621 lines
21 KiB
C
621 lines
21 KiB
C
/* -*- mode: c; tab-width: 4; indent-tabs-mode: t; c-basic-offset: 4; coding: utf-8 -*- */
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/************************************************************************************
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** **
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** mcHF QRP Transceiver **
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** K Atanassov - M0NKA 2014 **
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** **
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**---------------------------------------------------------------------------------**
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** **
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** File name: **
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** Description: **
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** Last Modified: **
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** Licence: GNU GPLv3 **
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************************************************************************************/
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// Common
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#include "uhsdr_board.h"
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#include "uhsdr_hw_i2c.h"
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#include "serial_eeprom.h"
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// for MAX_VAR_ADDR only
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#include "ui_configuration.h"
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typedef struct SerialEEPROM_Configuration
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{
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uint8_t device_type;
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uint8_t use_type;
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bool detection;
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} SerialEEPROM_Configuration_t;
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// static SerialEEPROM_Configuration_t ser_eeprom_config;
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const SerialEEPROM_EEPROMTypeDescriptor SerialEEPROM_eepromTypeDescs[SERIAL_EEPROM_DESC_NUM] = {
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// 0
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{
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.size = 0,
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.supported = false,
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.pagesize = 0,
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.name = "No EEPROM"
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},
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// 1
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{
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.size = 0,
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.supported = false,
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.pagesize = 0,
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.name = "Wrong Signature"
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},
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// 2
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{
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.size = 0,
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.supported = false,
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.pagesize = 0,
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.name = "Unknown Type"
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},
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// 3
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{
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.size = 0,
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.supported = false,
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.pagesize = 0,
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.name = "Not used"
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},
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// 4
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{
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.size = 0,
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.supported = false,
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.pagesize = 64,
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.name = "Not used"
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},
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// 5
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{
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.size = 0,
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.supported = false,
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.pagesize = 0,
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.name = "Not used"
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},
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// 6
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{
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.size = 0,
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.supported = false,
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.pagesize = 0,
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.name = "Not used"
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},
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// 7
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{
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.size = 128,
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.supported = false,
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.pagesize = 8,
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.name = "24xx01"
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},
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// 8
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{
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.size = 256,
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.supported = false,
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.pagesize = 8,
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.name = "24xx02"
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},
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// 9
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{
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.size = 2*256,
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.supported = false,
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.pagesize = 16,
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.name = "24xx04"
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},
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// 10
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{
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.size = 1*1024,
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.supported = false,
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.pagesize = 16,
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.name = "24xx08"
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},
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// 11
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{
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.size = 2*1024,
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.supported = false,
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.pagesize = 16,
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.name = "24xx16"
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},
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// 12
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{
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.size = 4*1024,
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.supported = false,
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.pagesize = 32,
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.name = "24xx32"
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},
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// 13
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{
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.size = 8*1024,
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.supported = false,
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.pagesize = 32,
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.name = "24xx64"
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},
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// 14
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{
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.size = 16*1024,
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.supported = false,
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.pagesize = 64,
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.name = "24xx128"
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},
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// 15
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{
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.size = 32*1024,
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.supported = true,
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.pagesize = 64,
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.name = "24xx256"
