FreeRTOS/Demo/CORTEX_AT91SAM3U256_IAR/AT91Lib/peripherals/efc/efc.c - nest-detect/1.2/freertos - Git at Google

 /* ----------------------------------------------------------------------------
  *         ATMEL Microcontroller Software Support
  * ----------------------------------------------------------------------------
  * Copyright (c) 2008, Atmel Corporation
  *
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are met:
  *
  * - Redistributions of source code must retain the above copyright notice,
  * this list of conditions and the disclaimer below.
  *
  * Atmel's name may not be used to endorse or promote products derived from
  * this software without specific prior written permission.
  *
  * DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR
  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
  * DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
  * OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
  * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
  * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
  * EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  * ----------------------------------------------------------------------------
  */

 //------------------------------------------------------------------------------
 //         Headers
 //------------------------------------------------------------------------------

 #include "efc.h"

 #ifdef BOARD_FLASH_EFC

 #include <utility/assert.h>
 #include <utility/trace.h>

 //------------------------------------------------------------------------------
 //         Local definitions
 //------------------------------------------------------------------------------

 // Round a number to the nearest integral value (number must have been
 // multiplied by 10, e.g. to round 10.3 enter 103).
 #define ROUND(n)    ((((n) % 10) >= 5) ? (((n) / 10) + 1) : ((n) / 10))

 // Returns the FMCN field value when manipulating lock bits, given MCK.
 #if defined(at91sam7a3)
     #define FMCN_BITS(mck)      (ROUND((mck) / 1000000) << 16)
 #else
     #define FMCN_BITS(mck)      (ROUND((mck) / 100000) << 16)
 #endif

 // Returns the FMCN field value when manipulating the rest of the flash.
 #define FMCN_FLASH(mck)         ((((mck) / 2000000) * 3) << 16)

 //------------------------------------------------------------------------------
 //         Local functions
 //------------------------------------------------------------------------------

 /// Master clock frequency, used to infer the value of the FMCN field.
 #ifdef MCK_VARIABLE
 static unsigned int lMck = 0;
 #else
 static const unsigned int lMck = BOARD_MCK;
 #endif

 //------------------------------------------------------------------------------
 //         Global functions
 //------------------------------------------------------------------------------

 //------------------------------------------------------------------------------
 /// Sets the system master clock so the FMCN field of the EFC(s) can be
 /// programmed properly.
 /// \param mck  Master clock frequency in Hz.
 //------------------------------------------------------------------------------
 void EFC_SetMasterClock(unsigned int mck)
 {
 #ifdef MCK_VARIABLE
     lMck = mck;
 #else
     ASSERT(mck == BOARD_MCK, "-F- EFC has not been configured to work at a freq. different from %dMHz", BOARD_MCK);
 #endif
 }

 //------------------------------------------------------------------------------
 /// Enables the given interrupt sources on an EFC peripheral.
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 /// \param sources  Interrupt sources to enable.
 //------------------------------------------------------------------------------
 void EFC_EnableIt(AT91S_EFC *pEfc, unsigned int sources)
 {
     SANITY_CHECK(pEfc);
     SANITY_CHECK((sources & ~0x0000000D) == 0);

     pEfc->EFC_FMR |= sources;
 }

 //------------------------------------------------------------------------------
 /// Disables the given interrupt sources on an EFC peripheral.
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 /// \param sources  Interrupt sources to disable.
 //------------------------------------------------------------------------------
 void EFC_DisableIt(AT91S_EFC *pEfc, unsigned int sources)
 {
     SANITY_CHECK(pEfc);
     SANITY_CHECK((sources & ~(AT91C_MC_FRDY | AT91C_MC_LOCKE | AT91C_MC_PROGE)) == 0);

     pEfc->EFC_FMR &= ~sources;
 }

 //------------------------------------------------------------------------------
 /// Enables or disable the "Erase before programming" feature of an EFC.
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 /// \param enable  If 1, the feature is enabled; otherwise it is disabled.
 //------------------------------------------------------------------------------
 void EFC_SetEraseBeforeProgramming(AT91S_EFC *pEfc, unsigned char enable)
 {
     SANITY_CHECK(pEfc);

