SPIFlash_LowPowerLab/SPIFlash.cpp

/*
 * Copyright (c) 2013 by Felix Rusu <felix@lowpowerlab.com>
 * SPI Flash memory library for arduino/moteino.
 * This works with 256byte/page SPI flash memory
 * For instance a 4MBit (512Kbyte) flash chip will have 2048 pages: 256*2048 = 524288 bytes (512Kbytes)
 * Minimal modifications should allow chips that have different page size but modifications
 * DEPENDS ON: Arduino SPI library
 *
 * Updated Jan. 5, 2015, TomWS1, modified writeBytes to allow blocks > 256 bytes and handle page misalignment.
 *
 * This file is free software; you can redistribute it and/or modify
 * it under the terms of either the GNU General Public License version 2
 * or the GNU Lesser General Public License version 2.1, both as
 * published by the Free Software Foundation.
 */

#include <SPIFlash.h>

byte SPIFlash::UNIQUEID[8];

/// IMPORTANT: NAND FLASH memory requires erase before write, because
///            it can only transition from 1s to 0s and only the erase command can reset all 0s to 1s
/// See http://en.wikipedia.org/wiki/Flash_memory
/// The smallest range that can be erased is a sector (4K, 32K, 64K); there is also a chip erase command

/// Constructor. JedecID is optional but recommended, since this will ensure that the device is present and has a valid response
/// get this from the datasheet of your flash chip
/// Example for Atmel-Adesto 4Mbit AT25DF041A: 0x1F44 (page 27: http://www.adestotech.com/sites/default/files/datasheets/doc3668.pdf)
/// Example for Winbond 4Mbit W25X40CL: 0xEF30 (page 14: http://www.winbond.com/NR/rdonlyres/6E25084C-0BFE-4B25-903D-AE10221A0929/0/W25X40CL.pdf)
SPIFlash::SPIFlash(uint8_t slaveSelectPin, uint16_t jedecID) {
  _slaveSelectPin = slaveSelectPin;
  _jedecID = jedecID;
}

/// Select the flash chip
void SPIFlash::select() {
  noInterrupts();
  //save current SPI settings
  _SPCR = SPCR;
  _SPSR = SPSR;
  //set FLASH chip SPI settings
  SPI.setDataMode(SPI_MODE0);
  SPI.setBitOrder(MSBFIRST);
  SPI.setClockDivider(SPI_CLOCK_DIV4); //decided to slow down from DIV2 after SPI stalling in some instances, especially visible on mega1284p when RFM69 and FLASH chip both present
  SPI.begin();
  digitalWrite(_slaveSelectPin, LOW);
}

/// UNselect the flash chip
void SPIFlash::unselect() {
  digitalWrite(_slaveSelectPin, HIGH);
  //restore SPI settings to what they were before talking to the FLASH chip
  SPCR = _SPCR;
  SPSR = _SPSR;
  interrupts();
}

/// setup SPI, read device ID etc...
boolean SPIFlash::initialize()
{
  _SPCR = SPCR;
  _SPSR = SPSR;
  pinMode(_slaveSelectPin, OUTPUT);
  unselect();
  wakeup();
  
  if (_jedecID == 0 || readDeviceId() == _jedecID) {
    command(SPIFLASH_STATUSWRITE, true); // Write Status Register
    SPI.transfer(0);                     // Global Unprotect
    unselect();
    return true;
  }
  return false;
}

/// Get the manufacturer and device ID bytes (as a short word)
word SPIFlash::readDeviceId()
{
#if defined(__AVR_ATmega32U4__) // Arduino Leonardo, MoteinoLeo
  command(SPIFLASH_IDREAD); // Read JEDEC ID
#else
  select();
  SPI.transfer(SPIFLASH_IDREAD);
#endif
  word jedecid = SPI.transfer(0) << 8;
  jedecid |= SPI.transfer(0);
  unselect();
  return jedecid;
}