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},
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// 16
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{
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.size = 64*1024,
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.supported = true,
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.pagesize = 128,
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.name = "24xx512"
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},
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// 17
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{
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.size = 128*1024,
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.supported = true,
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.pagesize = 128,
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.name = "24xx1025"
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},
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// 18
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{
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.size = 128 * 1024,
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.supported = true,
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.pagesize = 128,
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.name = "24xx1026/CM01"
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},
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// 19
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{
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.size = 256*1024,
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.supported = true,
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.pagesize = 256,
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.name = "24CM02"
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}
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};
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typedef struct
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{
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uint8_t devaddr;
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uint16_t addr;
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uint16_t addr_size;
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} SerialEEPROM_24CXX_Descriptor;
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static SerialEEPROM_24CXX_Descriptor serialEeprom_desc;
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// THIS CAN BE USED ONLY WITH SINGLE EEPROM AND SINGLE THREAD
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// NOT THREAD SAFE, USE local variable instead then
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#define MEM_DEVICE_WRITE_ADDR 0xA0
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// serial eeprom functions by DF8OE
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static uint16_t SerialEEPROM_24Cxx_DeviceConnected(void)
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{
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uint16_t retVal = UhsdrHw_I2C_DeviceReady(&hi2c2,MEM_DEVICE_WRITE_ADDR);
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return retVal;
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}
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static void SerialEEPROM_24Cxx_AdjustAddrs(const uint8_t Mem_Type, uint8_t* devaddr_ptr, uint32_t* Addr_ptr)
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{
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*devaddr_ptr = MEM_DEVICE_WRITE_ADDR;
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if (*Addr_ptr > 0xFFFF) {
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switch (Mem_Type)
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{
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case 17: // 24LC1025
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*devaddr_ptr = MEM_DEVICE_WRITE_ADDR + 8; // 24LC1025
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break;
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case 18:
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*devaddr_ptr = MEM_DEVICE_WRITE_ADDR + 2; // 24LC1026
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break;
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case 19: // 24CM02
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*devaddr_ptr = MEM_DEVICE_WRITE_ADDR + ((*Addr_ptr & 0x30000) >> 15); // the upper bits 16 and 17 determine the I2C address offset
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break;
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}
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*Addr_ptr &= 0xFFFF; // mask address to 16bits in all cases
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}
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}
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static uint16_t SerialEEPROM_24Cxx_ackPolling(uint32_t Addr, uint8_t Mem_Type)
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{
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uint8_t devaddr;
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SerialEEPROM_24Cxx_AdjustAddrs(Mem_Type,&devaddr,&Addr);
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uint16_t retVal = UhsdrHw_I2C_DeviceReady(&hi2c2,devaddr); // != HAL_OK?0xFD00:0;
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return retVal;
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}
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static void SerialEEPROM_24Cxx_StartTransfer_Prep(uint32_t Addr, uint8_t Mem_Type, SerialEEPROM_24CXX_Descriptor* eeprom_desc_ptr)
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{
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SerialEEPROM_24Cxx_AdjustAddrs(Mem_Type,&eeprom_desc_ptr->devaddr,&Addr);
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eeprom_desc_ptr->addr = (uint16_t)((0xFFFF)&(Addr));
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if (Mem_Type > 8)
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{
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eeprom_desc_ptr->addr_size = I2C_MEMADD_SIZE_16BIT;
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}
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else
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{
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eeprom_desc_ptr->addr_size = I2C_MEMADD_SIZE_8BIT;
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}
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}
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uint16_t SerialEEPROM_24Cxx_Write(uint32_t Addr, uint8_t Data, uint8_t Mem_Type)
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{
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SerialEEPROM_24Cxx_StartTransfer_Prep(Addr, Mem_Type,&serialEeprom_desc);
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uint16_t retVal = UhsdrHw_I2C_WriteRegister(SERIALEEPROM_I2C,serialEeprom_desc.devaddr,serialEeprom_desc.addr,serialEeprom_desc.addr_size,Data);
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if (!retVal)
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{
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retVal = SerialEEPROM_24Cxx_ackPolling(Addr,Mem_Type);
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}
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return retVal;
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}
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uint16_t SerialEEPROM_24Cxx_Read(uint32_t Addr, uint8_t Mem_Type)
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{
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uint8_t value;
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SerialEEPROM_24Cxx_StartTransfer_Prep(Addr, Mem_Type,&serialEeprom_desc);
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uint16_t retVal = UhsdrHw_I2C_ReadRegister(SERIALEEPROM_I2C,serialEeprom_desc.devaddr,serialEeprom_desc.addr,serialEeprom_desc.addr_size,&value);
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if (!retVal)
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{
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retVal = value;
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}
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return retVal;
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}
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uint16_t SerialEEPROM_24Cxx_ReadBulk(uint32_t Addr, uint8_t *buffer, uint16_t length, uint8_t Mem_Type)
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{
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uint16_t retVal = 0xFFFF;
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if (Mem_Type < SERIAL_EEPROM_DESC_NUM) {
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uint32_t page, count;
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count = 0;
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page =SerialEEPROM_eepromTypeDescs[Mem_Type].pagesize;
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while(count < length)
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{
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if (length - count < page)
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{
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// make sure we do not read more than asked for! Buffer Overflow!