     if (enable) {

         pEfc->EFC_FMR &= ~AT91C_MC_NEBP;
     }
     else {

         pEfc->EFC_FMR |= AT91C_MC_NEBP;
     }
 }

 //------------------------------------------------------------------------------
 /// Translates the given address into EFC, page and offset values. The resulting
 /// values are stored in the provided variables if they are not null.
 /// \param address  Address to translate.
 /// \param ppEfc  Pointer to target EFC peripheral.
 /// \param pPage  First page accessed.
 /// \param pOffset  Byte offset in first page.
 //------------------------------------------------------------------------------
 void EFC_TranslateAddress(
     unsigned int address,
     AT91S_EFC **ppEfc,
     unsigned short *pPage,
     unsigned short *pOffset)
 {
     AT91S_EFC *pEfc;
     unsigned short page;
     unsigned short offset;

     SANITY_CHECK(address >= AT91C_IFLASH);
     SANITY_CHECK(address <= (AT91C_IFLASH + AT91C_IFLASH_SIZE));

 #if defined(AT91C_BASE_EFC0)
     if (address >= (AT91C_IFLASH + AT91C_IFLASH_SIZE / 2)) {

         pEfc = AT91C_BASE_EFC1;
         page = (address - AT91C_IFLASH - AT91C_IFLASH_SIZE / 2) / AT91C_IFLASH_PAGE_SIZE;
         offset = (address - AT91C_IFLASH - AT91C_IFLASH_SIZE / 2) % AT91C_IFLASH_PAGE_SIZE;
     }
     else {

         pEfc = AT91C_BASE_EFC0;
         page = (address - AT91C_IFLASH) / AT91C_IFLASH_PAGE_SIZE;
         offset = (address - AT91C_IFLASH) % AT91C_IFLASH_PAGE_SIZE;
     }
 #else
     pEfc = AT91C_BASE_EFC;
     page = (address - AT91C_IFLASH) / AT91C_IFLASH_PAGE_SIZE;
     offset = (address - AT91C_IFLASH) % AT91C_IFLASH_PAGE_SIZE;
 #endif
     TRACE_DEBUG("Translated 0x%08X to EFC=0x%08X, page=%d and offset=%d\n\r",
               address, (unsigned int) pEfc, page, offset);

     // Store values
     if (ppEfc) {

         *ppEfc = pEfc;
     }
     if (pPage) {

         *pPage = page;
     }
     if (pOffset) {

         *pOffset = offset;
     }
 }

 //------------------------------------------------------------------------------
 /// Computes the address of a flash access given the EFC, page and offset.
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 /// \param page  Page number.
 /// \param offset  Byte offset inside page.
 /// \param pAddress  Computed address (optional).
 //------------------------------------------------------------------------------
 void EFC_ComputeAddress(
     AT91S_EFC *pEfc,
     unsigned short page,
     unsigned short offset,
     unsigned int *pAddress)
 {
     unsigned int address;

     SANITY_CHECK(pEfc);
 #if defined(AT91C_BASE_EFC1)
     SANITY_CHECK(page <= (AT91C_IFLASH_NB_OF_PAGES / 2));
 #else
     SANITY_CHECK(page <= AT91C_IFLASH_NB_OF_PAGES);
 #endif
     SANITY_CHECK(offset < AT91C_IFLASH_PAGE_SIZE);

     // Compute address
     address = AT91C_IFLASH + page * AT91C_IFLASH_PAGE_SIZE + offset;
 #if defined(AT91C_BASE_EFC1)
     if (pEfc == AT91C_BASE_EFC1) {

         address += AT91C_IFLASH_SIZE / 2;
     }
 #endif

     // Store result
     if (pAddress) {

         *pAddress = address;
     }
 }

 //------------------------------------------------------------------------------
 /// Starts the executing the given command on an EFC. This function returns
 /// as soon as the command is started. It does NOT set the FMCN field automatically.
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 /// \param command  Command to execute.
 /// \param argument  Command argument (should be 0 if not used).
 //------------------------------------------------------------------------------
 #if defined(flash)
    #ifdef __ICCARM__
 __ramfunc
    #else
 __attribute__ ((section (".ramfunc")))
    #endif
 #endif
 void EFC_StartCommand(
     AT91S_EFC *pEfc,
     unsigned char command,
     unsigned short argument)
 {
     SANITY_CHECK(pEfc);
     ASSERT(lMck != 0, "-F- Master clock not set.\n\r");