/// Get the 64 bit unique identifier, stores it in UNIQUEID[8]. Only needs to be called once, ie after initialize
/// Returns the byte pointer to the UNIQUEID byte array
/// Read UNIQUEID like this:
/// flash.readUniqueId(); for (byte i=0;i<8;i++) { Serial.print(flash.UNIQUEID[i], HEX); Serial.print(' '); }
/// or like this:
/// flash.readUniqueId(); byte* MAC = flash.readUniqueId(); for (byte i=0;i<8;i++) { Serial.print(MAC[i], HEX); Serial.print(' '); }
byte* SPIFlash::readUniqueId()
{
  command(SPIFLASH_MACREAD);
  SPI.transfer(0);
  SPI.transfer(0);
  SPI.transfer(0);
  SPI.transfer(0);
  for (byte i=0;i<8;i++)
    UNIQUEID[i] = SPI.transfer(0);
  unselect();
  return UNIQUEID;
}

/// read 1 byte from flash memory
byte SPIFlash::readByte(long addr) {
  command(SPIFLASH_ARRAYREADLOWFREQ);
  SPI.transfer(addr >> 16);
  SPI.transfer(addr >> 8);
  SPI.transfer(addr);
  byte result = SPI.transfer(0);
  unselect();
  return result;
}

/// read unlimited # of bytes
void SPIFlash::readBytes(long addr, void* buf, word len) {
  command(SPIFLASH_ARRAYREAD);
  SPI.transfer(addr >> 16);
  SPI.transfer(addr >> 8);
  SPI.transfer(addr);
  SPI.transfer(0); //"dont care"
  for (word i = 0; i < len; ++i)
    ((byte*) buf)[i] = SPI.transfer(0);
  unselect();
}

/// Send a command to the flash chip, pass TRUE for isWrite when its a write command
void SPIFlash::command(byte cmd, boolean isWrite){
#if defined(__AVR_ATmega32U4__) // Arduino Leonardo, MoteinoLeo
  DDRB |= B00000001;            // Make sure the SS pin (PB0 - used by RFM12B on MoteinoLeo R1) is set as output HIGH!
  PORTB |= B00000001;
#endif
  if (isWrite)
  {
    command(SPIFLASH_WRITEENABLE); // Write Enable
    unselect();
  }
  //wait for any write/erase to complete
  //  a time limit cannot really be added here without it being a very large safe limit
  //  that is because some chips can take several seconds to carry out a chip erase or other similar multi block or entire-chip operations
  //  a recommended alternative to such situations where chip can be or not be present is to add a 10k or similar weak pulldown on the
  //  open drain MISO input which can read noise/static and hence return a non 0 status byte, causing the while() to hang when a flash chip is not present
  while(busy());
  select();
  SPI.transfer(cmd);
}

/// check if the chip is busy erasing/writing
boolean SPIFlash::busy()
{
  /*
  select();
  SPI.transfer(SPIFLASH_STATUSREAD);
  byte status = SPI.transfer(0);
  unselect();
  return status & 1;
  */
  return readStatus() & 1;
}

/// return the STATUS register
byte SPIFlash::readStatus()
{
  select();
  SPI.transfer(SPIFLASH_STATUSREAD);
  byte status = SPI.transfer(0);
  unselect();
  return status;
}


/// Write 1 byte to flash memory
/// WARNING: you can only write to previously erased memory locations (see datasheet)
///          use the block erase commands to first clear memory (write 0xFFs)
void SPIFlash::writeByte(long addr, uint8_t byt) {
  command(SPIFLASH_BYTEPAGEPROGRAM, true);  // Byte/Page Program
  SPI.transfer(addr >> 16);
  SPI.transfer(addr >> 8);
  SPI.transfer(addr);
  SPI.transfer(byt);
  unselect();
}

