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/* ----------------------------------------------------------------------------
* ATMEL Microcontroller Software Support
* ----------------------------------------------------------------------------
* Copyright (c) 2009, 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 "flashd.h"
#include <board.h>
#if !defined (CHIP_FLASH_EEFC)
#error eefc not supported
#endif
#include <eefc/eefc.h>
#include <utility/math.h>
#include <utility/assert.h>
#include <utility/trace.h>
#include <string.h>
//------------------------------------------------------------------------------
// Local constants
//------------------------------------------------------------------------------
#if defined(AT91C_BASE_EFC) && !defined(AT91C_BASE_EFC0)
#define AT91C_BASE_EFC0 AT91C_BASE_EFC
#endif
//------------------------------------------------------------------------------
// Local functions
//------------------------------------------------------------------------------
//------------------------------------------------------------------------------
/// Computes the lock range associated with the given address range.
/// \param start Start address of lock range.
/// \param end End address of lock range.
/// \param pActualStart Actual start address of lock range.
/// \param pActualEnd Actual end address of lock range.
//------------------------------------------------------------------------------
static void ComputeLockRange(
unsigned int start,
unsigned int end,
unsigned int *pActualStart,
unsigned int *pActualEnd)
{
AT91S_EFC *pStartEfc, *pEndEfc;
unsigned short startPage, endPage;
unsigned short numPagesInRegion;
unsigned short actualStartPage, actualEndPage;
// Convert start and end address in page numbers
EFC_TranslateAddress(&pStartEfc, start, &startPage, 0);
EFC_TranslateAddress(&pEndEfc, end, &endPage, 0);
// Find out the first page of the first region to lock
numPagesInRegion = AT91C_IFLASH_LOCK_REGION_SIZE / AT91C_IFLASH_PAGE_SIZE;
actualStartPage = startPage - (startPage % numPagesInRegion);
actualEndPage = endPage;
if ((endPage % numPagesInRegion) != 0) {
actualEndPage += numPagesInRegion - (endPage % numPagesInRegion);
}
// Store actual page numbers
EFC_ComputeAddress(pStartEfc, actualStartPage, 0, pActualStart);
EFC_ComputeAddress(pEndEfc, actualEndPage, 0, pActualEnd);
TRACE_DEBUG("Actual lock range is 0x%06X - 0x%06X\n\r", *pActualStart, *pActualEnd);
}
//------------------------------------------------------------------------------
// Global functions
//------------------------------------------------------------------------------
//------------------------------------------------------------------------------
/// Initializes the flash driver.
/// \param mck Master clock frequency in Hz.
//------------------------------------------------------------------------------
void FLASHD_Initialize(unsigned int mck)
{
EFC_DisableFrdyIt(AT91C_BASE_EFC0);
#ifdef AT91C_BASE_EFC1
EFC_DisableFrdyIt(AT91C_BASE_EFC1);
#endif
}
//------------------------------------------------------------------------------
/// Erases the entire flash.
/// Returns 0 if successful; otherwise returns an error code.
//------------------------------------------------------------------------------
unsigned char FLASHD_Erase(unsigned int address)
{
AT91S_EFC *pEfc;
unsigned short page;
unsigned short offset;
unsigned char error;
#ifdef AT91C_BASE_EFC1
// Convert wrapped address to physical address.
address &= 0x19FFFF;
SANITY_CHECK((address >=AT91C_IFLASH) || (address >=AT91C_IFLASH1));
// Check EFC crossover 2 bank
if (address >=AT91C_IFLASH1) {
SANITY_CHECK(address <= (AT91C_IFLASH1 + AT91C_IFLASH1_SIZE));
}
else {
SANITY_CHECK(address <= (AT91C_IFLASH + AT91C_IFLASH_SIZE));
}
#else
SANITY_CHECK((address >=AT91C_IFLASH) || (address <= (AT91C_IFLASH + AT91C_IFLASH_SIZE)));
#endif
// Translate write address
EFC_TranslateAddress(&pEfc, address, &page, &offset);
error = EFC_PerformCommand(pEfc, AT91C_EFC_FCMD_EA, 0);
return error;
}
static unsigned char pPageBuffer[AT91C_IFLASH_PAGE_SIZE];
//------------------------------------------------------------------------------
/// Writes a data buffer in the internal flash. This function works in polling
/// mode, and thus only returns when the data has been effectively written.