     // Check command & argument
     switch (command) {

         case AT91C_MC_FCMD_PROG_AND_LOCK:
             ASSERT(0, "-F- Write and lock command cannot be carried out.\n\r");
             break;

         case AT91C_MC_FCMD_START_PROG:
         case AT91C_MC_FCMD_LOCK:
         case AT91C_MC_FCMD_UNLOCK:
             ASSERT(argument < AT91C_IFLASH_NB_OF_PAGES,
                    "-F- Maximum number of pages is %d (argument was %d)\n\r",
                    AT91C_IFLASH_NB_OF_PAGES,
                    argument);
             break;

 #if (EFC_NUM_GPNVMS > 0)
         case AT91C_MC_FCMD_SET_GP_NVM:
         case AT91C_MC_FCMD_CLR_GP_NVM:
             ASSERT(argument < EFC_NUM_GPNVMS, "-F- A maximum of %d GPNVMs are available on the chip.\n\r", EFC_NUM_GPNVMS);
             break;
 #endif

         case AT91C_MC_FCMD_ERASE_ALL:

 #if !defined(EFC_NO_SECURITY_BIT)
         case AT91C_MC_FCMD_SET_SECURITY:
 #endif
             ASSERT(argument == 0, "-F- Argument is meaningless for the given command\n\r");
             break;

         default: ASSERT(0, "-F- Unknown command %d\n\r", command);
     }

     // Set FMCN
     switch (command) {

         case AT91C_MC_FCMD_LOCK:
         case AT91C_MC_FCMD_UNLOCK:
 #if (EFC_NUM_GPNVMS > 0)
         case AT91C_MC_FCMD_SET_GP_NVM:
         case AT91C_MC_FCMD_CLR_GP_NVM:
 #endif
 #if !defined(EFC_NO_SECURITY_BIT)
         case AT91C_MC_FCMD_SET_SECURITY:
 #endif
             pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) | FMCN_BITS(lMck);
             break;

         case AT91C_MC_FCMD_START_PROG:
         case AT91C_MC_FCMD_ERASE_ALL:
             pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) | FMCN_FLASH(lMck);
             break;
     }

     // Start command
     ASSERT((pEfc->EFC_FSR & AT91C_MC_FRDY) != 0, "-F- Efc is not ready\n\r");
     pEfc->EFC_FCR = (0x5A << 24) | (argument << 8) | command;
 }

 //------------------------------------------------------------------------------
 /// Performs the given command and wait until its completion (or an error).
 /// Returns 0 if successful; otherwise returns an error code.
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 /// \param command  Command to perform.
 /// \param argument  Optional command argument.
 //------------------------------------------------------------------------------
 #if defined(flash)
    #ifdef __ICCARM__
 __ramfunc
    #else
 __attribute__ ((section (".ramfunc")))
    #endif
 #endif
 unsigned char EFC_PerformCommand(
     AT91S_EFC *pEfc,
     unsigned char command,
     unsigned short argument)
 {
     unsigned int status;

     // Set FMCN
     switch (command) {

         case AT91C_MC_FCMD_LOCK:
         case AT91C_MC_FCMD_UNLOCK:
 #if (EFC_NUM_GPNVMS > 0)
         case AT91C_MC_FCMD_SET_GP_NVM:
         case AT91C_MC_FCMD_CLR_GP_NVM:
 #endif
 #if !defined(EFC_NO_SECURITY_BIT)
         case AT91C_MC_FCMD_SET_SECURITY:
 #endif
             pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) | FMCN_BITS(lMck);
             break;

         case AT91C_MC_FCMD_START_PROG:
         case AT91C_MC_FCMD_ERASE_ALL:
             pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) | FMCN_FLASH(lMck);
             break;
     }