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page = (length - count);
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}
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SerialEEPROM_24Cxx_StartTransfer_Prep(Addr + count, Mem_Type,&serialEeprom_desc);
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retVal = UhsdrHw_I2C_ReadBlock(SERIALEEPROM_I2C,serialEeprom_desc.devaddr,serialEeprom_desc.addr,serialEeprom_desc.addr_size,&buffer[count],page);
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count+=page;
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if (retVal)
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{
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break;
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}
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}
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}
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return retVal;
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}
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/**
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* Write a consecutive area of memory into the I2C eeprom starting with Addr.
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* @param Addr the location of the first byte in the eeprom. May have any value within the memory size of the eeprom
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* @param buffer memory to copy from
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* @param length how many bytes to copy
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* @param Mem_Type which eeprom type are we having
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* @return 0 if success, I2C error code otherwise
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*/
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uint16_t SerialEEPROM_24Cxx_WriteBulk(uint32_t Addr, const uint8_t *buffer, uint16_t length, uint8_t Mem_Type)
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{
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uint16_t retVal = 0;
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if (Mem_Type < SERIAL_EEPROM_DESC_NUM) {
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uint32_t count = 0;
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const uint32_t page = SerialEEPROM_eepromTypeDescs[Mem_Type].pagesize;
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while(retVal == 0 && count < length)
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{
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SerialEEPROM_24Cxx_StartTransfer_Prep(Addr + count, Mem_Type,&serialEeprom_desc);
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uint32_t transfer_size = page;
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// correct the transfer_size to keep inside a single page
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// if the start address is not on a page boundary
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// this will happen only for the first bulkd write (if at all)
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// then the Addr + count will be aligned on page boundaries
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transfer_size -= ((Addr+count) % page);
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if (length - count < transfer_size)
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{
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transfer_size = length - count;
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}
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retVal = UhsdrHw_I2C_WriteBlock(SERIALEEPROM_I2C,serialEeprom_desc.devaddr,serialEeprom_desc.addr,serialEeprom_desc.addr_size,&buffer[count],transfer_size);
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count+=transfer_size;
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if (retVal)
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{
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break;
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}
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retVal = SerialEEPROM_24Cxx_ackPolling(Addr,Mem_Type);
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}
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}
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return retVal;
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}
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/**
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* @brief in general a non-destructive probing to identify the used EEPROM, in some cases devices are written (and changed data restored)
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* this code uses hardware properties to identify the connected I2C eeprom, no previously signature etc. used or required
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* @returns identified eeprom chip type or EEPROM_SER_UNKNOWN
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*/
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static uint8_t SerialEEPROM_24Cxx_DetectProbeHardware(void)
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{
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uint8_t ser_eeprom_type = EEPROM_SER_UNKNOWN;
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const uint8_t testsignatureA = 0x66;
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const uint8_t testsignatureB = 0x77; // has to be different from testsignature 1
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const uint16_t testaddr1 = 0x0001;
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const uint16_t testaddr1plus128 = testaddr1 + 0x80;
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// 8 Bit Test First
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uint16_t test8Byte1 = SerialEEPROM_24Cxx_Read(testaddr1,8);
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// first decide if 8 or 16 bit addressable eeprom by trying to read with 8 or 16 bit algorithm
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// if an algorithm succeeds we know the address width
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if(test8Byte1 < 0x100)
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{
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// 8 bit addressing
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uint16_t test8Byte2 = SerialEEPROM_24Cxx_Read(testaddr1plus128,8);
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SerialEEPROM_24Cxx_Write(testaddr1,testsignatureB,8);
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SerialEEPROM_24Cxx_Write(testaddr1plus128,testsignatureB,8);
