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Fork of eeprom_1 by
eeprom.cpp
- Committer:
- bborredon
- Date:
- 2015-11-02
- Revision:
- 2:79ed7ff7c23d
- Parent:
- 1:a262173cac81
- Child:
- 3:925096a4c7f0
File content as of revision 2:79ed7ff7c23d:
/*********************************************************** Author: Bernard Borredon Date : 12 decembre 2013 Version: 1.2 - Update api documentation Date: 11 december 2013 Version: 1.1 - Change address parameter size form uint16_t to uint32_t (error for eeprom > 24C256). - Change size parameter size from uint16_t to uint32_t (error for eeprom > 24C256). - Correct a bug in function write(uint32_t address, int8_t data[], uint32_t length) : last step must be done only if it remain datas to send. - Add function getName. - Add function clear. - Initialize _name array. Date: 27 december 2011 Version: 1.0 ************************************************************/ #include "eeprom.h" #define BIT_SET(x,n) (x=x | (0x01<<n)) #define BIT_TEST(x,n) (x & (0x01<<n)) #define BIT_CLEAR(x,n) (x=x & ~(0x01<<n)) const char * const EEPROM::_name[] = {"24C01","24C02","24C04","24C08","24C16","24C32", "24C64","24C128","24C256","24C512","24C1024","24C1025"}; EEPROM::EEPROM(PinName sda, PinName scl, uint8_t address, TypeEeprom type) : _i2c(sda, scl) { _errnum = EEPROM_NoError; _type = type; // Check address range _address = address; switch(type) { case T24C01 : case T24C02 : if(address > 7) { _errnum = EEPROM_BadAddress; } _address = _address << 1; _page_write = 8; _page_number = 1; break; case T24C04 : if(address > 7) { _errnum = EEPROM_BadAddress; } _address = (_address & 0xFE) << 1; _page_write = 16; _page_number = 2; break; case T24C08 : if(address > 7) { _errnum = EEPROM_BadAddress; } _address = (_address & 0xFC) << 1; _page_write = 16; _page_number = 4; break; case T24C16 : _address = 0; _page_write = 16; _page_number = 8; break; case T24C32 : case T24C64 : if(address > 7) { _errnum = EEPROM_BadAddress; } _address = _address << 1; _page_write = 32; _page_number = 1; break; case T24C128 : case T24C256 : if(address > 3) { _errnum = EEPROM_BadAddress; } _address = _address << 1; _page_write = 64; _page_number = 1; break; case T24C512 : if(address > 3) { _errnum = EEPROM_BadAddress; } _address = _address << 1; _page_write = 128; _page_number = 1; break; case T24C1024 : if(address > 7) { _errnum = EEPROM_BadAddress; } _address = (_address & 0xFE) << 1; _page_write = 128; _page_number = 2; break; case T24C1025 : if(address > 3) { _errnum = EEPROM_BadAddress; } _address = _address << 1; _page_write = 128; _page_number = 2; break; } // Size in bytes _size = _type; if(_type == T24C1025) _size = T24C1024; // Set I2C frequency _i2c.frequency(400000); } void EEPROM::write(uint32_t address, int8_t data) { uint8_t page; uint8_t addr; uint8_t cmd[3]; int len; int ack; // Check error if(_errnum) return; // Check address if(!checkAddress(address)) { _errnum = EEPROM_OutOfRange; return; } // Compute page number page = 0; if(_type < T24C32) page = (uint8_t) (address / 256); // Device address addr = EEPROM_Address | _address | (page << 1); if(_type < T24C32) { len = 2; // Word address cmd[0] = (uint8_t) (address - page * 256); // Data cmd[1] = (uint8_t) data; } else { len = 3; // First word address (MSB) cmd[0] = (uint8_t) (address >> 8); // Second word address (LSB) cmd[1] = (uint8_t) address; // Data cmd[2] = (uint8_t) data; } ack = _i2c.write((int)addr,(char *)cmd,len); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); } void EEPROM::write(uint32_t address, int8_t data[], uint32_t length) { uint8_t page; uint8_t addr = 0; uint8_t blocs,remain; uint8_t fpart,lpart; uint8_t i,j,ind; uint8_t cmd[129]; int ack; // Check error if(_errnum) return; // Check address if(!checkAddress(address)) { _errnum = EEPROM_OutOfRange; return; } // Check length if(!checkAddress(address + length - 1)) { _errnum = EEPROM_OutOfRange; return; } // Compute blocs numbers blocs = length / _page_write; // Compute remaining bytes remain = length - blocs * _page_write; for(i = 0;i < blocs;i++) { // Compute page number page = 0; if(_type < T24C32) page = (uint8_t) (address / 256); // Device address addr = EEPROM_Address | _address | (page << 1); if(_type < T24C32) { // Word address cmd[0] = (uint8_t) (address - page * 256); if((uint8_t) ((address + _page_write) / 256) == page) { // Data fit in the same page // Add data for(j = 0;j < _page_write;j++) cmd[j + 1] = (uint8_t) data[i * _page_write + j]; // Write data ack = _i2c.write((int)addr,(char *)cmd,_page_write + 1); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); // Increment address address += _page_write; } else { // Data on 2 pages. We must split the write // Number of bytes in current page fpart = (page + 1) * 256 - address; // Add data for current page for(j = 0;j < fpart;j++) cmd[j + 1] = (uint8_t) data[i * _page_write + j]; // Write data for current page ack = _i2c.write((int)addr,(char *)cmd,fpart + 1); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); // Increment address address += fpart; if(page < _page_number - 1) { // Increment page page++; // Device address addr = EEPROM_Address | _address | (page << 1); // Word address cmd[0] = (uint8_t) (address - page * 256); // Data index ind = i * _page_write + fpart; // Number of bytes in next page lpart = _page_write - fpart; // Add data for next page for(j = 0;j < lpart;j++) cmd[j + 1] = (uint8_t) data[ind + j]; // Write data for next page ack = _i2c.write((int)addr,(char *)cmd,lpart + 1); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); // Increment address address += lpart; } } } else { // First word address (MSB) cmd[0] = (uint8_t) (address >> 8); // Second word address (LSB) cmd[1] = (uint8_t) address; // Add data for(j = 0;j < _page_write;j++) cmd[j + 2] = (uint8_t) data[i * _page_write + j]; // Write data ack = _i2c.write((int)addr,(char *)cmd,_page_write + 2); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); // Increment address address += _page_write; } } if(remain) { // Compute page number page = 0; if(_type < T24C32) page = (uint8_t) (address / 256); // Device address addr = EEPROM_Address | _address | (page << 1); if(_type < T24C32) { // Word address cmd[0] = (uint8_t) (address - page * 256); if((uint8_t) ((address + remain) / 256) == page) { // Data fit in the same page // Add data for the current page for(j = 0;j < remain;j++) cmd[j + 1] = (uint8_t) data[blocs * _page_write + j]; // Write data for the current page ack = _i2c.write((int)addr,(char *)cmd,remain + 1); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); } else { // Data on 2 pages. We must split the write // Number of bytes in current page fpart = (page + 1) * 256 - address; // Add data for current page for(j = 0;j < fpart;j++) cmd[j + 1] = (uint8_t) data[blocs * _page_write + j]; // Write data for current page ack = _i2c.write((int)addr,(char *)cmd,fpart + 1); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); // Increment address address += fpart; if(page < _page_number - 1) { // Increment page page++; // Device address addr = EEPROM_Address | _address | (page << 1); // Word address cmd[0] = (uint8_t) (address - page * 256); // Data index ind = blocs * _page_write + fpart; // Number of bytes in next page lpart = remain - fpart; // Add data for next page for(j = 0;j < lpart;j++) cmd[j + 1] = (uint8_t) data[ind + j]; // Write data for next page ack = _i2c.write((int)addr,(char *)cmd,lpart + 1); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); } } } } else { // Fist word address (MSB) cmd[0] = (uint8_t) (address >> 8); // Second word address (LSB) cmd[1] = (uint8_t) address; // Add data for the current page for(j = 0;j < remain;j++) cmd[j + 2] = (uint8_t) data[blocs * _page_write + j]; // Write data for the current page ack = _i2c.write((int)addr,(char *)cmd,remain + 2); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Wait end of write ready(); } } void EEPROM::write(uint32_t address, int16_t data) { int8_t cmd[2]; // Check error if(_errnum) return; // Check address if(!checkAddress(address + 1)) { _errnum = EEPROM_OutOfRange; return; } memcpy(cmd,&data,2); write(address,cmd,2); } void EEPROM::write(uint32_t address, int32_t data) { int8_t cmd[4]; // Check error if(_errnum) return; // Check address if(!checkAddress(address + 3)) { _errnum = EEPROM_OutOfRange; return; } memcpy(cmd,&data,4); write(address,cmd,4); } void EEPROM::write(uint32_t address, float data) { int8_t cmd[4]; // Check error if(_errnum) return; // Check address if(!checkAddress(address + 3)) { _errnum = EEPROM_OutOfRange; return; } memcpy(cmd,&data,4); write(address,cmd,4); } void EEPROM::write(uint32_t address, void *data, uint32_t size) { int8_t *cmd = NULL; // Check error if(_errnum) return; // Check address if(!checkAddress(address + size - 1)) { _errnum = EEPROM_OutOfRange; return; } cmd = (int8_t *)malloc(size); if(cmd == NULL) { _errnum = EEPROM_MallocError; return; } memcpy(cmd,(uint8_t *)data,size); write(address,cmd,size); free(cmd); } void EEPROM::read(uint32_t address, int8_t& data) { uint8_t page; uint8_t addr; uint8_t cmd[2]; uint8_t len; int ack; // Check error if(_errnum) return; // Check address if(!checkAddress(address)) { _errnum = EEPROM_OutOfRange; return; } // Compute page number