 #ifdef BOARD_FLASH_IAP_ADDRESS
     // Pointer on IAP function in ROM
     static void (*IAP_PerformCommand)(unsigned int, unsigned int);
     unsigned int index = 0;
 #ifdef AT91C_BASE_EFC1
     if (pEfc == AT91C_BASE_EFC1) {

         index = 1;
     }
 #endif
     IAP_PerformCommand = (void (*)(unsigned int, unsigned int)) *((unsigned int *) BOARD_FLASH_IAP_ADDRESS);

     // Check if IAP function is implemented (opcode in SWI != 'b' or 'ldr') */
     if ((((((unsigned long) IAP_PerformCommand >> 24) & 0xFF) != 0xEA) &&
         (((unsigned long) IAP_PerformCommand >> 24) & 0xFF) != 0xE5)) {

         IAP_PerformCommand(index, (0x5A << 24) | (argument << 8) | command);
         return (pEfc->EFC_FSR & (AT91C_MC_LOCKE | AT91C_MC_PROGE));
     }
 #endif

     pEfc->EFC_FCR = (0x5A << 24) | (argument << 8) | command;
     do {

         status = pEfc->EFC_FSR;
     }
     while ((status & AT91C_MC_FRDY) == 0);

     return (status & (AT91C_MC_PROGE | AT91C_MC_LOCKE));
 }

 //------------------------------------------------------------------------------
 /// Returns the current status of an EFC. Keep in mind that this function clears
 /// the value of some status bits (LOCKE, PROGE).
 /// \param pEfc  Pointer to an AT91S_EFC structure.
 //------------------------------------------------------------------------------
 unsigned int EFC_GetStatus(AT91S_EFC *pEfc)
 {
     return pEfc->EFC_FSR;
 }

 #endif //#ifdef BOARD_FLASH_EFC
	/* ----------------------------------------------------------------------------
	* ATMEL Microcontroller Software Support
	* ----------------------------------------------------------------------------
	* Copyright (c) 2008, Atmel Corporation
	*
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	*
	* - Redistributions of source code must retain the above copyright notice,
	* this list of conditions and the disclaimer below.
	*
	* Atmel's name may not be used to endorse or promote products derived from
	* this software without specific prior written permission.
	*
	* DISCLAIMER: THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR
	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
	* DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
	* OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
	* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
	* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
	* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	* ----------------------------------------------------------------------------
	*/

	//------------------------------------------------------------------------------
	// Headers
	//------------------------------------------------------------------------------

	#include "efc.h"

	#ifdef BOARD_FLASH_EFC

	#include <utility/assert.h>
	#include <utility/trace.h>

	//------------------------------------------------------------------------------
	// Local definitions
	//------------------------------------------------------------------------------

	// Round a number to the nearest integral value (number must have been
	// multiplied by 10, e.g. to round 10.3 enter 103).
	#define ROUND(n) ((((n) % 10) >= 5) ? (((n) / 10) + 1) : ((n) / 10))

	// Returns the FMCN field value when manipulating lock bits, given MCK.
	#if defined(at91sam7a3)
	#define FMCN_BITS(mck) (ROUND((mck) / 1000000) << 16)
	#else
	#define FMCN_BITS(mck) (ROUND((mck) / 100000) << 16)
	#endif

	// Returns the FMCN field value when manipulating the rest of the flash.
	#define FMCN_FLASH(mck) ((((mck) / 2000000) * 3) << 16)

	//------------------------------------------------------------------------------
	// Local functions
	//------------------------------------------------------------------------------

	/// Master clock frequency, used to infer the value of the FMCN field.
	#ifdef MCK_VARIABLE
	static unsigned int lMck = 0;
	#else
	static const unsigned int lMck = BOARD_MCK;
	#endif

	//------------------------------------------------------------------------------
	// Global functions
	//------------------------------------------------------------------------------