/// write multiple bytes to flash memory (up to 64K)
/// WARNING: you can only write to previously erased memory locations (see datasheet)
///          use the block erase commands to first clear memory (write 0xFFs)
/// This version handles both page alignment and data blocks larger than 256 bytes.
///
void SPIFlash::writeBytes(long addr, const void* buf, uint16_t len) {
  uint16_t n;
  uint16_t maxBytes = 256-(addr%256);  // force the first set of bytes to stay within the first page
  uint16_t offset = 0;
  while (len>0)
  {
    n = (len<=maxBytes) ? len : maxBytes;
    command(SPIFLASH_BYTEPAGEPROGRAM, true);  // Byte/Page Program
    SPI.transfer(addr >> 16);
    SPI.transfer(addr >> 8);
    SPI.transfer(addr);
    
    for (uint16_t i = 0; i < n; i++)
      SPI.transfer(((byte*) buf)[offset + i]);
    unselect();
    
    addr+=n;  // adjust the addresses and remaining bytes by what we've just transferred.
    offset +=n;
    len -= n;
    maxBytes = 256;   // now we can do up to 256 bytes per loop
  }
}

/// erase entire flash memory array
/// may take several seconds depending on size, but is non blocking
/// so you may wait for this to complete using busy() or continue doing
/// other things and later check if the chip is done with busy()
/// note that any command will first wait for chip to become available using busy()
/// so no need to do that twice
void SPIFlash::chipErase() {
  command(SPIFLASH_CHIPERASE, true);
  unselect();
}

/// erase a 4Kbyte block
void SPIFlash::blockErase4K(long addr) {
  command(SPIFLASH_BLOCKERASE_4K, true); // Block Erase
  SPI.transfer(addr >> 16);
  SPI.transfer(addr >> 8);
  SPI.transfer(addr);
  unselect();
}

/// erase a 32Kbyte block
void SPIFlash::blockErase32K(long addr) {
  command(SPIFLASH_BLOCKERASE_32K, true); // Block Erase
  SPI.transfer(addr >> 16);
  SPI.transfer(addr >> 8);
  SPI.transfer(addr);
  unselect();
}

void SPIFlash::sleep() {
  command(SPIFLASH_SLEEP);
  unselect();
}

void SPIFlash::wakeup() {
  command(SPIFLASH_WAKE);
  unselect();
}

/// cleanup
void SPIFlash::end() {
  SPI.end();
}
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`/*`
			`* Copyright (c) 2013 by Felix Rusu <felix@lowpowerlab.com>`
			`* SPI Flash memory library for arduino/moteino.`
			`* This works with 256byte/page SPI flash memory`
			`* For instance a 4MBit (512Kbyte) flash chip will have 2048 pages: 256*2048 = 524288 bytes (512Kbytes)`
			`* Minimal modifications should allow chips that have different page size but modifications`
			`* DEPENDS ON: Arduino SPI library`
			`*`
Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`* Updated Jan. 5, 2015, TomWS1, modified writeBytes to allow blocks > 256 bytes and handle page misalignment.`
			`*`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`* This file is free software; you can redistribute it and/or modify`
			`* it under the terms of either the GNU General Public License version 2`
			`* or the GNU Lesser General Public License version 2.1, both as`
			`* published by the Free Software Foundation.`
			`*/`

			`#include <SPIFlash.h>`

Add readUniqueId() to get unique 64 bit MAC Reads 64 bit MAC unique ID 2014-05-29 19:32:12 +01:00			`byte SPIFlash::UNIQUEID[8];`

adding sleep/wakeup functions, moving WirelessHEX 2013-07-14 04:07:08 +01:00			`/// IMPORTANT: NAND FLASH memory requires erase before write, because`
			`/// it can only transition from 1s to 0s and only the erase command can reset all 0s to 1s`
			`/// See http://en.wikipedia.org/wiki/Flash_memory`
			`/// The smallest range that can be erased is a sector (4K, 32K, 64K); there is also a chip erase command`

Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`/// Constructor. JedecID is optional but recommended, since this will ensure that the device is present and has a valid response`
			`/// get this from the datasheet of your flash chip`
			`/// Example for Atmel-Adesto 4Mbit AT25DF041A: 0x1F44 (page 27: http://www.adestotech.com/sites/default/files/datasheets/doc3668.pdf)`
Update SPIFlash.cpp 2013-04-16 20:44:56 +01:00			`/// Example for Winbond 4Mbit W25X40CL: 0xEF30 (page 14: http://www.winbond.com/NR/rdonlyres/6E25084C-0BFE-4B25-903D-AE10221A0929/0/W25X40CL.pdf)`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`SPIFlash::SPIFlash(uint8_t slaveSelectPin, uint16_t jedecID) {`
			`_slaveSelectPin = slaveSelectPin;`
			`_jedecID = jedecID;`
			`}`

			`/// Select the flash chip`
			`void SPIFlash::select() {`
			`noInterrupts();`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`//save current SPI settings`
			`_SPCR = SPCR;`
			`_SPSR = SPSR;`
			`//set FLASH chip SPI settings`
			`SPI.setDataMode(SPI_MODE0);`
			`SPI.setBitOrder(MSBFIRST);`
			`SPI.setClockDivider(SPI_CLOCK_DIV4); //decided to slow down from DIV2 after SPI stalling in some instances, especially visible on mega1284p when RFM69 and FLASH chip both present`
			`SPI.begin();`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`digitalWrite(_slaveSelectPin, LOW);`
			`}`

			`/// UNselect the flash chip`
			`void SPIFlash::unselect() {`
			`digitalWrite(_slaveSelectPin, HIGH);`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`//restore SPI settings to what they were before talking to the FLASH chip`
			`SPCR = _SPCR;`
			`SPSR = _SPSR;`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`interrupts();`
			`}`

			`/// setup SPI, read device ID etc...`
			`boolean SPIFlash::initialize()`
			`{`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`_SPCR = SPCR;`
			`_SPSR = SPSR;`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`pinMode(_slaveSelectPin, OUTPUT);`
			`unselect();`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`wakeup();`

Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`if (_jedecID == 0 \|\| readDeviceId() == _jedecID) {`
			`command(SPIFLASH_STATUSWRITE, true); // Write Status Register`
			`SPI.transfer(0); // Global Unprotect`
			`unselect();`
			`return true;`
			`}`
			`return false;`
			`}`

			`/// Get the manufacturer and device ID bytes (as a short word)`
			`word SPIFlash::readDeviceId()`
			`{`
fix infinite loop bug when HIGH-Z MISO stays high (take2) 2013-08-02 15:23:56 +01:00			`#if defined(__AVR_ATmega32U4__) // Arduino Leonardo, MoteinoLeo`
			`command(SPIFLASH_IDREAD); // Read JEDEC ID`
			`#else`
fix infinite loop bug when HIGH-Z MISO stays high When FLASH chip is not present and MISO is in high impedance, other SPI devices might pull MISO high and the while(busy) loop might never return because of a false positive busy (actually MISO would return 0XFF for status register including the BUSY bit) 2013-08-02 05:02:46 +01:00			`select();`
			`SPI.transfer(SPIFLASH_IDREAD);`
fix infinite loop bug when HIGH-Z MISO stays high (take2) 2013-08-02 15:23:56 +01:00			`#endif`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`word jedecid = SPI.transfer(0) << 8;`
			`jedecid \|= SPI.transfer(0);`
			`unselect();`
			`return jedecid;`
			`}`

Add readUniqueId() to get unique 64 bit MAC Reads 64 bit MAC unique ID 2014-05-29 19:32:12 +01:00			`/// Get the 64 bit unique identifier, stores it in UNIQUEID[8]. Only needs to be called once, ie after initialize`
			`/// Returns the byte pointer to the UNIQUEID byte array`
			`/// Read UNIQUEID like this:`
			`/// flash.readUniqueId(); for (byte i=0;i<8;i++) { Serial.print(flash.UNIQUEID[i], HEX); Serial.print(' '); }`
			`/// or like this:`
			`/// flash.readUniqueId(); byte* MAC = flash.readUniqueId(); for (byte i=0;i<8;i++) { Serial.print(MAC[i], HEX); Serial.print(' '); }`
			`byte* SPIFlash::readUniqueId()`
			`{`
			`command(SPIFLASH_MACREAD);`
			`SPI.transfer(0);`
			`SPI.transfer(0);`
			`SPI.transfer(0);`
			`SPI.transfer(0);`
			`for (byte i=0;i<8;i++)`
			`UNIQUEID[i] = SPI.transfer(0);`
			`unselect();`
			`return UNIQUEID;`
			`}`

Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`/// read 1 byte from flash memory`
			`byte SPIFlash::readByte(long addr) {`
			`command(SPIFLASH_ARRAYREADLOWFREQ);`
			`SPI.transfer(addr >> 16);`
			`SPI.transfer(addr >> 8);`
			`SPI.transfer(addr);`
			`byte result = SPI.transfer(0);`
			`unselect();`
			`return result;`
			`}`

			`/// read unlimited # of bytes`
			`void SPIFlash::readBytes(long addr, void* buf, word len) {`
			`command(SPIFLASH_ARRAYREAD);`
			`SPI.transfer(addr >> 16);`
			`SPI.transfer(addr >> 8);`
			`SPI.transfer(addr);`
			`SPI.transfer(0); //"dont care"`
			`for (word i = 0; i < len; ++i)`
			`((byte*) buf)[i] = SPI.transfer(0);`
			`unselect();`
			`}`

			`/// Send a command to the flash chip, pass TRUE for isWrite when its a write command`
			`void SPIFlash::command(byte cmd, boolean isWrite){`
Fix for SS pin on MoteinoLeo, Atmega32u4, Arduino Leonardo 2013-05-30 22:47:40 +01:00			`#if defined(__AVR_ATmega32U4__) // Arduino Leonardo, MoteinoLeo`
			`DDRB \|= B00000001; // Make sure the SS pin (PB0 - used by RFM12B on MoteinoLeo R1) is set as output HIGH!`
			`PORTB \|= B00000001;`
			`#endif`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`if (isWrite)`
			`{`
			`command(SPIFLASH_WRITEENABLE); // Write Enable`
			`unselect();`
			`}`
Add busy() while() explanation 2015-01-09 01:44:12 +00:00			`//wait for any write/erase to complete`
			`// a time limit cannot really be added here without it being a very large safe limit`
			`// that is because some chips can take several seconds to carry out a chip erase or other similar multi block or entire-chip operations`
			`// a recommended alternative to such situations where chip can be or not be present is to add a 10k or similar weak pulldown on the`
			`// open drain MISO input which can read noise/static and hence return a non 0 status byte, causing the while() to hang when a flash chip is not present`
			`while(busy());`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`select();`
			`SPI.transfer(cmd);`
			`}`

			`/// check if the chip is busy erasing/writing`
			`boolean SPIFlash::busy()`
			`{`
			`/*`
			`select();`
			`SPI.transfer(SPIFLASH_STATUSREAD);`
			`byte status = SPI.transfer(0);`
			`unselect();`
			`return status & 1;`
			`*/`
			`return readStatus() & 1;`
			`}`

			`/// return the STATUS register`
			`byte SPIFlash::readStatus()`
			`{`
			`select();`
			`SPI.transfer(SPIFLASH_STATUSREAD);`
			`byte status = SPI.transfer(0);`
			`unselect();`
			`return status;`
			`}`


			`/// Write 1 byte to flash memory`
			`/// WARNING: you can only write to previously erased memory locations (see datasheet)`
			`/// use the block erase commands to first clear memory (write 0xFFs)`
			`void SPIFlash::writeByte(long addr, uint8_t byt) {`
			`command(SPIFLASH_BYTEPAGEPROGRAM, true); // Byte/Page Program`
			`SPI.transfer(addr >> 16);`
			`SPI.transfer(addr >> 8);`
			`SPI.transfer(addr);`
			`SPI.transfer(byt);`
			`unselect();`
			`}`

Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`/// write multiple bytes to flash memory (up to 64K)`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`/// WARNING: you can only write to previously erased memory locations (see datasheet)`
			`/// use the block erase commands to first clear memory (write 0xFFs)`
Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`/// This version handles both page alignment and data blocks larger than 256 bytes.`
			`///`
Fix writeBytes length Credit to wilsynet 2014-06-30 16:25:09 +01:00			`void SPIFlash::writeBytes(long addr, const void* buf, uint16_t len) {`
void* pointer arithmetic bug 2015-02-09 03:13:47 +00:00			`uint16_t n;`
			`uint16_t maxBytes = 256-(addr%256); // force the first set of bytes to stay within the first page`
			`uint16_t offset = 0;`
Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`while (len>0)`
			`{`
			`n = (len<=maxBytes) ? len : maxBytes;`
			`command(SPIFLASH_BYTEPAGEPROGRAM, true); // Byte/Page Program`
			`SPI.transfer(addr >> 16);`
			`SPI.transfer(addr >> 8);`
			`SPI.transfer(addr);`
void* pointer arithmetic bug 2015-02-09 03:13:47 +00:00
Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`for (uint16_t i = 0; i < n; i++)`
void* pointer arithmetic bug 2015-02-09 03:13:47 +00:00			`SPI.transfer(((byte*) buf)[offset + i]);`
Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`unselect();`

			`addr+=n; // adjust the addresses and remaining bytes by what we've just transferred.`
void* pointer arithmetic bug 2015-02-09 03:13:47 +00:00			`offset +=n;`
Removed 256 restriction from writeBytes() Original version was constrained by Flash 256 byte page limits. This change allows up to 64K writes and also deals with blocks that cross pages (even if 2 bytes starting at address = 0xyyFF. 2015-02-06 14:58:42 +00:00			`len -= n;`
			`maxBytes = 256; // now we can do up to 256 bytes per loop`
			`}`
Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`}`

			`/// erase entire flash memory array`
			`/// may take several seconds depending on size, but is non blocking`
			`/// so you may wait for this to complete using busy() or continue doing`
			`/// other things and later check if the chip is done with busy()`
			`/// note that any command will first wait for chip to become available using busy()`
			`/// so no need to do that twice`
			`void SPIFlash::chipErase() {`
			`command(SPIFLASH_CHIPERASE, true);`
			`unselect();`
			`}`

			`/// erase a 4Kbyte block`
			`void SPIFlash::blockErase4K(long addr) {`
			`command(SPIFLASH_BLOCKERASE_4K, true); // Block Erase`
			`SPI.transfer(addr >> 16);`
			`SPI.transfer(addr >> 8);`
			`SPI.transfer(addr);`
			`unselect();`
			`}`

			`/// erase a 32Kbyte block`
			`void SPIFlash::blockErase32K(long addr) {`
			`command(SPIFLASH_BLOCKERASE_32K, true); // Block Erase`
			`SPI.transfer(addr >> 16);`
			`SPI.transfer(addr >> 8);`
			`SPI.transfer(addr);`
			`unselect();`
			`}`

adding sleep/wakeup functions, moving WirelessHEX 2013-07-14 04:07:08 +01:00			`void SPIFlash::sleep() {`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`command(SPIFLASH_SLEEP);`
adding sleep/wakeup functions, moving WirelessHEX 2013-07-14 04:07:08 +01:00			`unselect();`
			`}`

			`void SPIFlash::wakeup() {`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`command(SPIFLASH_WAKE);`
adding sleep/wakeup functions, moving WirelessHEX 2013-07-14 04:07:08 +01:00			`unselect();`
			`}`

Create SPIFlash.cpp 2013-04-04 23:04:29 +01:00			`/// cleanup`
			`void SPIFlash::end() {`
			`SPI.end();`
Unintrusive SPI transactions & misc fixes 2014-07-29 22:10:06 +01:00			`}`