Yann Garcia
Simplified access to Ramtron (Cypress) FM24Vxx F-RAM devices
FM24Vxx_I2C.h
- Committer:
- Yann
- Date:
- 2013-04-13
- Revision:
- 2:bf7d1264d3ff
- Parent:
- 1:6a16bddd7222
File content as of revision 2:bf7d1264d3ff:
/* mbed simplified access to RAMTRON FV24xx Serial 3V F-RAM Memory (I2C)
* Copyright (c) 2013 ygarcia, MIT License
*
* Permission is hereby granted, free of charge, to any person obtaining a copy of this software
* and associated documentation files (the "Software"), to deal in the Software without restriction,
* including without limitation the rights to use, copy, modify, merge, publish, distribute,
* sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all copies or
* substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING
* BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
#if !defined(__FM24VXX_I2C_H__)
#define __FM24VXX_I2C_H__
#include <string>
#include <vector>
#include "FM24Vxx_IDs.h"
#include "FM24Vxx_SN.h"
#include "Debug.h" // Include mbed header + debug primitives. See DebugLibrary
namespace _FM24VXX_I2C {
/** This class provides simplified I2C access to a RAMTRON FV24xx Serial 3V F-RAM Memory device. V0.0.0.1
*
* Note that RAMTRON FV24xx Serial 3V F-RAM Memory device could be powered at 3.3V or less only.
* Note that this header file include following headers:
* - <string>
* - <vector>
* - <mbed.h>
*
* @author Yann Garcia (Don't hesitate to contact me: garcia.yann@gmail.com)
*/
class CFM24VXX_I2C {
/** Reference counter used to guarentee unicity of the instance of I2C class
*/
static unsigned char I2CModuleRefCounter;
/** Device address input: A1, A2 (Pins <2,3>). See FM24V10_ds.pdf - Clause Pin Configuration
*/
unsigned char _slaveAddress;
/** WP state indicator (pin 7); true is write protected, false otherwise
*/
DigitalOut *_wp;
/** An unique instance of I2C class
*/
I2C *_i2cInstance;
/** Device ID
*/
CFM24VXX_IDs *_deviceID;
/** Serial number
*/
CFM24VXX_SN *_sn;
public:
/** Memory storage mode
*/
enum Mode {
LittleEndian, //<! Little Endian mode: 0xA0B70708 is stored as 08: MSB and A0 LSB
BigEndian //<! Little Endian mode: 0xA0B70708 is stored as AO: MSB and 08 LSB
};
public:
/** Constructor with Write Protect command pin wired. Use it to manage the first I2C module
*
* @param p_sda: MBed pin for SDA
* @param p_scl: MBed pin for SCL
* @param p_address: Device address input: A1, A2 (Pins <2,3>)
* @param p_wp: MBed pin to manage Write Protect input. If NC, WP is not managed, default value is NC, not connected
* @param p_frequency: Frequency of the I2C interface (SCL), default value is 400KHz
* Example:
* - If A1 pin is tired to Vdd and A2 is tired to Vss, address shall '00000001'B
*/
CFM24VXX_I2C(const PinName p_sda, const PinName p_scl, const unsigned char p_address, const PinName p_wp = NC, const unsigned int p_frequency = 400000);
/** Destructor
*/
virtual ~CFM24VXX_I2C();
/** Used to return the unique instance of I2C instance
*/
inline const I2C * operator * () { return (const I2C *)_i2cInstance; };
/** Used to return the unique device identifier
*/
inline const CFM24VXX_IDs * GetDeviceID() { return (const CFM24VXX_IDs *)_deviceID; };
/**
* Used to return the serial number
* Note This functionality is available only for the FM24VN10. In other case, it will return 0xff
* @remark See FM24V10_ds.pdf Page 10/16 Clause Unique Serial Number (FM24VN10 only)
*/
inline const CFM24VXX_SN * GetSerialNumber() { return (const CFM24VXX_SN *)_sn; };
/**
* Used to swith high speed mode
* @param highSpeedMode Set to true to switch to high speed mode
* @remark See FM24V10_ds.pdf Page 4/16 Clause High Speed Mode (HS-mode)
*/
inline void SwitchSpeedMode(const bool highSpeedMode) { /* FIXME To be done */ };
/**
* Used to enter in sleep mode
* @remark See FM24V10_ds.pdf Page 8/16 Clause Sleep Mode
*/
inline void EnterSleepMode() { /* FIXME To be done */ };
/**
* Used to leave sleep mode
* @remark See FM24V10_ds.pdf Page 8/16 Clause Sleep Mode
*/
inline void LeaveSpeedMode() { /* FIXME To be done */ };
/**
* Used to select memory page
* @param memoryPage The selected memory page (0 or 1)
* @remark See FM24V10_ds.pdf Page 3/16 Clause Memory Architecture
*/
inline void SelectMemoryPage(const unsigned char memoryPage) { _slaveAddress |= ((memoryPage & 0x01) << 1); };
/** Erase of memory area starting at the specified address, using the specified pattern to fill the memory area
*
* @param p_startAddress The address of the memory area (from 0 to N - 1, N is the number of cells of the memory)
* @param p_count The size of the memory area to erase
* @param p_pattern The pattern value to use to fill the memory area. Default vqlue: 0x00
* @return true on success, false otherwise
* Exemple:
* @code
* ...