	//------------------------------------------------------------------------------
	/// Sets the system master clock so the FMCN field of the EFC(s) can be
	/// programmed properly.
	/// \param mck Master clock frequency in Hz.
	//------------------------------------------------------------------------------
	void EFC_SetMasterClock(unsigned int mck)
	{
	#ifdef MCK_VARIABLE
	lMck = mck;
	#else
	ASSERT(mck == BOARD_MCK, "-F- EFC has not been configured to work at a freq. different from %dMHz", BOARD_MCK);
	#endif
	}

	//------------------------------------------------------------------------------
	/// Enables the given interrupt sources on an EFC peripheral.
	/// \param pEfc Pointer to an AT91S_EFC structure.
	/// \param sources Interrupt sources to enable.
	//------------------------------------------------------------------------------
	void EFC_EnableIt(AT91S_EFC *pEfc, unsigned int sources)
	{
	SANITY_CHECK(pEfc);
	SANITY_CHECK((sources & ~0x0000000D) == 0);

	pEfc->EFC_FMR \|= sources;
	}

	//------------------------------------------------------------------------------
	/// Disables the given interrupt sources on an EFC peripheral.
	/// \param pEfc Pointer to an AT91S_EFC structure.
	/// \param sources Interrupt sources to disable.
	//------------------------------------------------------------------------------
	void EFC_DisableIt(AT91S_EFC *pEfc, unsigned int sources)
	{
	SANITY_CHECK(pEfc);
	SANITY_CHECK((sources & ~(AT91C_MC_FRDY \| AT91C_MC_LOCKE \| AT91C_MC_PROGE)) == 0);

	pEfc->EFC_FMR &= ~sources;
	}

	//------------------------------------------------------------------------------
	/// Enables or disable the "Erase before programming" feature of an EFC.
	/// \param pEfc Pointer to an AT91S_EFC structure.
	/// \param enable If 1, the feature is enabled; otherwise it is disabled.
	//------------------------------------------------------------------------------
	void EFC_SetEraseBeforeProgramming(AT91S_EFC *pEfc, unsigned char enable)
	{
	SANITY_CHECK(pEfc);

	if (enable) {

	pEfc->EFC_FMR &= ~AT91C_MC_NEBP;
	}
	else {

	pEfc->EFC_FMR \|= AT91C_MC_NEBP;
	}
	}

	//------------------------------------------------------------------------------
	/// Translates the given address into EFC, page and offset values. The resulting
	/// values are stored in the provided variables if they are not null.
	/// \param address Address to translate.
	/// \param ppEfc Pointer to target EFC peripheral.
	/// \param pPage First page accessed.
	/// \param pOffset Byte offset in first page.
	//------------------------------------------------------------------------------
	void EFC_TranslateAddress(
	unsigned int address,
	AT91S_EFC **ppEfc,
	unsigned short *pPage,
	unsigned short *pOffset)
	{
	AT91S_EFC *pEfc;
	unsigned short page;
	unsigned short offset;

	SANITY_CHECK(address >= AT91C_IFLASH);
	SANITY_CHECK(address <= (AT91C_IFLASH + AT91C_IFLASH_SIZE));

	#if defined(AT91C_BASE_EFC0)
	if (address >= (AT91C_IFLASH + AT91C_IFLASH_SIZE / 2)) {

	pEfc = AT91C_BASE_EFC1;
	page = (address - AT91C_IFLASH - AT91C_IFLASH_SIZE / 2) / AT91C_IFLASH_PAGE_SIZE;
	offset = (address - AT91C_IFLASH - AT91C_IFLASH_SIZE / 2) % AT91C_IFLASH_PAGE_SIZE;
	}
	else {

	pEfc = AT91C_BASE_EFC0;
	page = (address - AT91C_IFLASH) / AT91C_IFLASH_PAGE_SIZE;
	offset = (address - AT91C_IFLASH) % AT91C_IFLASH_PAGE_SIZE;
	}
	#else
	pEfc = AT91C_BASE_EFC;
	page = (address - AT91C_IFLASH) / AT91C_IFLASH_PAGE_SIZE;
	offset = (address - AT91C_IFLASH) % AT91C_IFLASH_PAGE_SIZE;
	#endif
	TRACE_DEBUG("Translated 0x%08X to EFC=0x%08X, page=%d and offset=%d\n\r",
	address, (unsigned int) pEfc, page, offset);