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if (SerialEEPROM_24Cxx_Read(testaddr1,8) == testsignatureB)
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{
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SerialEEPROM_24Cxx_Write(testaddr1,testsignatureA,8); // write test signature
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ser_eeprom_type = 7; // smallest possible 8 bit EEPROM (128Bytes)
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if(SerialEEPROM_24Cxx_Read(testaddr1plus128,8) == testsignatureB)
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{
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ser_eeprom_type = 8;
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}
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}
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SerialEEPROM_24Cxx_Write(testaddr1,test8Byte1,8); // write back old data
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SerialEEPROM_24Cxx_Write(testaddr1plus128,test8Byte2,8);
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}
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if (ser_eeprom_type == EEPROM_SER_UNKNOWN)
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{
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// 16 bit addressing check
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// the other banks are mapped to different I2C
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// device addresses. We simply try to read from them
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// and if it succeeds we know the device type
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// We need to check unique addresses for each EEPROM type
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// 0xA0 + 0x10000: 0xA8
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if(SerialEEPROM_24Cxx_Read(0x10000,17) < 0x100)
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{
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ser_eeprom_type = 17; // 24LC1025
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}
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// 0xA0 + 0x10000: 0xA2
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if(SerialEEPROM_24Cxx_Read(0x10000,18) < 0x100)
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{
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ser_eeprom_type = 18; // 24LC1026
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}
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// 0xA0 + 0x10000: 0xA2 + 0x20000: 0xA4 + 0x30000: 0xA6
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if(SerialEEPROM_24Cxx_Read(0x20000,19) < 0x100)
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{
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ser_eeprom_type = 19; // 24CM02
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}
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// it is not a large EEPROM (i.e. >64KB Data)
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//
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// the following test requires writing to EEPROM,
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// we remember content of test locations
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// and write them back later
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if(ser_eeprom_type == EEPROM_SER_UNKNOWN)
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{
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const uint16_t testaddr1plus256 = 0x0100 + testaddr1; // same as before but 0x100 == 256 byte spacing
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uint16_t testByte1 = SerialEEPROM_24Cxx_Read(testaddr1,16); // read old content
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uint16_t testByte2 = SerialEEPROM_24Cxx_Read(testaddr1plus256,16); // of test bytes
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if (testByte1 < 0x100 && testByte2 < 0x100) {
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// successful read from both locations, let us start
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SerialEEPROM_24Cxx_Write(testaddr1, testsignatureA,16); // write testsignature 1
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SerialEEPROM_24Cxx_Write(testaddr1plus256, testsignatureB,16); // write testsignature 2
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if(SerialEEPROM_24Cxx_Read(testaddr1,16) == testsignatureA && SerialEEPROM_24Cxx_Read(testaddr1plus256,16) == testsignatureB)
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{
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// 16 bit addressing
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ser_eeprom_type = 9; // smallest possible 16 bit EEPROM
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// we look for the "looping" in data, i.e. we read back 0x66
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// which we wrote to address 0x0003
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// from a address we did not wrote it to
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// once it occurs, we know the size of the EEPROM
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// since all of these EEPROMS are ignoring the unused bits in the address
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for (int shift = 0; shift < 8; shift++) {
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uint16_t shift_test_addr = (0x200 << shift)+testaddr1;
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if(SerialEEPROM_24Cxx_Read(shift_test_addr,16) == testsignatureA) {
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// now we write test signature 2 to make sure the match was no accident
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// i.e. match with same content in EEPROM
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SerialEEPROM_24Cxx_Write(shift_test_addr,testsignatureB,16);
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if(SerialEEPROM_24Cxx_Read(testaddr1,16) == testsignatureB) {
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// we found the looping,
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// now stop checking and set EEPROM type
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ser_eeprom_type = 9 + shift;
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break;
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}
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else
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{
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// oops: just an accident, so we write back old content and continue