* myEEPROM.EraseMemoryArea(0, 1024); // Set to 0x00 the first 1Kb memory
* ...
* @endcode
*/
bool EraseMemoryArea(const short p_startAddress, const int p_count, const unsigned char p_pattern = 0x00);
/** Write a byte at the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_byte The byte value to save
* @return true on success, false otherwise
* Exemple:
* @code
* unsigned char value = 0xaa;
* ...
* myEEPROM.Write(memoryAddress, value);
* ...
* @endcode
*/
bool Write(const short p_address, const unsigned char p_byte);
/** Write a short at the specified memory address according to the specified mode
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_short The short value to save
* @param p_mode The storage mode. Default value: BigEndian
* @return true on success, false otherwise
* Exemple:
* @code
* short value = 0xcafe;
* ...
* myEEPROM.Write(memoryAddress, value, LittleEndian);
* ...
* @endcode
*/
bool Write(const short p_address, const short p_short, const CFM24VXX_I2C::Mode p_mode = BigEndian);
/** Write an integer at the specified memory address according to the specified mode
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_int The integer value to save
* @param p_mode The storage mode. Default value: BigEndian
* @return true on success, false otherwise
* Exemple:
* @code
* int value = 0xcafedeca;
* ...
* myEEPROM.Write(memoryAddress, value, LittleEndian);
* ...
* @endcode
*/
bool Write(const short p_address, const int p_int, const CFM24VXX_I2C::Mode p_mode = BigEndian);
/** Write a buffer of bytes at the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_datas The string to save
* @param p_storeLength If true, store also the length of the buffer in Big Endian mode, otherwise the length will be provided by p_length2write parameter. Default value: true.
* @param p_length2write The number of bytes to write, -1 for all characters. Default value: -1
* @return true on success, false otherwise
*/
bool Write(const short p_address, const std::vector<unsigned char> & p_datas, bool p_storeLength = true, const int p_length2write = -1);
/** Write a buffer of bytes at the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_datas The buffer of bytes to save
* @param p_storeLength If true, store also the length of the buffer in Big Endian mode, otherwise the length will be provided by p_length2write parameter. Default value: true.
* @param p_length2write The number of bytes to write, -1 for all bytes. Default value: -1
* @return true on success, false otherwise
*/
bool Write(const short p_address, const unsigned char *p_datas, bool p_storeLength = true, const int p_length2write = -1);
/** Write a string at the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_string The string to save
* @param p_storeLength If true, store also the length of the string in Big Endian mode, otherwise the length will be provided by p_length2write parameter. Default value: true.
* @param p_length2write The number of character to write, -1 for all characters
* @return true on success, false otherwise
* Exemple:
* @code
* std::string text2save("CafeDeca");
* ...
* myEEPROM.Write(memoryAddress, text2save);
* ...
* @endcode
*/
bool Write(const short p_address, const std::string & p_string, const bool p_storeLength = true, const int p_length2write = -1);
/** Write a buffer of characters at the specified memory address (from 0 to N - 1, N is the number of cells of the memory).
* The NULL character is not written.
*
* Note that the length of the buffer is not saved and the string is saved in Big Endian mode
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_string The string to save
* @param p_storeLength If true, store also the length of the string in Big Endian mode, otherwise the length will be provided by p_length2write parameter. Default value: true.
* @param length2write The number of character to write, -1 for all characters
* @return true on success, false otherwise
*/
bool Write(const short p_address, const char *p_string, const bool p_storeLength = true, const int p_length2write = -1);
/** Read a byte from the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_byte The byte value to read
* @return true on success, false otherwise
* Exemple:
* @code
* unsigned char value;
* ...
* myEEPROM.Read(memoryAddress, (unsigned char *)&value);
* ...
* @endcode
*/
bool Read(const short p_address, unsigned char *p_value);
/** Read a short from the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_short The short value to read
* @return true on success, false otherwise
* Exemple:
* @code
* short value;
* ...
* myEEPROM.Read(memoryAddress, (short *)&value);
* ...