	// Store values
	if (ppEfc) {

	*ppEfc = pEfc;
	}
	if (pPage) {

	*pPage = page;
	}
	if (pOffset) {

	*pOffset = offset;
	}
	}

	//------------------------------------------------------------------------------
	/// Computes the address of a flash access given the EFC, page and offset.
	/// \param pEfc Pointer to an AT91S_EFC structure.
	/// \param page Page number.
	/// \param offset Byte offset inside page.
	/// \param pAddress Computed address (optional).
	//------------------------------------------------------------------------------
	void EFC_ComputeAddress(
	AT91S_EFC *pEfc,
	unsigned short page,
	unsigned short offset,
	unsigned int *pAddress)
	{
	unsigned int address;

	SANITY_CHECK(pEfc);
	#if defined(AT91C_BASE_EFC1)
	SANITY_CHECK(page <= (AT91C_IFLASH_NB_OF_PAGES / 2));
	#else
	SANITY_CHECK(page <= AT91C_IFLASH_NB_OF_PAGES);
	#endif
	SANITY_CHECK(offset < AT91C_IFLASH_PAGE_SIZE);

	// Compute address
	address = AT91C_IFLASH + page * AT91C_IFLASH_PAGE_SIZE + offset;
	#if defined(AT91C_BASE_EFC1)
	if (pEfc == AT91C_BASE_EFC1) {

	address += AT91C_IFLASH_SIZE / 2;
	}
	#endif

	// Store result
	if (pAddress) {

	*pAddress = address;
	}
	}

	//------------------------------------------------------------------------------
	/// Starts the executing the given command on an EFC. This function returns
	/// as soon as the command is started. It does NOT set the FMCN field automatically.
	/// \param pEfc Pointer to an AT91S_EFC structure.
	/// \param command Command to execute.
	/// \param argument Command argument (should be 0 if not used).
	//------------------------------------------------------------------------------
	#if defined(flash)
	#ifdef __ICCARM__
	__ramfunc
	#else
	__attribute__ ((section (".ramfunc")))
	#endif
	#endif
	void EFC_StartCommand(
	AT91S_EFC *pEfc,
	unsigned char command,
	unsigned short argument)
	{
	SANITY_CHECK(pEfc);
	ASSERT(lMck != 0, "-F- Master clock not set.\n\r");

	// Check command & argument
	switch (command) {

	case AT91C_MC_FCMD_PROG_AND_LOCK:
	ASSERT(0, "-F- Write and lock command cannot be carried out.\n\r");
	break;

	case AT91C_MC_FCMD_START_PROG:
	case AT91C_MC_FCMD_LOCK:
	case AT91C_MC_FCMD_UNLOCK:
	ASSERT(argument < AT91C_IFLASH_NB_OF_PAGES,
	"-F- Maximum number of pages is %d (argument was %d)\n\r",
	AT91C_IFLASH_NB_OF_PAGES,
	argument);
	break;

	#if (EFC_NUM_GPNVMS > 0)
	case AT91C_MC_FCMD_SET_GP_NVM:
	case AT91C_MC_FCMD_CLR_GP_NVM:
	ASSERT(argument < EFC_NUM_GPNVMS, "-F- A maximum of %d GPNVMs are available on the chip.\n\r", EFC_NUM_GPNVMS);
	break;
	#endif

	case AT91C_MC_FCMD_ERASE_ALL:

	#if !defined(EFC_NO_SECURITY_BIT)
	case AT91C_MC_FCMD_SET_SECURITY:
	#endif
	ASSERT(argument == 0, "-F- Argument is meaningless for the given command\n\r");
	break;

	default: ASSERT(0, "-F- Unknown command %d\n\r", command);
	}

	// Set FMCN
	switch (command) {

	case AT91C_MC_FCMD_LOCK:
	case AT91C_MC_FCMD_UNLOCK:
	#if (EFC_NUM_GPNVMS > 0)
	case AT91C_MC_FCMD_SET_GP_NVM:
	case AT91C_MC_FCMD_CLR_GP_NVM:
	#endif
	#if !defined(EFC_NO_SECURITY_BIT)
	case AT91C_MC_FCMD_SET_SECURITY:
	#endif
	pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) \| FMCN_BITS(lMck);
	break;

	case AT91C_MC_FCMD_START_PROG:
	case AT91C_MC_FCMD_ERASE_ALL:
	pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) \| FMCN_FLASH(lMck);
	break;
	}