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SerialEEPROM_24Cxx_Write(shift_test_addr,testsignatureA,16);
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}
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}
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}
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}
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SerialEEPROM_24Cxx_Write(testaddr1,testByte1,16); // write back old data
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SerialEEPROM_24Cxx_Write(testaddr1plus256,testByte2,16);
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}
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}
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}
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return ser_eeprom_type;
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}
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static void SerialEEPROM_Read_Signature(uint8_t ser_eeprom_type, uint16_t* type_p, uint16_t* state_p)
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{
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*type_p = SerialEEPROM_24Cxx_Read(0,ser_eeprom_type);
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*state_p = SerialEEPROM_24Cxx_Read(1,ser_eeprom_type);
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}
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uint16_t SerialEEPROM_Set_UseStateInSignature(uint8_t state)
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{
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return SerialEEPROM_24Cxx_Write(1,SER_EEPROM_IN_USE,ts.ser_eeprom_type);
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}
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uint16_t SerialEEPROM_Get_UseStateInSignature()
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{
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return SerialEEPROM_24Cxx_Read(1,ts.ser_eeprom_type);
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}
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uint8_t SerialEEPROM_Detect() {
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uint16_t ser_eeprom_type = EEPROM_SER_UNKNOWN;
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// serial EEPROM init
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if(SerialEEPROM_24Cxx_DeviceConnected() != HAL_OK || SerialEEPROM_24xx_Exists() == false) // Issue with Ser EEPROM, either not available or other problems
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{
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ser_eeprom_type = EEPROM_SER_NONE; // no serial EEPROM available
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}
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else
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{
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// this initial read will bring us the first byte of any eeprom (8 or 16bits)
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// if we read anything but the 0xff == SER_EERPM_NOT_IN_USE value which indicates empty eeprom
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// we assume some configuration information tells us what EEPROM we have and how it is used
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if(SerialEEPROM_24Cxx_Read(0,16) != SER_EEPROM_NOT_IN_USE)
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{
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ser_eeprom_type = EEPROM_SER_WRONG_SIG;
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// unless we find a correct signature, we have to assume the EEPROM has incorrect/corrupted data
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uint16_t ser_eeprom_type_read;
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uint16_t ser_eeprom_sig;
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SerialEEPROM_Read_Signature(8, &ser_eeprom_type_read, &ser_eeprom_sig);
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// all 8 bit (i.e. 256 or 128 Byte) EEPROMS are marked as "too small" during detection
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if(ser_eeprom_sig == SER_EEPROM_TOO_SMALL && ser_eeprom_type_read >= SERIAL_EEPROM_DESC_REAL && ser_eeprom_type_read < 9)
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{
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ser_eeprom_type = ser_eeprom_type_read;
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}
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else
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{
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SerialEEPROM_Read_Signature(16, &ser_eeprom_type_read, &ser_eeprom_sig);
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// we either have a new EEPROM, just being initialized ( ser_eeprom_sig = SER_EEPROM_NOT_IN_USE && valid type) or
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// we have an used EEPROM (ser_eeprom_sig = SER_EEPROM_IN_USE && valid type)
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// please note, that even though no 16 bit EEPROM gets the "too small" signature written in, these may still be
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// consider too small by the later code. Only EEPROMS which have the "supported" flag set in the descriptor will
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// be consider of sufficient size for actual use
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if((ser_eeprom_sig == SER_EEPROM_IN_USE || ser_eeprom_sig == SER_EEPROM_NOT_IN_USE) && ser_eeprom_type_read < SERIAL_EEPROM_DESC_NUM && ser_eeprom_type_read > 8)
|
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{
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ser_eeprom_type = ser_eeprom_type_read;
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|
}
|
|
}
|
|
}
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else
|
|
{
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ser_eeprom_type = SerialEEPROM_24Cxx_DetectProbeHardware();
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|
|
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if (ser_eeprom_type >= SERIAL_EEPROM_DESC_REAL && ser_eeprom_type < SERIAL_EEPROM_DESC_NUM)
|
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{
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SerialEEPROM_24Cxx_Write(0,ser_eeprom_type,ser_eeprom_type);
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if (SerialEEPROM_eepromTypeDescs[ser_eeprom_type].supported == false)
|
|
{
|
|
SerialEEPROM_24Cxx_Write(1,SER_EEPROM_TOO_SMALL,ser_eeprom_type);
|
|
}
|
|
}
|
|
}
|
|
// just to be save. Never ever deliver a type id outside the array boundaries.
