHSTOP 0x3FFFFF #define RELEASE 1 #define HOLDCS 0 #define HEADER2OFFSET 0x400 typedef enum{ EF_HEADER, EF_SAMPLE, EF_DEVICEDATA, EF_VPMDATA, EF_SETTINGS, EF_FIRMWARE, EF_FIRMWARE2, }which_ring_enum; typedef struct{ uint8_t IsBusy:1; uint8_t IsWriteEnabled:1; uint8_t BlockProtect0:1; uint8_t BlockProtect1:1; uint8_t BlockProtect2:1; uint8_t BlockProtect3:1; uint8_t IsAutoAddressIncMode:1; uint8_t BlockProtectL:1; } extFlashStatusUbit8_t; typedef union{ extFlashStatusUbit8_t ub; uint8_t uw; } extFlashStatusBit8_Type; /* Exported variables --------------------------------------------------------*/ /* Private variables ---------------------------------------------------------*/ static uint32_t actualAddress = 0; static uint32_t preparedPageAddress = 0; static uint32_t closeSectorAddress = 0; static uint32_t entryPoint = 0; static uint32_t actualPointerHeader = 0; static uint32_t actualPointerSample = 0; static uint32_t LengthLeftSampleRead = 0; static uint32_t actualPointerDevicedata = DDSTART; static uint32_t actualPointerDevicedata_Read = DDSTART; static uint32_t actualPointerVPM = 0; static uint32_t actualPointerSettings = SETTINGSSTART; static uint32_t actualPointerFirmware = 0; static uint32_t actualPointerFirmware2 = 0; /* Private function prototypes -----------------------------------------------*/ static void chip_unselect(void); static void chip_select(void); static void error_led_on(void); static void error_led_off(void); static void write_spi(uint8_t data, uint8_t unselect_CS_afterwards); static uint8_t read_spi(uint8_t unselect_CS_afterwards); static void write_address(uint8_t unselect_CS_afterwards); static void Error_Handler_extflash(void); static void wait_chip_not_busy(void); static void ext_flash_incf_address(uint8_t type); //void ext_flash_incf_address_ring(void); static void ext_flash_decf_address_ring(uint8_t type); static void ext_flash_erase4kB(void); static void ext_flash_erase32kB(void); static void ext_flash_erase64kB(void); static uint8_t ext_flash_erase_if_on_page_start(void); static void ef_write_block(uint8_t * sendByte, uint32_t length, uint8_t type, uint8_t do_not_erase); static void ext_flash_read_block(uint8_t *getByte, uint8_t type); static void ext_flash_read_block_multi(void *getByte, uint32_t size, uint8_t type); static void ext_flash_read_block_stop(void); static void ef_hw_rough_delay_us(uint32_t delayUs); static void ef_erase_64K(uint32_t blocks); static void ext_flash_overwrite_sample_without_erase(uint8_t *pSample, uint16_t length); static void ext_flash_disable_protection(void); static _Bool ext_flash_test_remaining_space_of_page_empty(uint32_t pointer, uint16_t length); static void ext_flash_set_to_begin_of_next_page(uint32_t *pointer, uint8_t type); static void ext_flash_find_start(void); /* Exported functions --------------------------------------------------------*/ void ext_flash_write_firmware(uint8_t *pSample1, uint32_t length1)//, uint8_t *pSample2, uint32_t length2) { general32to8_Type lengthTransform; lengthTransform.u32 = length1; actualPointerFirmware = FWSTART; ef_write_block(lengthTransform.u8,4, EF_FIRMWARE, 1); ef_write_block(pSample1,length1, EF_FIRMWARE, 1); // if(length2) // ef_write_block(pSample2,length2, EF_FIRMWARE, 1); } uint8_t ext_flash_read_firmware_version(char *text) { uint32_t backup = actualAddress; uint8_t buffer[4]; // + 4 for length data, see ext_flash_write_firmware actualAddress = FWSTART + 4 + 0x10000; ext_flash_read_block_start(); ext_flash_read_block(&buffer[0], EF_FIRMWARE); ext_flash_read_block(&buffer[1], EF_FIRMWARE); ext_flash_read_block(&buffer[2], EF_FIRMWARE); ext_flash_read_block(&buffer[3], EF_FIRMWARE); ext_flash_read_block_stop(); actualAddress = backup; uint8_t ptr = 0; text[ptr++] = 'V'; ptr += gfx_number_to_string(2,0,&text[ptr],buffer[0] & 0x3F); text[ptr++] = '.'; ptr += gfx_number_to_string(2,0,&text[ptr],buffer[1] & 0x3F); text[ptr++] = '.'; ptr += gfx_number_to_string(2,0,&text[ptr],buffer[2] & 0x3F); text[ptr++] = ' '; if(buffer[3]) { text[ptr++] = 'b'; text[ptr++] = 'e'; text[ptr++] = 't'; text[ptr++] = 'a'; text[ptr++] = ' '; } return ptr; } uint32_t ext_flash_read_firmware(uint8_t *pSample1, uint32_t max_length, uint8_t *magicByte) { uint32_t backup = actualAddress; general32to8_Type lengthTransform; actualAddress = FWSTART; ext_flash_read_block_start(); ext_flash_read_block(&lengthTransform.u8[0], EF_FIRMWARE); ext_flash_read_block(&lengthTransform.u8[1], EF_FIRMWARE); ext_flash_read_block(&lengthTransform.u8[2], EF_FIRMWARE); ext_flash_read_block(&lengthTransform.u8[3], EF_FIRMWARE); if(lengthTransform.u32 == 0xFFFFFFFF) { lengthTransform.u32 = 0xFFFFFFFF; } else if(lengthTransform.u32 > max_length) { lengthTransform.u32 = 0xFF000000; } else { for(uint32_t i = 0; i<lengthTransform.u32; i++) { ext_flash_read_block(&pSample1[i], EF_FIRMWARE); } } ext_flash_read_block_stop(); if(magicByte) { *magicByte = pSample1[0x10000 + 0x3E]; // 0x3E == 62 } actualAddress = backup; return lengthTransform.u32; } void ext_flash_write_firmware2(uint32_t offset, uint8_t *pSample1, uint32_t length1, uint8_t *pSample2, uint32_t length2) { general32to8_Type lengthTransform, offsetTransform; lengthTransform.u32 = length1 + length2; offsetTransform.u32 = offset; actualPointerFirmware2 = FWSTART2; ef_write_block(lengthTransform.u8,4, EF_FIRMWARE2, 1); ef_write_block(offsetTransform.u8,4, EF_FIRMWARE2, 1); ef_write_block(pSample1,length1, EF_FIRMWARE2, 1); if(length2) ef_write_block(pSample2,length2, EF_FIRMWARE2, 1); } uint32_t ext_flash_read_firmware2(uint32_t *offset, uint8_t *pSample1, uint32_t max_length1, uint8_t *pSample2, uint32_t max_length2) { uint32_t backup = actualAddress; uint32_t length1, length2; general32to8_Type lengthTransform, offsetTransform; actualAddress = FWSTART2; ext_flash_read_block_start(); ext_flash_read_block(&lengthTransform.u8[0], EF_FIRMWARE2); ext_flash_read_block(&lengthTransform.u8[1], EF_FIRMWARE2); ext_flash_read_block(&lengthTransform.u8[2], EF_FIRMWARE2); ext_flash_read_block(&lengthTransform.u8[3], EF_FIRMWARE2); ext_flash_read_block(&offsetTransform.u8[0], EF_FIRMWARE2); ext_flash_read_block(&offsetTransform.u8[1], EF_FIRMWARE2); ext_flash_read_block(&offsetTransform.u8[2], EF_FIRMWARE2); ext_flash_read_block(&offsetTransform.u8[3], EF_FIRMWARE2); *offset = offsetTransform.u32; if(lengthTransform.u32 == 0xFFFFFFFF) { lengthTransform.u32 = 0xFFFFFFFF; } else if(lengthTransform.u32 > max_length1 + max_length2) { lengthTransform.u32 = 0xFF000000; } else { if(lengthTransform.u32 < max_length1) { length1 = lengthTransform.u32; length2 = 0; } else { length1 = max_length1; length2 = lengthTransform.u32 - max_length1; } if(pSample1) { for(uint32_t i = 0; i<length1; i++) { ext_flash_read_block(&pSample1[i], EF_FIRMWARE2); } if(pSample2) { for(uint32_t i = 0; i<length2; i++) { ext_flash_read_block(&pSample2[i], EF_FIRMWARE2); } } } else if(pSample2) { actualAddress += length1; for(uint32_t i = 0; i<length2; i++) { ext_flash_read_block(&pSample2[i], EF_FIRMWARE2); } } } ext_flash_read_block_stop(); actualAddress = backup; return lengthTransform.u32; } void ext_flash_read_fixed_16_devicedata_blocks_formated_128byte_total(uint8_t *buffer) { SDeviceLine data[16]; uint8_t tempLengthIngnore; uint16_t count; uint8_t transfer; RTC_DateTypeDef Sdate; RTC_TimeTypeDef Stime; actualAddress = DDSTART; ext_flash_read_block_start(); ext_flash_read_block(&tempLengthIngnore, EF_DEVICEDATA); ext_flash_read_block(&tempLengthIngnore, EF_DEVICEDATA); ext_flash_read_block_multi((uint8_t *)data,16*3*4, EF_DEVICEDATA); ext_flash_read_block_stop(); count = 0; for(int i=0;i<16;i++) { transfer = (data[i].value_int32 >> 24) & 0xFF; buffer[count++] = transfer; transfer = (data[i].value_int32 >> 16) & 0xFF; buffer[count++] = transfer; transfer = (data[i].value_int32 >> 8) & 0xFF; buffer[count++] = transfer; transfer = (data[i].value_int32) & 0xFF; buffer[count++] = transfer; translateDate(data[i].date_rtc_dr, &Sdate); translateTime(data[i].time_rtc_tr, &Stime); buffer[count++] = Sdate.Year; buffer[count++] = Sdate.Month; buffer[count++] = Sdate.Date; buffer[count++] = Stime.Hours; } } #ifndef BOOTLOADER_STANDALONE void ext_flash_write_devicedata(uint8_t resetRing) { uint8_t *pData; const uint16_t length = sizeof(SDevice); uint8_t length_lo, length_hi; uint8_t dataLength[2] = { 0 }; uint32_t tmpBlockStart; ext_flash_disable_protection(); pData = (uint8_t *)stateDeviceGetPointer(); /* Reset the Ring to the start address if requested (e.g. because we write the default block during shutdown) */ if((resetRing) || ((actualPointerDevicedata + length) >= DDSTOP)) { actualPointerDevicedata = DDSTART; } tmpBlockStart = actualPointerDevicedata; length_lo = (uint8_t)(length & 0xFF); length_hi = (uint8_t)(length >> 8); dataLength[0] = length_lo; dataLength[1] = length_hi; ef_write_block(dataLength,2, EF_DEVICEDATA, 0); ef_write_block(pData,length, EF_DEVICEDATA, 0); actualPointerDevicedata_Read = tmpBlockStart; } uint16_t ext_flash_read_devicedata(uint8_t *buffer, uint16_t max_length) { uint16_t length; uint8_t length_lo, length_hi; actualAddress = actualPointerDevicedata_Read; length = 0; length_lo = 0; length_hi = 0; ext_flash_read_block_start(); ext_flash_read_block(&length_lo, EF_DEVICEDATA); ext_flash_read_block(&length_hi, EF_DEVICEDATA); while ((length_lo != 0xFF) && (length_hi != 0xFF)) { length = (length_hi * 256) + length_lo; if(length > max_length) return 0; ext_flash_read_block_multi(buffer,length,EF_DEVICEDATA); ext_flash_read_block(&length_lo, EF_DEVICEDATA); /* check if another devicedata set is available */ ext_flash_read_block(&length_hi, EF_DEVICEDATA); /* length will be 0xFFFF if a empty memory is read */ } ext_flash_decf_address_ring(EF_DEVICEDATA); /* set pointer back to empty address */ ext_flash_decf_address_ring(EF_DEVICEDATA); ext_flash_read_block_stop(); if(actualAddress > actualPointerDevicedata) /* the write pointer has not yet been set up probably */ { actualPointerDevicedata = actualAddress; } return length; } void ext_flash_write_vpm(SVpm *vpmInput) { uint8_t *pData; const uint16_t length = sizeof(SVpm); uint8_t length_lo, length_hi; uint8_t dataLength[2] = { 0 }; pData = (uint8_t *)vpmInput; actualPointerVPM = VPMSTART; length_lo = (uint8_t)(length & 0xFF); length_hi = (uint8_t)(length >> 8); dataLength[0] = length_lo; dataLength[1] = length_hi; ef_write_block(dataLength,2, EF_VPMDATA, 0); ef_write_block(pData,length, EF_VPMDATA, 0); } int ext_flash_read_vpm(SVpm *vpmOutput) { uint8_t *pData; const uint16_t length = sizeof(SVpm); uint8_t length_lo, length_hi; int output; actualAddress = VPMSTART; ext_flash_read_block_start(); ext_flash_read_block(&length_lo, EF_VPMDATA); ext_flash_read_block(&length_hi, EF_VPMDATA); if((length_lo == (uint8_t)(length & 0xFF)) &&(length_hi == (uint8_t)(length >> 8))) { pData = (uint8_t *)vpmOutput; for(uint16_t i = 0; i < length; i++) ext_flash_read_block(&pData[i], EF_VPMDATA); output = length; } else output = 0; ext_flash_read_block_stop(); return output; } #ifdef DEMOMODE void ext_flash_write_settings(void) { return; } #else void ext_flash_write_settings(uint8_t resetRing) { uint8_t *pData; const uint16_t length = sizeof(SSettings); uint8_t length_lo, length_hi; uint8_t dataLength[2] = { 0 }; ext_flash_disable_protection(); if(stateRealGetPointer()->lastKnownBatteryPercentage) { settingsGetPointer()->lastKnownBatteryPercentage = stateRealGetPointer()->lastKnownBatteryPercentage; } settingsGetPointer()->backup_localtime_rtc_tr = stateRealGetPointer()->lifeData.timeBinaryFormat; settingsGetPointer()->backup_localtime_rtc_dr = stateRealGetPointer()->lifeData.dateBinaryFormat; pData = (uint8_t *)settingsGetPointer(); /* Reset the Ring to the start address if requested (e.g. because we write the default block during shutdown) */ if((resetRing) || ((actualPointerSettings + length) >= SETTINGSSTOP)) { actualPointerSettings = SETTINGSSTART; } length_lo = (uint8_t)(length & 0xFF); length_hi = (uint8_t)(length >> 8); dataLength[0] = length_lo; dataLength[1] = length_hi; ef_write_block(dataLength,2, EF_SETTINGS, 0); ef_write_block(pData,length, EF_SETTINGS, 0); // ext_flash_enable_protection(); } #endif /* CHANGES 150929 hw * this now allows to read old settings too * but make sure that everything is fixed in * set_new_settings_missing_in_ext_flash * new settings should be fine as they are added * and loaded before calling this function */ uint8_t ext_flash_read_settings(void) { uint8_t returnValue = HAL_BUSY; uint8_t exit = 0; uint8_t *pData; const uint16_t lengthStandardNow = sizeof(SSettings); uint8_t length_lo, length_hi; uint16_t lengthOnEEPROM; uint32_t header; SSettings *pSettings = settingsGetPointer(); actualAddress = SETTINGSSTART; ext_flash_read_block_start(); ext_flash_read_block(&length_lo, EF_SETTINGS); ext_flash_read_block(&length_hi, EF_SETTINGS); while ((length_lo != 0xFF) && (length_hi != 0xFF) && (exit == 0)) /* get the latest stored setting block */ { lengthOnEEPROM = length_hi * 256; lengthOnEEPROM += length_lo; if(lengthOnEEPROM <= lengthStandardNow) /* EEPROM Header size equal or smaller => settings constant or upgraded */ { ext_flash_read_block_multi(&header, 4, EF_SETTINGS); if((header <= pSettings->header) && (header >= pSettings->updateSettingsAllowedFromHeader)) /* check to allow update of header */ { returnValue = HAL_OK; pSettings->header = header; pData = (uint8_t *)pSettings + 4; /* header */ for(uint16_t i = 0; i < (lengthOnEEPROM-4); i++) ext_flash_read_block(&pData[i], EF_SETTINGS); if(header != pSettings->header) /* setting layout changed => no additional setting sets expected */ { exit = 1; } } else { returnValue = HAL_ERROR; exit = 1; } } else /* size of settings decreased => possible downgrade of firmware */ { ext_flash_read_block_multi(&header, 4, EF_SETTINGS); if(header > 0xFFFF0014) /* verify that new (old) header should be compatible (only less bytes, no change in layout) */ { returnValue = HAL_OK; pSettings->header = header; pData = (uint8_t *)pSettings + 4; /* header */ for(uint16_t i = 0; i < (lengthStandardNow-4); i++) /* only read the data fitting into the structure */ ext_flash_read_block(&pData[i], EF_SETTINGS); } else { returnValue = HAL_ERROR; } exit = 1; } ext_flash_read_block(&length_lo, EF_SETTINGS); ext_flash_read_block(&length_hi, EF_SETTINGS); } ext_flash_decf_address_ring(EF_SETTINGS); /* set pointer back to empty address */ ext_flash_decf_address_ring(EF_SETTINGS); ext_flash_read_block_stop(); if(actualAddress > actualPointerSettings) /* the write pointer has not yet been set up probably */ { actualPointerSettings = actualAddress; } ext_flash_read_block_stop(); return returnValue; } /* ext_flash_start_new_dive_log_and_set_actualPointerSample * prepares the write sample pointer * to be used by ext_flash_write_sample() * to be set in the * pHeaderPreDive * for write with ext_flash_create_new_dive_log() and ext_flash_close_new_dive_log() */ void ext_flash_start_new_dive_log_and_set_actualPointerSample(uint8_t *pHeaderPreDive) { convert_Type data; SSettings *settings = settingsGetPointer(); /* new 5. Jan. 2015 */ actualPointerSample = settings->logFlashNextSampleStartAddress; if(!ext_flash_test_remaining_space_of_page_empty(actualPointerSample, 4)) ext_flash_set_to_begin_of_next_page(&actualPointerSample, EF_SAMPLE); if((actualPointerSample < SAMPLESTART) || (actualPointerSample > SAMPLESTOP)) actualPointerSample = SAMPLESTART; data.u32bit = actualPointerSample; pHeaderPreDive[2] = data.u8bit.byteLow; pHeaderPreDive[3] = data.u8bit.byteMidLow; pHeaderPreDive[4] = data.u8bit.byteMidHigh; /* to start sample writing and header etc. pp. */ ext_flash_disable_protection_for_logbook(); } /* ext_flash_create_new_dive_log * uses the first header without HEADER2OFFSET * for the header it is not important to be complete * and can be reconstructed * ext_flash_start_new_dive_log_and_set_actualPointerSample() * has to be called before to set the actualPointerSample * in the header * the following func writes to header to the ext_flash */ void ext_flash_create_new_dive_log(uint8_t *pHeaderPreDive) { SSettings *settings; uint8_t id; uint8_t header1, header2; settings = settingsGetPointer(); id = settings->lastDiveLogId; actualAddress = HEADERSTART + (0x800 * id); ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_SAMPLE); /* the sample ring is increased instead of header... not sure if that is planned intention */ ext_flash_read_block(&header2, EF_SAMPLE); /* does not matter because actual address is reset in write_block call */ ext_flash_read_block_stop(); /* TODO Cleanup_Ref_2: The code below should not be necessary in case of a proper shutdown and startup */ /* the implementation fixes an issue which might happen at Cleanup_Ref_1 (in case of more then 254 dives) */ if((header1 == 0xFA) && (header2 == 0xFA)) { id += 1; /* 0-255, auto rollover */ if(id & 1) { actualAddress = HEADERSTART + (0x800 * id); ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_SAMPLE); ext_flash_read_block(&header2, EF_SAMPLE); ext_flash_read_block_stop(); if((header1 == 0xFA) && (header2 == 0xFA)) id += 1; } } else { id = 0; } settings->lastDiveLogId = id; actualPointerHeader = HEADERSTART + (0x800 * id); if(pHeaderPreDive != 0) ef_write_block(pHeaderPreDive,HEADERSIZE, EF_HEADER, 0); } void ext_flash_close_new_dive_log(uint8_t *pHeaderPostDive ) { SSettings * settings = settingsGetPointer(); uint8_t id; convert_Type startAddress; convert_Type data; uint32_t backup; uint8_t sampleData[3]; actualAddress = actualPointerSample; sampleData[0] = 0xFD; sampleData[1] = 0xFD; ext_flash_write_sample(sampleData, 2); /* end of sample data, pointing to the last sample 0xFD */ actualAddress = actualPointerSample; // change hw 17.09.2015 ext_flash_decf_address_ring(EF_SAMPLE); // 17.09.2015: this decf actualAddress only!! actualPointerSample = actualAddress; // change hw 17.09.2015 data.u32bit = actualPointerSample; pHeaderPostDive[5] = data.u8bit.byteLow; pHeaderPostDive[6] = data.u8bit.byteMidLow; pHeaderPostDive[7] = data.u8bit.byteMidHigh; /* take data written before, calculate length and write SLogbookHeader has different order: length (byte# 8,9,10) prior to profile version (byte# 11) */ startAddress.u8bit.byteLow = pHeaderPostDive[2]; startAddress.u8bit.byteMidLow = pHeaderPostDive[3]; startAddress.u8bit.byteMidHigh = pHeaderPostDive[4]; startAddress.u8bit.byteHigh = 0; if(startAddress.u32bit < actualPointerSample) data.u32bit = 1 + actualPointerSample - startAddress.u32bit; else data.u32bit = 2 + (actualPointerSample - SAMPLESTART) + (SAMPLESTOP - startAddress.u32bit); pHeaderPostDive[8] = data.u8bit.byteLow; pHeaderPostDive[9] = data.u8bit.byteMidLow; pHeaderPostDive[10] = data.u8bit.byteMidHigh; /* set id and write post-dive-header */ id = settings->lastDiveLogId; actualPointerHeader = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ef_write_block(pHeaderPostDive,HEADERSIZE, EF_HEADER, 0); /* write length at beginning of sample and write proper beginning for next dive to actualPointerSample */ backup = actualPointerSample; actualPointerSample = startAddress.u32bit; // is still 0xFF sampleData[0] = data.u8bit.byteLow; sampleData[1] = data.u8bit.byteMidLow; sampleData[2] = data.u8bit.byteMidHigh; ext_flash_overwrite_sample_without_erase(sampleData, 3); actualAddress = backup; ext_flash_incf_address(EF_SAMPLE); actualPointerSample = actualAddress; ext_flash_enable_protection(); } void ext_flash_write_sample(uint8_t *pSample, uint16_t length) { uint32_t actualAdressBackup = 0; ef_write_block(pSample,length, EF_SAMPLE, 0); SSettings *settings = settingsGetPointer(); settings->logFlashNextSampleStartAddress = actualPointerSample; if(0xFFFF - (actualAddress & 0x0000FFFF) < 255) /* are we close to a sector border? */ { if (((actualAddress & 0x0000FFFF) != 0) && (preparedPageAddress == 0)) /* only prepare if not already at start of sector */ { actualAdressBackup = actualAddress; actualAddress = (actualAddress & 0xFFFF0000) + 0x00010000; /* Set to start of next 64k sector */ if(actualAddress >= SAMPLESTOP) { actualAddress = SAMPLESTART; } preparedPageAddress = actualAddress; ext_flash_erase64kB(); actualAddress = actualAdressBackup; } } } static void ext_flash_overwrite_sample_without_erase(uint8_t *pSample, uint16_t length) { ef_write_block(pSample,length, EF_SAMPLE, 1); } uint8_t ext_flash_count_dive_headers(void) { uint8_t id = 0; uint8_t counter = 0; uint16_t headerStartData = 0x0000; id = settingsGetPointer()->lastDiveLogId; do { actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); ext_flash_read_block_multi((uint8_t *)&headerStartData, 2, EF_HEADER); ext_flash_read_block_stop(); counter++; id -=1; } while((headerStartData == 0xFAFA) && (counter < 255)); return (counter - 1); } void ext_flash_read_dive_header(uint8_t *pHeaderToFill, uint8_t StepBackwards) { SSettings *settings; uint8_t id; uint16_t i; settings = settingsGetPointer(); id = settings->lastDiveLogId; id -= StepBackwards; /* 0-255, auto rollover */ actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); for(i = 0; i < HEADERSIZE; i++) ext_flash_read_block(&pHeaderToFill[i], EF_HEADER); ext_flash_read_block_stop(); } void