* @endcode
*/
bool Read(const short p_address, short *p_short, CFM24VXX_I2C::Mode p_mode = BigEndian);
/** Read an integer from the specified memory address
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_int The integer value to read
* @return true on success, false otherwise
* Exemple:
* @code
* int value;
* ...
* myEEPROM.Read(memoryAddress, (int *)&value);
* ...
* @endcode
*/
bool Read(const short p_address, int *p_int, CFM24VXX_I2C::Mode p_mode = BigEndian);
/** Read a buffer of bytes from the specified memory address and store it into a std::vector<unsigned char> object
*
* Note that the size of the buffer object is used for the number of bytes to read
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_datas The buffer to fill
* @param p_readLengthFirst If true, read the length first and p_length2write parameter is ignored, otherwise the length is provided by p_length2write parameter. Default value: true
* @param p_length2read The number of character to write, -1 to use the size of the string buffer
* @return true on success, false otherwise
* Exemple:
* @code
* std::vector<unsigned char> datas(bufferLength);
* ...
* myEEPROM.Read(memoryAddress, datas);
* ...
* @endcode
*/
bool Read(const short p_address, std::vector<unsigned char> & p_datas, bool p_readLengthFirst = true, int p_length2read = -1);
/** Read a buffer of characters from the specified memory address and store it into a string object
*
* Note that the size of the string object is used for the number of characters to read
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_string The string buffer to fill
* @param p_readLengthFirst If true, read the length first and p_length2write parameter is ignored, otherwise the length is provided by p_length2write parameter. Default value: true
* @param p_length2write The number of character to write, -1 to use the size of the string buffer
* @return true on success, false otherwise
* Exemple:
* @code
* std::string readtext;
* ...
* myEEPROM.Read(memoryAddress, readtext);
* ...
* @endcode
*/
bool Read(const short p_address, std::string & p_string, bool p_readLengthFirst = true, int p_length2write = -1);
/** Read a buffer of characters at the specified memory address. The NULL character is not read.
*
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_string The string to read
* @param p_storeLength If true, store also the length of the buffer in Big Endian mode, otherwise the length will be provided by p_length2write parameter. Default value: true.
* @param p_length2write The number of characters to write, -1 for all bytes. Default value: -1
* @return true on success, false otherwise
*/
bool Read(const short p_address, char *p_string, const bool p_storeLength = true, const int p_length2write = -1);
/** Activate or deactivate write protect (pin 7)
*
* @param p_writeProtect: Set to true to activate write protection, false otherwise
* @return true on success, false otherwise
*/
bool WriteProtect(const bool p_writeProtect);
/** Indicate the current WP state indicator (pin 7)
* @return true is write protected, false otherwise
*/
inline bool IsWriteProtected() {
return (_wp != NULL) ? (bool)(_wp->read() == 1) : false;
}
#if defined(__DEBUG)
/** Dump a memory area
*
* Note that this method is available only on debug mode
* @param p_address The memory address (from 0 to N - 1, N is the number of cells of the memory)
* @param p_count The number of bytes toi dump
* @return true on success, false otherwise
*/
void DumpMemoryArea(const int p_address, const int p_count);
/** For debug purpose only
*/
inline std::string & ToString() { return _internalId; };
#else // __DEBUG
inline void DumpMemoryArea(const int p_address, const int p_count) {};
#endif // _DEBUG
private:
/** Internal reference identifier
*/
std::string _internalId;
private:
/** Retrieve device identifiers
* @remark See FM24V10_ds.pdf Page 9/16 Clause Device ID
*/
bool GetDevideIDs();
/**
* Used to return the serial number
* Note This functionality is available only for the FM24VN10. In other case, it will return 0xff
* @remark See FM24V10_ds.pdf Page 10/16 Clause Unique Serial Number (FM24VN10 only)
*/
bool GetSerialNumbers();
/**
* Function to Calculate CRC
* @param pdatas The read Serial Number
* @param length The number of bytes in the pdatas array. Default: 7 bytes length
* @return The 8-bits length checksum
* @see See FM24V10_ds.pdf Page 10/16 Clause Unique Serial Number (FM24VN10 only)
*/
unsigned char ChecksumSN(const unsigned char *pdatas, const unsigned int length = 7);
}; // End of class CFM24VXX_I2C
}; // End of namespace _FM24VXX_I2C
using namespace _FM24VXX_I2C;
#endif // __FM24VXX_I2C_H__
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| Type: | Library |
|---|---|
| Created: | 03 Apr 2013 |
| Imports: | 35 |
| Forks: | 0 |
| Commits: | 3 |
| Dependents: | 1 |
| Dependencies: | 0 |
| Followers: | 3 |
The code in this repository is Apache licensed.
Components
Ramtron FM24Vxx F-RAM