	// Start command
	ASSERT((pEfc->EFC_FSR & AT91C_MC_FRDY) != 0, "-F- Efc is not ready\n\r");
	pEfc->EFC_FCR = (0x5A << 24) \| (argument << 8) \| command;
	}

	//------------------------------------------------------------------------------
	/// Performs the given command and wait until its completion (or an error).
	/// Returns 0 if successful; otherwise returns an error code.
	/// \param pEfc Pointer to an AT91S_EFC structure.
	/// \param command Command to perform.
	/// \param argument Optional command argument.
	//------------------------------------------------------------------------------
	#if defined(flash)
	#ifdef __ICCARM__
	__ramfunc
	#else
	__attribute__ ((section (".ramfunc")))
	#endif
	#endif
	unsigned char EFC_PerformCommand(
	AT91S_EFC *pEfc,
	unsigned char command,
	unsigned short argument)
	{
	unsigned int status;

	// Set FMCN
	switch (command) {

	case AT91C_MC_FCMD_LOCK:
	case AT91C_MC_FCMD_UNLOCK:
	#if (EFC_NUM_GPNVMS > 0)
	case AT91C_MC_FCMD_SET_GP_NVM:
	case AT91C_MC_FCMD_CLR_GP_NVM:
	#endif
	#if !defined(EFC_NO_SECURITY_BIT)
	case AT91C_MC_FCMD_SET_SECURITY:
	#endif
	pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) \| FMCN_BITS(lMck);
	break;

	case AT91C_MC_FCMD_START_PROG:
	case AT91C_MC_FCMD_ERASE_ALL:
	pEfc->EFC_FMR = (pEfc->EFC_FMR & ~AT91C_MC_FMCN) \| FMCN_FLASH(lMck);
	break;
	}

	#ifdef BOARD_FLASH_IAP_ADDRESS
	// Pointer on IAP function in ROM
	static void (*IAP_PerformCommand)(unsigned int, unsigned int);
	unsigned int index = 0;
	#ifdef AT91C_BASE_EFC1
	if (pEfc == AT91C_BASE_EFC1) {

	index = 1;
	}
	#endif
	IAP_PerformCommand = (void ()(unsigned int, unsigned int)) ((unsigned int *) BOARD_FLASH_IAP_ADDRESS);

	// Check if IAP function is implemented (opcode in SWI != 'b' or 'ldr') */
	if ((((((unsigned long) IAP_PerformCommand >> 24) & 0xFF) != 0xEA) &&
	(((unsigned long) IAP_PerformCommand >> 24) & 0xFF) != 0xE5)) {

	IAP_PerformCommand(index, (0x5A << 24) \| (argument << 8) \| command);
	return (pEfc->EFC_FSR & (AT91C_MC_LOCKE \| AT91C_MC_PROGE));
	}
	#endif

	pEfc->EFC_FCR = (0x5A << 24) \| (argument << 8) \| command;
	do {

	status = pEfc->EFC_FSR;
	}
	while ((status & AT91C_MC_FRDY) == 0);

	return (status & (AT91C_MC_PROGE \| AT91C_MC_LOCKE));
	}

	//------------------------------------------------------------------------------
	/// Returns the current status of an EFC. Keep in mind that this function clears
	/// the value of some status bits (LOCKE, PROGE).
	/// \param pEfc Pointer to an AT91S_EFC structure.
	//------------------------------------------------------------------------------
	unsigned int EFC_GetStatus(AT91S_EFC *pEfc)
	{
	return pEfc->EFC_FSR;
	}

	#endif //#ifdef BOARD_FLASH_EFC