ext_flash_read_dive_header2(uint8_t *pHeaderToFill, uint8_t id, _Bool bOffset) { uint16_t i; actualAddress = HEADERSTART + (0x800 * id) ; if(bOffset) actualAddress += HEADER2OFFSET; ext_flash_read_block_start(); for(i = 0; i < HEADERSIZE; i++) ext_flash_read_block(&pHeaderToFill[i], EF_HEADER); ext_flash_read_block_stop(); } uint32_t ext_flash_read_dive_raw_with_double_header_1K(uint8_t *data, uint32_t max_size, uint8_t StepBackwards) { if(max_size < 0x800) return 0; uint8_t id; convert_Type dataStart, dataEnd; uint32_t LengthAll = 0; id = settingsGetPointer()->lastDiveLogId; id -= StepBackwards; /* 0-255, auto rollover */ // clear data for(int i=0;i<0x800;i++) data[i] = 0xFF; // copy primary/pre-dive actualAddress = HEADERSTART + (0x800 * id); ext_flash_read_block_start(); for(int i = 0; i < HEADERSIZE; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // copy main/secondary/post-dive actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); for(int i = 0x400; i < HEADERSIZE+0x400; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // data dataStart.u8bit.byteHigh = 0; dataStart.u8bit.byteLow = data[0x402]; dataStart.u8bit.byteMidLow = data[0x403]; dataStart.u8bit.byteMidHigh = data[0x404]; dataEnd.u8bit.byteHigh = 0; dataEnd.u8bit.byteLow = data[0x405]; dataEnd.u8bit.byteMidLow = data[0x406]; dataEnd.u8bit.byteMidHigh = data[0x407]; actualPointerSample = dataStart.u32bit; if(dataEnd.u32bit >= dataStart.u32bit) LengthAll = 1 + dataEnd.u32bit - dataStart.u32bit; else LengthAll = 2 + (dataStart.u32bit - SAMPLESTART) + (SAMPLESTOP - dataEnd.u32bit); LengthAll += 0x800; if(LengthAll > max_size) return 0x800; actualAddress = actualPointerSample; ext_flash_read_block_start(); for(uint32_t i = 0x800; i < LengthAll; i++) ext_flash_read_block(&data[i], EF_SAMPLE); ext_flash_read_block_stop(); return LengthAll; } void ext_flash_write_dive_raw_with_double_header_1K(uint8_t *data, uint32_t length) { convert_Type dataStart, dataEnd; SLogbookHeader headerTemp; // set actualPointerSample and get pointer to sample storage and disable flash write protect ext_flash_start_new_dive_log_and_set_actualPointerSample((uint8_t *)&headerTemp); dataStart.u8bit.byteHigh = 0; dataStart.u8bit.byteLow = headerTemp.pBeginProfileData[0]; dataStart.u8bit.byteMidLow = headerTemp.pBeginProfileData[1]; dataStart.u8bit.byteMidHigh = headerTemp.pBeginProfileData[2]; dataEnd.u32bit = dataStart.u32bit + length - 0x801; if(dataEnd.u32bit > SAMPLESTOP) dataEnd.u32bit -= SAMPLESTOP + SAMPLESTART - 1; data[0x002] = data[0x402] = dataStart.u8bit.byteLow; data[0x003] = data[0x403] = dataStart.u8bit.byteMidLow; data[0x004] = data[0x404] = dataStart.u8bit.byteMidHigh; data[0x005] = data[0x405] = dataEnd.u8bit.byteLow; data[0x006] = data[0x406] = dataEnd.u8bit.byteMidLow; data[0x007] = data[0x407] = dataEnd.u8bit.byteMidHigh; // set actualPointerHeader to next free header and update lastDiveLogId ext_flash_create_new_dive_log(0); // copy header data ef_write_block(data,0x800,EF_HEADER, 1); // copy sample data ef_write_block(&data[0x800], length-0x800, EF_SAMPLE, 1); // update logFlashNextSampleStartAddress settingsGetPointer()->logFlashNextSampleStartAddress = actualPointerSample; } // =============================================================================== // ext_flash_read_header_memory /// @brief This function returns the entire header space 1:1 /// @date 04-April-2016 /// /// @param *data 256KB output // =============================================================================== void ext_flash_read_header_memory(uint8_t *data) { actualAddress = HEADERSTART; actualPointerHeader = actualAddress; ext_flash_read_block_start(); for(int i=0;i<8;i++) ext_flash_read_block_multi(&data[0x8000 * i], 0x8000, EF_HEADER); ext_flash_read_block_stop(); } // =============================================================================== // ext_flash_write_header_memory /// @brief This function erases and overwrites the entire logbook header block /// @date 04-April-2016 /// /// @param *data 256KB input of header memory 1:1 // =============================================================================== void ext_flash_write_header_memory(uint8_t *data) { actualAddress = HEADERSTART; actualPointerHeader = actualAddress; ef_write_block(data, 0x40000, EF_HEADER, 0); } void ext_flash_read_sample_memory(uint8_t *data,uint16_t blockId) { actualAddress = SAMPLESTART; actualAddress += blockId * 0x8000; /* add 32k Block offset */ actualPointerSample = actualAddress; ext_flash_read_block_start(); ext_flash_read_block_multi(data, 0x8000, EF_SAMPLE); ext_flash_read_block_stop(); } void ext_flash_write_sample_memory(uint8_t *data,uint16_t blockId) { actualAddress = SAMPLESTART; actualAddress += blockId * 0x8000; /* add 32k Block offset */ actualPointerSample = actualAddress; ef_write_block(data, 0x8000, EF_SAMPLE,0); } void ext_flash_open_read_sample(uint8_t StepBackwards, uint32_t *totalNumberOfBytes) { SSettings *settings = settingsGetPointer(); uint8_t id; convert_Type dataStart, dataEnd; uint8_t header1, header2; id = settings->lastDiveLogId; id -= StepBackwards; /* 0-255, auto rollover */ # actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; actualPointerHeader = actualAddress; ext_flash_read_block_start(); /* little endian */ ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); dataStart.u8bit.byteHigh = 0; ext_flash_read_block(&dataStart.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidHigh, EF_HEADER); dataEnd.u8bit.byteHigh = 0; ext_flash_read_block(&dataEnd.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataEnd.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataEnd.u8bit.byteMidHigh, EF_HEADER); ext_flash_read_block_stop(); actualPointerSample = dataStart.u32bit; if(dataEnd.u32bit >= dataStart.u32bit) LengthLeftSampleRead = 1 + dataEnd.u32bit - dataStart.u32bit; else LengthLeftSampleRead = 2 + (dataStart.u32bit - SAMPLESTART) + (SAMPLESTOP - dataEnd.u32bit); *totalNumberOfBytes = LengthLeftSampleRead; actualAddress = actualPointerSample; ext_flash_read_block_start(); } void ext_flash_read_next_sample_part(uint8_t *pSample, uint8_t length) { for(uint16_t i = 0; i < length; i++) ext_flash_read_block(&pSample[i], EF_SAMPLE); } void ext_flash_close_read_sample(void) { actualPointerSample = actualAddress; ext_flash_read_block_stop(); } void ext_flash_set_entry_point(void) { entryPoint = actualAddress; } void ext_flash_reopen_read_sample_at_entry_point(void) { error_led_on(); chip_unselect(); wait_chip_not_busy(); actualAddress = entryPoint; ext_flash_read_block_start(); error_led_off(); } /* uint8_t ext_flash_point_to_64k_block_in_headerSpace(uint8_t logId) { uint32_t pointerToData = logId * 0x800; return pointerToData / 0x10000; } */ // =============================================================================== // ext_flash_repair_dive_numbers_starting_count_helper /// @brief /// @date 22-June-2016 // =============================================================================== static uint16_t ext_flash_repair_dive_numbers_starting_count_helper(uint8_t *data, uint8_t *change64k, uint16_t startNumber, uint8_t lastLogId) { const uint32_t headerStep = 0x800; uint8_t actualLogId = 0; uint16_t oldNumber = 0; uint16_t actualNumber = 0; SLogbookHeader *ptrLogbookHeader = 0; if(startNumber == 0) return 0; actualNumber = startNumber - 1; // where is the oldest dive (Which is now getting startNumber) // use first header for ease (without HEADER2OFFSET for end of dive header) // compare for lastLogId to prevent endless loop if(*(uint16_t*)&data[lastLogId * headerStep] != 0xFAFA) return 0; actualLogId = lastLogId - 1; while((*(uint16_t*)&data[actualLogId * headerStep] == 0xFAFA) && (actualLogId != lastLogId)) { actualLogId--; } // now pointing to one behind the last while(actualLogId != lastLogId) { actualLogId++; actualNumber++; ptrLogbookHeader = (SLogbookHeader *)&data[actualLogId * headerStep]; oldNumber = ptrLogbookHeader->diveNumber; if(oldNumber != actualNumber) { // change64k[ext_flash_point_to_64k_block_in_headerSpace(actualLogId )] = 1; change64k[(actualLogId * 0x800)/0x10000] = 1; ptrLogbookHeader->diveNumber = actualNumber; ptrLogbookHeader = (SLogbookHeader *)(&data[actualLogId * headerStep] + HEADER2OFFSET); ptrLogbookHeader->diveNumber = actualNumber; } } return actualNumber; } // =============================================================================== // ext_flash_repair_SPECIAL_dive_numbers_starting_count_with /// @brief This function /// @date 04-April-2016 /// problem (160621): 64K blocks (32 dives) in the new flash memory chip /// This block needs to be deleted /// these where only 4KB block before /// @output endCount, last diveNumber // =============================================================================== uint16_t ext_flash_repair_SPECIAL_dive_numbers_starting_count_with(uint16_t startCount) { uint32_t logCopyDataPtr = 0; uint8_t *data; uint16_t lastCount; uint8_t listOfChanged64kBlocks[8]; // 32 dives each 64K logCopyDataPtr = getFrame(97); data = (uint8_t *)logCopyDataPtr; for(int i=0;i<8;i++) listOfChanged64kBlocks[i] = 0; actualAddress = HEADERSTART; ext_flash_read_block_start(); ext_flash_read_block_multi(data,0x100000,EF_HEADER); ext_flash_read_block_stop(); lastCount = ext_flash_repair_dive_numbers_starting_count_helper(data, listOfChanged64kBlocks, startCount, settingsGetPointer()->lastDiveLogId); for(int i=0;i<8;i++) { if(listOfChanged64kBlocks[i] != 0) { actualPointerHeader = HEADERSTART + (i * 0x10000); ef_write_block(&data[i * 0x10000], 0x10000, EF_HEADER, 0); } } releaseFrame(97,logCopyDataPtr); if(settingsGetPointer()->totalDiveCounter < lastCount) { settingsGetPointer()->totalDiveCounter = lastCount; } return lastCount; } /* void OLD_ext_flash_repair_SPECIAL_dive_numbers_starting_count_with(uint16_t startCount) { uint16_t counterStorage[256]; uint8_t start = 0xFF; uint32_t logCopyDataPtr = 0; uint8_t *data; uint8_t startAbsolute = 0; int16_t count = 0; _Bool repair = 0; uint8_t startBackup = 0; SLogbookHeader tempLogbookHeader; SLogbookHeader *ptrHeaderInData1a; SLogbookHeader *ptrHeaderInData1b; SLogbookHeader *ptrHeaderInData2a; SLogbookHeader *ptrHeaderInData2b; logCopyDataPtr = getFrame(97); data = (uint8_t *)logCopyDataPtr; ptrHeaderInData1a = (SLogbookHeader *)logCopyDataPtr; ptrHeaderInData1b = (SLogbookHeader *)(logCopyDataPtr + HEADER2OFFSET); ptrHeaderInData2a = (SLogbookHeader *)(logCopyDataPtr + 0x800); ptrHeaderInData2b = (SLogbookHeader *)(logCopyDataPtr + 0x800 + HEADER2OFFSET); // get data for(int StepBackwards = 0; StepBackwards < 255; StepBackwards++) { logbook_getHeader(StepBackwards, &tempLogbookHeader); counterStorage[StepBackwards+1] = tempLogbookHeader.diveNumber; if(tempLogbookHeader.diveHeaderStart == 0xFAFA) start = StepBackwards; else break; } if(start == 0xFF) return; count = start + 1; startAbsolute = settingsGetPointer()->lastDiveLogId; if(start%2) { if(counterStorage[start] != startCount) { // clear data for(int i=0;i<0x800*2;i++) data[i] = 0xFF; uint8_t id = settingsGetPointer()->lastDiveLogId; id -= start; // 0-255, auto rollover // copy primary/pre-dive actualAddress = HEADERSTART + (0x800 * id); ext_flash_read_block_start(); for(int i = 0; i < HEADERSIZE; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // copy main/secondary/post-dive actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); for(int i = 0x400; i < HEADERSIZE+0x400; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // repair ptrHeaderInData2a->diveNumber = startCount; ptrHeaderInData2b->diveNumber = startCount; startCount++; // write actualAddress = HEADERSTART + (0x800 * (id-1)); ef_write_block(data,0x800*2,EF_HEADER, 0); } start--; } // for(int count = start; count > -1; count -= 2) while(count > 0) { // clear data for(int i=0;i<0x1000;i++) data[i] = 0xFF; repair = 0; startBackup = startAbsolute; if(startAbsolute%2) // 0x800 to 0x1000 { // copy second pre-dive actualAddress = HEADERSTART + (0x800 * startAbsolute); ext_flash_read_block_start(); for(int i = 0x800; i < HEADERSIZE+0x800; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // copy second post-dive actualAddress = HEADERSTART + HEADER2OFFSET + (0x800 * startAbsolute); ext_flash_read_block_start(); for(int i = 0xC00; i < HEADERSIZE+0xC00; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); if(counterStorage[count] != startCount) { ptrHeaderInData2a->diveNumber = startCount; ptrHeaderInData2b->diveNumber = startCount; repair = 1; } startCount += 1; startAbsolute -= 1; count -= 1; if(count > 0) { // copy first pre-dive actualAddress = HEADERSTART + (0x800 * startAbsolute); ext_flash_read_block_start(); for(int i = 0; i < HEADERSIZE; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // copy first post-dive actualAddress = HEADERSTART + (0x800 * startAbsolute); ext_flash_read_block_start(); for(int i = 0x400; i < HEADERSIZE+0x400; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); if(counterStorage[count] != startCount) { ptrHeaderInData1a->diveNumber = startCount; ptrHeaderInData1b->diveNumber = startCount; repair = 1; } startCount += 1; startAbsolute -= 1; count -= 1; } } else { // copy first pre-dive actualAddress = HEADERSTART + (0x800 * startAbsolute); ext_flash_read_block_start(); for(int i = 0; i < HEADERSIZE; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); // copy first post-dive actualAddress = HEADERSTART + (0x800 * startAbsolute); ext_flash_read_block_start(); for(int i = 0x400; i < HEADERSIZE+0x400; i++) ext_flash_read_block(&data[i], EF_HEADER); ext_flash_read_block_stop(); if(counterStorage[count] != startCount) { ptrHeaderInData1a->diveNumber = startCount; ptrHeaderInData1b->diveNumber = startCount; repair = 1; } startCount += 1; startAbsolute -= 1; count -= 1; } // write if(repair) { actualPointerHeader = HEADERSTART + (0x1000 * startBackup%2); ef_write_block(data,0x1000,EF_HEADER, 0); } } releaseFrame(97,logCopyDataPtr); settingsGetPointer()->totalDiveCounter = startCount; } */ uint8_t ext_dive_log_consistent(void) { uint8_t ret = 0; uint8_t header1, header2; uint8_t id; convert_Type dataStart; convert_Type dataEnd; SSettings *settings = settingsGetPointer(); id = settings->lastDiveLogId; if(settings->lastDiveLogId != 0) /* not trust LogID 0 which might be reset by a settings problem */ { /* ==> Find function will be called restoring the Id belonging to the latest sample */ actualAddress = HEADERSTART + (0x800 * id); ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); ext_flash_read_block_stop(); if((header1 == 0xFA) && (header2 == 0xFA)) /* Header is indicating the start of a dive */ { actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); dataStart.u8bit.byteHigh = 0; ext_flash_read_block(&dataStart.