page = 0; if(_type < T24C32) page = (uint8_t) (address / 256); // Device address addr = EEPROM_Address | _address | (page << 1); if(_type < T24C32) { len = 1; // Word address cmd[0] = (uint8_t) (address - page * 256); } else { len = 2; // First word address (MSB) cmd[0] = (uint8_t) (address >> 8); // Second word address (LSB) cmd[1] = (uint8_t)address; } // Write command ack = _i2c.write((int)addr,(char *)cmd,len,true); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Read data ack = _i2c.read((int)addr,(char *)&data,sizeof(data)); if(ack != 0) { _errnum = EEPROM_I2cError; return; } } void EEPROM::read(uint32_t address, int8_t *data, uint32_t size) { uint8_t page; uint8_t addr; uint8_t cmd[2]; uint8_t len; int ack; // Check error if(_errnum) return; // Check address if(!checkAddress(address)) { _errnum = EEPROM_OutOfRange; return; } // Check size if(!checkAddress(address + size - 1)) { _errnum = EEPROM_OutOfRange; return; } // Compute page number page = 0; if(_type < T24C32) page = (uint8_t) (address / 256); // Device address addr = EEPROM_Address | _address | (page << 1); if(_type < T24C32) { len = 1; // Word address cmd[0] = (uint8_t) (address - page * 256); } else { len = 2; // First word address (MSB) cmd[0] = (uint8_t) (address >> 8); // Second word address (LSB) cmd[1] = (uint8_t) address; } // Write command ack = _i2c.write((int)addr,(char *)cmd,len,true); if(ack != 0) { _errnum = EEPROM_I2cError; return; } // Sequential read ack = _i2c.read((int)addr,(char *)data,size); if(ack != 0) { _errnum = EEPROM_I2cError; return; } } void EEPROM::read(int8_t& data) { uint8_t addr; int ack; // Check error if(_errnum) return; // Device address addr = EEPROM_Address | _address; // Read data ack = _i2c.read((int)addr,(char *)&data,sizeof(data)); if(ack != 0) { _errnum = EEPROM_I2cError; return; } } void EEPROM::read(uint32_t address, int16_t& data) { int8_t cmd[2]; // Check error if(_errnum) return; // Check address if(!checkAddress(address + 1)) { _errnum = EEPROM_OutOfRange; return; } read(address,cmd,2); memcpy(&data,cmd,2); } void EEPROM::read(uint32_t address, int32_t& data) { int8_t cmd[4]; // Check error if(_errnum) return; // Check address if(!checkAddress(address + 3)) { _errnum = EEPROM_OutOfRange; return; } read(address,cmd,4); memcpy(&data,cmd,4); } void EEPROM::read(uint32_t address, float& data) { int8_t cmd[4]; // Check error if(_errnum) return; // Check address if(!checkAddress(address + 3)) { _errnum = EEPROM_OutOfRange; return; } read(address,cmd,4); memcpy(&data,cmd,4); } void EEPROM::read(uint32_t address, void *data, uint32_t size) { int8_t *cmd = NULL; // Check error if(_errnum) return; // Check address if(!checkAddress(address + size - 1)) { _errnum = EEPROM_OutOfRange; return; } cmd = (int8_t *)malloc(size); if(cmd == NULL) { _errnum = EEPROM_MallocError; return; } read(address,(int8_t *)cmd,size); memcpy(data,cmd,size); free(cmd); } void EEPROM::clear(void) { int32_t data; uint32_t i; data = 0; for(i = 0; i < _size / 4;i++) { write((uint32_t)(i * 4),data); } } void EEPROM::ready(void) { int ack; uint8_t addr; uint8_t cmd[2]; // Check error if(_errnum) return; // Device address addr = EEPROM_Address | _address; cmd[0] = 0; // Wait end of write do { ack = _i2c.write((int)addr,(char *)cmd,0); //wait(0.5); } while(ack != 0); } uint32_t EEPROM::getSize(void) { return(_size); } const char* EEPROM::getName(void) { uint8_t i = 0; switch(_type) { case T24C01 : i = 0; break; case T24C02 : i = 1; break; case T24C04 : i = 2; break; case T24C08 : i = 3; break; case T24C16 : i = 4; break; case T24C32 : i = 5; break; case T24C64 : i = 6; break; case T24C128 : i = 7; break; case T24C256 : i = 8; break; case T24C512 : i = 9; break; case T24C1024 : i = 10; break; case T24C1025 : i = 11; break; } return(_name[i]); } uint8_t EEPROM::getError(void) { return(_errnum); } bool EEPROM::checkAddress(uint32_t address) { bool ret = true; switch(_type) { case T24C01 : if(address >= T24C01) ret = false; break; case T24C02 : if(address >= T24C02) ret = false; break; case T24C04 : if(address >= T24C04) ret = false; break; case T24C08 : if(address >= T24C08) ret = false; break; case T24C16 : if(address >= T24C16) ret = false; break; case T24C32 : if(address >= T24C32) ret = false; break; case T24C64 : if(address >= T24C64) ret = false; break; case T24C128 : if(address >= T24C128) ret = false; break; case T24C256 : if(address >= T24C256) ret = false; break; case T24C512 : if(address >= T24C512) ret = false; break; case T24C1024 : if(address >= T24C1024) ret = false; break; case T24C1025 : if(address >= T24C1025 - 1) ret = false; break; } return(ret); }