|
|
if (ser_eeprom_type >= SERIAL_EEPROM_DESC_NUM)
|
|
{
|
|
ser_eeprom_type = EEPROM_SER_UNKNOWN;
|
|
}
|
|
}
|
|
|
|
return ser_eeprom_type;
|
|
|
|
}
|
|
|
|
static void SerialEEPROM_Clear_Variable(uint16_t addr)
|
|
{
|
|
const uint8_t empty_var[2] = { 0xff, 0xff };
|
|
SerialEEPROM_24Cxx_WriteBulk(addr*2, empty_var,2, ts.ser_eeprom_type);
|
|
}
|
|
|
|
void SerialEEPROM_Clear_AllVariables()
|
|
{
|
|
// variable 0 is the reserved signature variable
|
|
for(uint16_t count=1; count <= MAX_VAR_ADDR; count++)
|
|
{
|
|
SerialEEPROM_Clear_Variable(count);
|
|
}
|
|
}
|
|
|
|
void SerialEEPROM_Clear_Signature()
|
|
{
|
|
// variable 0 is the reserved signature variable
|
|
ts.ser_eeprom_type = SerialEEPROM_24Cxx_DetectProbeHardware();
|
|
SerialEEPROM_Clear_Variable(0);
|
|
}
|
|
|
|
|
|
bool SerialEEPROM_24xx_Exists()
|
|
{
|
|
return SerialEEPROM_24Cxx_Read(0,8) < 0x100;
|
|
}
|
|
|
|
|
|
//
|
|
// Interface for serial EEPROM functions
|
|
//
|
|
uint16_t SerialEEPROM_ReadVariable(uint16_t addr, uint16_t *value) // reference to serial EEPROM read function
|
|
{
|
|
uint8_t bytes[2];
|
|
|
|
|
|
uint16_t retval = SerialEEPROM_24Cxx_ReadBulk(addr*2,bytes, 2, ts.ser_eeprom_type);
|
|
|
|
if (retval == HAL_OK)
|
|
{
|
|
*value = ((uint16_t)bytes[0])<<8;
|
|
*value |= bytes[1];
|
|
}
|
|
|
|
return retval;
|
|
}
|
|
|
|
uint16_t SerialEEPROM_UpdateVariable(uint16_t addr, uint16_t value)
|
|
{
|
|
uint16_t value_read = 0;
|
|
uint16_t retval = SerialEEPROM_ReadVariable(addr,&value_read);
|
|
if (retval != 0 || value_read != value )
|
|
{
|
|
retval = SerialEEPROM_WriteVariable(addr,value);
|
|
}
|
|
return retval;
|
|
}
|
|
|
|
uint16_t SerialEEPROM_WriteVariable(uint16_t addr, uint16_t value) // reference to serial EEPROM write function, writing unsigned 16 bit
|
|
{
|
|
uint8_t bytes[2];
|
|
|
|
bytes[0] = (uint8_t)((value&(0xFF00))>>8);
|
|
bytes[1] = (uint8_t)(value&(0x00FF));
|
|
|
|
return SerialEEPROM_24Cxx_WriteBulk(addr*2, bytes, 2, ts.ser_eeprom_type);
|
|
}
|