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidHigh, EF_HEADER); dataEnd.u8bit.byteHigh = 0; ext_flash_read_block(&dataEnd.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataEnd.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataEnd.u8bit.byteMidHigh, EF_HEADER); ext_flash_read_block_stop(); if((header1 == 0xFA) && (header2 == 0xFA)) /* Secondary header was written at the end of a dive */ { if(dataStart.u32bit < dataEnd.u32bit) { ret = 1; /* => lastDiveLogID points to a valid dive entry */ } else /* check if address wrap is valid */ { if(ext_flash_SampleOverrunValid()) { ret = 1; } } } } } return ret; } // =============================================================================== // ext_flash_repair_dive_log /// @brief This function /// does set /// logFlashNextSampleStartAddress /// and /// lastDiveLogId /// void ext_flash_repair_dive_log(void) { uint8_t header1, header2; convert_Type dataStart; for(int id = 0; id < 255;id++) { actualAddress = HEADERSTART + (0x800 * id); ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); dataStart.u8bit.byteHigh = 0; ext_flash_read_block(&dataStart.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidHigh, EF_HEADER); ext_flash_read_block_stop(); if((header1 == 0xFA) && (header2 == 0xFA)) /* Header is indicating the start of a dive */ { actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); ext_flash_read_block_stop(); if((header1 != 0xFA) || (header2 != 0xFA)) /* Secondary header was not written at the end of a dive */ { actualPointerSample = dataStart.u32bit; /* Set datapointer to position stored in header written at beginning of dive */ actualAddress = actualPointerSample; logbook_recover_brokenlog(id); SSettings *settings = settingsGetPointer(); settings->logFlashNextSampleStartAddress = actualPointerSample; } } } ext_flash_find_start(); } static void ext_flash_find_start(void) { uint8_t id; uint8_t header1, header2; convert_Type dataStart, dataEnd; /* TODO Cleanup_Ref_1: cleanup logFlashNextSampleStartAddress and lastDiveLogId */ /* The implementation below would cause problems in case more then 254 dives would be done. */ /* This is avoided by Cleanup_Ref2 */ for(id = 0; id <= 255;id++) { actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); dataStart.u8bit.byteHigh = 0; ext_flash_read_block(&dataStart.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidHigh, EF_HEADER); ext_flash_read_block_stop(); if((header1 == 0xFF) && (header2 == 0xFF)) { break; } } id--; SSettings *settings = settingsGetPointer(); settings->lastDiveLogId = id; actualAddress = HEADERSTART + (0x800 * id) + HEADER2OFFSET; actualPointerHeader = actualAddress; ext_flash_read_block_start(); ext_flash_read_block(&header1, EF_HEADER); ext_flash_read_block(&header2, EF_HEADER); dataStart.u8bit.byteHigh = 0; ext_flash_read_block(&dataStart.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataStart.u8bit.byteMidHigh, EF_HEADER); dataEnd.u8bit.byteHigh = 0; ext_flash_read_block(&dataEnd.u8bit.byteLow, EF_HEADER); ext_flash_read_block(&dataEnd.u8bit.byteMidLow, EF_HEADER); ext_flash_read_block(&dataEnd.u8bit.byteMidHigh, EF_HEADER); ext_flash_read_block_stop(); //Find free space if((header1 == 0xFA) && (header2 == 0xFA)) { uint8_t uiRead = 0; int countFF = 0; //End of last complete dive actualPointerSample = dataEnd.u32bit ; actualAddress = actualPointerSample; //Check if there are samples of dives with less than half a minute while(true) { ext_flash_read_block_start(); ext_flash_read_block(&uiRead, EF_SAMPLE); if(uiRead == 0xFF) countFF++; else countFF = 0; if(countFF == 10) { actualAddress -= 10; break; } //New page: clear if(ext_flash_erase_if_on_page_start()) break; } // Set new start address actualPointerSample = actualAddress; settings->logFlashNextSampleStartAddress = actualPointerSample; } else { settings->logFlashNextSampleStartAddress = SAMPLESTART; } } #endif static void ext_flash_disable_protection(void) { /* extFlashStatusBit8_Type status; status.uw = 0; wait_chip_not_busy(); write_spi(0x50,RELEASE); // EWSR write_spi(0x01,HOLDCS); // WRSR write_spi(status.uw,RELEASE); // new status */ } void ext_flash_disable_protection_for_logbook(void) { /* extFlashStatusBit8_Type status; status.uw = 0; status.ub.BlockProtect0 = 1; status.ub.BlockProtect1 = 0; status.ub.BlockProtect2 = 1; status.ub.BlockProtect3 = 0; // not set in OSTC3. Why? wait_chip_not_busy(); write_spi(0x50,RELEASE); // EWSR write_spi(0x01,HOLDCS); // WRSR write_spi(status.uw,RELEASE); // new status */ } void ext_flash_enable_protection(void) { /* extFlashStatusBit8_Type status; status.uw = 0; status.ub.BlockProtect0 = 1; status.ub.BlockProtect1 = 1; status.ub.BlockProtect2 = 1; status.ub.BlockProtect3 = 1; // not set in OSTC3. Why? wait_chip_not_busy(); write_spi(0x50,RELEASE); // EWSR write_spi(0x01,HOLDCS); // WRSR write_spi(status.uw,RELEASE); // new status */ } /*void ext_flash_erase_chip(void) { wait_chip_not_busy(); write_spi(0x06,RELEASE); write_spi(0x60,RELEASE); wait_chip_not_busy(); }*/ void ext_flash_erase_firmware(void) { uint32_t size, blocks_64k; actualAddress = FWSTART; size = 1 + FWSTOP - FWSTART; blocks_64k = size / 0x10000; ef_erase_64K(blocks_64k); } void ext_flash_erase_firmware2(void) { uint32_t size, blocks_64k; actualAddress = FWSTART2; size = 1 + FWSTOP2 - FWSTART2; blocks_64k = size / 0x10000; ef_erase_64K(blocks_64k); } void ext_flash_erase_logbook(void) { uint32_t size, blocks_64k; ext_flash_disable_protection_for_logbook(); actualAddress = SAMPLESTART; size = 1 + SAMPLESTOP - SAMPLESTART; blocks_64k = size / 0x10000; ef_erase_64K(blocks_64k); actualAddress = HEADERSTART; size = 1 + HEADERSTOP - HEADERSTART; blocks_64k = size / 0x10000; ef_erase_64K(blocks_64k); ext_flash_enable_protection(); } static void ext_flash_erase4kB(void) { wait_chip_not_busy(); write_spi(0x06,RELEASE);/* WREN */ write_spi(0x20,HOLDCS);/* sector erase cmd */ write_address(RELEASE); } /* be careful - might not work with entire family and other products * see page 14 of LOGBOOK_V3_S25FS-S_00-271247.pdf */ static void ext_flash_erase32kB(void) { uint32_t actualAddress_backup; actualAddress_backup = actualAddress; actualAddress = 0; wait_chip_not_busy(); write_spi(0x06,RELEASE);/* WREN */ write_spi(0xD8,HOLDCS);/* sector erase cmd */ write_address(RELEASE); actualAddress = actualAddress_backup; } static void ext_flash_erase64kB(void) { wait_chip_not_busy(); write_spi(0x06,RELEASE);/* WREN */ write_spi(0xD8,HOLDCS);/* sector erase cmd */ write_address(RELEASE); } void ext_flash_read_block_start(void) { wait_chip_not_busy(); write_spi(0x03,HOLDCS); /* WREN */ write_address(HOLDCS); } /* 4KB, 32KB, 64 KB, not the upper 16 MB with 4 Byte address at the moment */ static uint8_t ext_flash_erase_if_on_page_start(void) { if(actualAddress < 0x00008000) { /* 4K Byte is 0x1000 */ if((actualAddress & 0xFFF) == 0) { ext_flash_erase4kB(); return 1; } } else if(actualAddress < 0x00010000) { /* 32K Byte is only one page */ if(actualAddress == 0x00010000) { ext_flash_erase32kB(); return 1; } } else { /* 64K Byte is 0x10000 */ if((actualAddress & 0xFFFF) == 0) { if(preparedPageAddress == actualAddress) /* has page already been prepared before? (at the moment for samples only) */ { preparedPageAddress = 0; } else { ext_flash_erase64kB(); } return 1; } } return 0; } static void ext_flash_read_block(uint8_t *getByte, uint8_t type) { *getByte = read_spi(HOLDCS);/* read data */ ext_flash_incf_address(type); } static void ext_flash_read_block_multi(void *getByte, uint32_t size, uint8_t type) { uint8_t *data; data = getByte; for(uint32_t i=0;i<size;i++) { data[i] = read_spi(HOLDCS);/* read data */ ext_flash_incf_address(type); } } static void ext_flash_read_block_stop(void) { chip_unselect(); } /* Private functions ---------------------------------------------------------*/ static void ef_write_block(uint8_t * sendByte, uint32_t length, uint8_t type, uint8_t do_not_erase) { uint32_t remaining_page_size, remaining_length, remaining_space_to_ring_end; uint32_t i=0; if(!length) return; uint32_t ringStart, ringStop; switch(type) { case EF_HEADER: actualAddress = actualPointerHeader; ringStart = HEADERSTART; ringStop = HEADERSTOP; break; case EF_SAMPLE: actualAddress = actualPointerSample; ringStart = SAMPLESTART; ringStop = SAMPLESTOP; break; case EF_DEVICEDATA: actualAddress = actualPointerDevicedata; ringStart = DDSTART; ringStop = DDSTOP; break; case EF_VPMDATA: actualAddress = actualPointerVPM; ringStart = VPMSTART; ringStop = VPMSTOP; break; case EF_SETTINGS: actualAddress = actualPointerSettings; ringStart = SETTINGSSTART; ringStop = SETTINGSSTOP; break; case EF_FIRMWARE: actualAddress = actualPointerFirmware; ringStart = FWSTART; ringStop = FWSTOP; break; case EF_FIRMWARE2: actualAddress = actualPointerFirmware2; ringStart = FWSTART2; ringStop = FWSTOP2; break; default: ringStart = FLASHSTART; ringStop = FLASHSTOP; break; } /* safety */ if(actualAddress < ringStart) actualAddress = ringStart; if(do_not_erase == 0) { ext_flash_erase_if_on_page_start(); } while( i<length) { ef_hw_rough_delay_us(5); wait_chip_not_busy(); write_spi(0x06,RELEASE); /* WREN */ write_spi(0x02,HOLDCS); /* write cmd */ write_address(HOLDCS); remaining_length = length - i; remaining_page_size = 0xFF - (uint8_t)(actualAddress & 0xFF) +1; remaining_space_to_ring_end = ringStop - actualAddress; if(remaining_length >= 256) { remaining_length = 255; /* up to 256 bytes may be written in one burst. Last byte is written with release */ } else { remaining_length--; /* last byte needed for release */ } if(remaining_length >= (remaining_page_size) ) /* use 256 byte page and calculate number of bytes left */ { remaining_length = remaining_page_size - 1; } if( (remaining_space_to_ring_end >= 256)) { for(int j=0; j<remaining_length; j++) { write_spi(sendByte[i],HOLDCS);/* write data */ actualAddress++; i++; } } /* byte with RELEASE */ write_spi(sendByte[i],RELEASE);/* write data */ actualAddress++; i++; if(actualAddress > ringStop) actualAddress = ringStart; if(do_not_erase == 0) ext_flash_erase_if_on_page_start(); } switch(type) { case EF_HEADER: actualPointerHeader = actualAddress; break; case EF_SAMPLE: actualPointerSample = actualAddress; break; case EF_DEVICEDATA: actualPointerDevicedata = actualAddress; break; case EF_VPMDATA: actualPointerVPM = actualAddress; break; case EF_SETTINGS: actualPointerSettings = actualAddress; break; case EF_FIRMWARE: actualPointerFirmware = actualAddress; break; case EF_FIRMWARE2: actualPointerFirmware2 = actualAddress; break; default: break; } } static _Bool ext_flash_test_remaining_space_of_page_empty(uint32_t pointer, uint16_t length) { if((pointer & 0xFFF) == 0) return 1; uint32_t backup = actualAddress; uint8_t data; uint32_t size_to_page_end; size_to_page_end = 0x1000 - (pointer & 0xFFF); if(length > size_to_page_end) length = size_to_page_end; actualAddress = pointer; ext_flash_read_block_start(); for(uint16_t i = 0; i<length; i++) { ext_flash_read_block(&data, 255); // 255 = ENTIRE FLASH if(data != 0xFF) { ext_flash_read_block_stop(); actualAddress = backup; return 0; } } ext_flash_read_block_stop(); actualAddress = backup; return 1; } static void ext_flash_set_to_begin_of_next_page(uint32_t *pointer, uint8_t type) { uint32_t ringStart, ringStop; switch(type) { case EF_HEADER: ringStart = HEADERSTART; ringStop = HEADERSTOP; break; case EF_SAMPLE: ringStart = SAMPLESTART; ringStop = SAMPLESTOP; break; case EF_DEVICEDATA: ringStart = DDSTART; ringStop = DDSTOP; break; case EF_VPMDATA: ringStart = VPMSTART; ringStop = VPMSTOP; break; case EF_SETTINGS: ringStart = SETTINGSSTART; ringStop = SETTINGSSTOP; break; default: ringStart = FLASHSTART; ringStop = FLASHSTOP; break; } *pointer = (*pointer & 0xFFF) + 0x1000; if((*pointer < ringStart) || (*pointer >= ringStop)) *pointer = ringStart; } static void ef_erase_64K(uint32_t blocks) { for(uint32_t i = 0; i < blocks; i++) { wait_chip_not_busy(); write_spi(0x06,RELEASE);/* WREN */ write_spi(0xD8,HOLDCS);/* 64k erase cmd */ write_address(RELEASE); actualAddress += 0x10000; HAL_Delay(25); } } static void chip_unselect(void) { HAL_GPIO_WritePin(EXTFLASH_CSB_GPIO_PORT,EXTFLASH_CSB_PIN,GPIO_PIN_SET); // chip select } static void chip_select(void) { HAL_GPIO_WritePin(EXTFLASH_CSB_GPIO_PORT,EXTFLASH_CSB_PIN,GPIO_PIN_RESET); // chip select } static void error_led_on(void) { HAL_GPIO_WritePin(OSCILLOSCOPE_GPIO_PORT,OSCILLOSCOPE_PIN,GPIO_PIN_SET); } static void error_led_off(void) { HAL_GPIO_WritePin(OSCILLOSCOPE_GPIO_PORT,OSCILLOSCOPE_PIN,GPIO_PIN_RESET); } static uint8_t read_spi(uint8_t unselect_CS_afterwards) { uint8_t byte; chip_select(); if(HAL_SPI_Receive(&hspiDisplay, &byte, 1, 10000) != HAL_OK) Error_Handler_extflash(); while (HAL_SPI_GetState(&hspiDisplay) != HAL_SPI_STATE_READY) { } if(unselect_CS_afterwards) chip_unselect(); return byte; } static void write_spi(uint8_t data, uint8_t unselect_CS_afterwards) { chip_select(); if(HAL_SPI_Transmit(&hspiDisplay, &data, 1, 10000) != HAL_OK) Error_Handler_extflash(); while (HAL_SPI_GetState(&hspiDisplay) != HAL_SPI_STATE_READY) { } if(unselect_CS_afterwards) chip_unselect(); } static void write_address(uint8_t unselect_CS_afterwards) { uint8_t hi, med ,lo; hi = (actualAddress >> 16) & 0xFF; med = (actualAddress >> 8) & 0xFF; lo = actualAddress & 0xFF; write_spi(hi, HOLDCS); write_spi(med, HOLDCS); write_spi(lo, unselect_CS_afterwards); } static void wait_chip_not_busy(void) { uint8_t status; chip_unselect(); write_spi(0x05,HOLDCS); /* RDSR */ status = read_spi(HOLDCS);/* read status */ while(status & 0x01) { HAL_Delay(1); status = read_spi(HOLDCS);/* read status */ } chip_unselect(); } static void ext_flash_incf_address(uint8_t type) { uint32_t ringStart, ringStop; actualAddress += 1; switch(type) { case EF_HEADER: ringStart = HEADERSTART; ringStop = HEADERSTOP; break; case EF_SAMPLE: ringStart = SAMPLESTART; ringStop = SAMPLESTOP; break; case EF_DEVICEDATA: ringStart = DDSTART; ringStop = DDSTOP; break; case EF_VPMDATA: ringStart = VPMSTART; ringStop = VPMSTOP; break; case EF_SETTINGS: ringStart = SETTINGSSTART; ringStop = SETTINGSSTOP; break; case EF_FIRMWARE: ringStart = FWSTART; ringStop = FWSTOP; break; case EF_FIRMWARE2: ringStart = FWSTART2; ringStop = FWSTOP2; break; default: ringStart = FLASHSTART; ringStop = FLASHSTOP; break; } if((actualAddress < ringStart) || (actualAddress > ringStop)) actualAddress = ringStart; } static void ext_flash_decf_address_ring(uint8_t type) { uint32_t ringStart, ringStop; switch(type) { case EF_HEADER: ringStart = HEADERSTART; ringStop = HEADERSTOP; break; case EF_SAMPLE: ringStart = SAMPLESTART; ringStop = SAMPLESTOP; break; case EF_DEVICEDATA: ringStart = DDSTART; ringStop = DDSTOP; break; case EF_VPMDATA: ringStart = VPMSTART; ringStop = VPMSTOP; break; case EF_SETTINGS: ringStart = SETTINGSSTART; ringStop = SETTINGSSTOP; break; case EF_FIRMWARE: ringStart = FWSTART; ringStop = FWSTOP; break; case EF_FIRMWARE2: ringStart = FWSTART2; ringStop = FWSTOP2; break; default: ringStart = FLASHSTART; ringStop = FLASHSTOP; break; } if((actualAddress <= ringStart) || (actualAddress > ringStop)) actualAddress = ringStop; else actualAddress -= 1; } static void ef_hw_rough_delay_us(uint32_t delayUs) { if(!delayUs) return; delayUs*= 12; while(delayUs--); return; } static void Error_Handler_extflash(void) { while(1) { } } void ext_flash_CloseSector(void) { uint32_t actualAddressBackup = actualAddress; int i=0; if(closeSectorAddress != 0) { /* write some dummy bytes to the sector which is currently used for storing samples. This is done to "hide" problem if function is calles again */ actualAddress = closeSectorAddress; wait_chip_not_busy(); write_spi(0x06,RELEASE); /* WREN */ write_spi(0x02,HOLDCS); /* write cmd */ write_address(HOLDCS); for(i = 0; i<8; i++) { write_spi(0xA5,HOLDCS);/* write data */ actualAddress++; } /* byte with RELEASE */ write_spi(0xA5,RELEASE);/* write data */ actualAddress = actualAddressBackup; closeSectorAddress = 0; } } /* This function validates a potential jump of sample address by checking the last sector for empty memory cells */ uint8_t ext_flash_SampleOverrunValid(void) { uint8_t jumpvalid = 1; uint32_t curAddress, actualaddrbackup; uint8_t tmpBuffer; uint8_t emptyCellCnt = 0; actualaddrbackup = actualAddress; curAddress = SAMPLESTOP - 20; /* check the last 20 bytes of the last sample sector */ actualAddress = curAddress; ext_flash_read_block_start(); while(actualAddress < SAMPLESTOP) { tmpBuffer = read_spi(HOLDCS);/* read data */ if(tmpBuffer == 0xFF) { emptyCellCnt++; } actualAddress++; } ext_flash_read_block_stop(); if(emptyCellCnt == 20) { jumpvalid = 0; } actualAddress = actualaddrbackup; return jumpvalid; } uint32_t ext_flash_AnalyseSampleBuffer() { uint8_t sectorState[192]; /* samples are stored in 192 sector / 64k each */ uint32_t curAddress = SAMPLESTART; uint8_t curSector = 0; uint8_t samplebuffer[10]; uint32_t actualAddressBackup = actualAddress; uint8_t emptyCellCnt = 0; uint32_t i = 0; uint8_t startedSectors = 0; uint8_t lastSectorInuse = 0; /* check if a sector is used till its end */ for(curSector = 0; curSector < 192; curSector++) { sectorState[curSector] = 0; emptyCellCnt = 0; curAddress = SAMPLESTART + (curSector * 0x10000); /* set address to begin of sector and check if it is used */ actualAddress = curAddress; ext_flash_read_block_start(); for(uint32_t i=0;i<10;i++) { samplebuffer[i] = read_spi(HOLDCS);/* read data */ if(samplebuffer[i] == 0xFF) { emptyCellCnt++; } } ext_flash_read_block_stop(); if(emptyCellCnt == 10) { sectorState[curSector] = SECTOR_NOTUSED; } emptyCellCnt = 0; curAddress = SAMPLESTART + (curSector * 0x10000) + 0xFFF5; /* set address to end of sector and check if it is used */ actualAddress = curAddress; ext_flash_read_block_start(); for(i=0;i<10;i++) { samplebuffer[i] = read_spi(HOLDCS);/* read data */ if(samplebuffer[i] == 0xFF) { emptyCellCnt++; } } ext_flash_read_block_stop(); if(emptyCellCnt == 10) { sectorState[curSector] |= SECTOR_INUSE; /* will become SECTOR_EMPTY if start is NOTUSED */ } } for(i=0;i<192;i++) { if( sectorState[i] == SECTOR_INUSE) { startedSectors++; lastSectorInuse = i; } } if(startedSectors > 1) /* more than one sector is in used => ring buffer corrupted */ { if(startedSectors == 2) /* only fix issue if only two sectors are in used. Otherwise fixing will cause more worries than help */ { /* the logic behind healing of the problem is that the larger address is the oldest one => restore the largest address */ curAddress = SAMPLESTART + (lastSectorInuse * 0x10000); emptyCellCnt = 0; actualAddress = curAddress; ext_flash_read_block_start(); while((emptyCellCnt < 10) && (actualAddress < curAddress + 0x10000)) { samplebuffer[0] = read_spi(HOLDCS);/* read data */ if(samplebuffer[0] == 0xFF) { emptyCellCnt++; } else { emptyCellCnt = 0; } actualAddress++; } ext_flash_read_block_stop(); actualAddress -= 10; /* step 10 bytes back to the start of free bytes */ actualPointerSample = actualAddress; closeSectorAddress = settingsGetPointer()->logFlashNextSampleStartAddress & 0xFFFF0000; closeSectorAddress += 0xFFF5; /* to be used once next time a dive is logged. Needed because NextSampleID is derived at every startup */ settingsGetPointer()->logFlashNextSampleStartAddress = actualPointerSample; /* store new position to be used for next dive */ ext_flash_CloseSector(); } } actualAddress = actualAddressBackup; return startedSectors; } uint32_t ext_flash_read_profilelength_small_header(uint32_t smallHeaderAddr) { uint32_t profileLength = 0; actualPointerSample = smallHeaderAddr; actualAddress = actualPointerSample; ext_flash_read_block_start(); ext_flash_read_next_sample_part((uint8_t*)&profileLength, 3); ext_flash_close_read_sample(); return profileLength; } /* uint8_t ext_flash_erase_firmware_if_not_empty(void) { const uint8_t TESTSIZE_FW = 4; uint8_t data[TESTSIZE_FW]; uint8_t notEmpty = 0; actualAddress = FWSTART; ext_flash_read_block_start(); for(int i = 0; i < TESTSIZE_FW; i++) { ext_flash_read_block(&data[i], EF_FIRMWARE); if(data[i] != 0xFF) notEmpty = 1; } ext_flash_read_block_stop(); if(notEmpty) { ext_flash_erase_firmware(); return 1; } else return 0; } uint8_t ext_flash_erase_firmware2_if_not_empty(void) { const uint8_t TESTSIZE_FW = 4; uint8_t data[TESTSIZE_FW]; uint8_t notEmpty = 0; actualAddress = FWSTART2; ext_flash_read_block_start(); for(int i = 0; i < TESTSIZE_FW; i++) { ext_flash_read_block(&data[i], EF_FIRMWARE2); if(data[i] != 0xFF) notEmpty = 1; } ext_flash_read_block_stop(); if(notEmpty) { ext_flash_erase_firmware2(); return 1; } else return 0; }*/