/// Returns 0 if successful; otherwise returns an error code.
/// \param address Write address.
/// \param pBuffer Data buffer.
/// \param size Size of data buffer in bytes.
//------------------------------------------------------------------------------
unsigned char FLASHD_Write(
unsigned int address,
const void *pBuffer,
unsigned int size)
{
AT91S_EFC *pEfc;
unsigned short page;
unsigned short offset;
unsigned int writeSize;
unsigned int pageAddress;
unsigned short padding;
unsigned char error;
unsigned int sizeTmp;
unsigned int *pAlignedDestination;
unsigned int *pAlignedSource;
SANITY_CHECK(pBuffer);
#ifdef AT91C_BASE_EFC1
// Convert wrapped address to physical address.
address &= 0x19FFFF;
SANITY_CHECK((address >=AT91C_IFLASH) || (address >=AT91C_IFLASH1));
// Check EFC crossover 2 bank
if (address >=AT91C_IFLASH1) {
SANITY_CHECK((address + size) <= (AT91C_IFLASH1 + AT91C_IFLASH1_SIZE));
}
else {
SANITY_CHECK((address + size) <= (AT91C_IFLASH + AT91C_IFLASH_SIZE));
}
#else
SANITY_CHECK(address >=AT91C_IFLASH);
SANITY_CHECK((address + size) <= (AT91C_IFLASH + AT91C_IFLASH_SIZE));
#endif
// Translate write address
EFC_TranslateAddress(&pEfc, address, &page, &offset);
// Write all pages
while (size > 0) {
// Copy data in temporary buffer to avoid alignment problems
writeSize = min(AT91C_IFLASH_PAGE_SIZE - offset, size);
EFC_ComputeAddress(pEfc, page, 0, &pageAddress);
padding = AT91C_IFLASH_PAGE_SIZE - offset - writeSize;
// Pre-buffer data
memcpy(pPageBuffer, (void *) pageAddress, offset);
// Buffer data
memcpy(pPageBuffer + offset, pBuffer, writeSize);
// Post-buffer data
memcpy(pPageBuffer + offset + writeSize, (void *) (pageAddress + offset + writeSize), padding);
// Write page
// Writing 8-bit and 16-bit data is not allowed
// and may lead to unpredictable data corruption
pAlignedDestination = (unsigned int*)pageAddress;
pAlignedSource = (unsigned int*)pPageBuffer;
sizeTmp = AT91C_IFLASH_PAGE_SIZE;
while (sizeTmp >= 4) {
*pAlignedDestination++ = *pAlignedSource++;
sizeTmp -= 4;
}
// Send writing command
error = EFC_PerformCommand(pEfc, AT91C_EFC_FCMD_EWP, page);
if (error) {
return error;
}
// Progression
address += AT91C_IFLASH_PAGE_SIZE;
pBuffer = (void *) ((unsigned int) pBuffer + writeSize);
size -= writeSize;
page++;
offset = 0;
}
return 0;
}
//------------------------------------------------------------------------------
/// Locks all the regions in the given address range. The actual lock range is
/// reported through two output parameters.
/// Returns 0 if successful; otherwise returns an error code.
/// \param start Start address of lock range.
/// \param end End address of lock range.
/// \param pActualStart Start address of the actual lock range (optional).
/// \param pActualEnd End address of the actual lock range (optional).
//------------------------------------------------------------------------------
unsigned char FLASHD_Lock(
unsigned int start,
unsigned int end,
unsigned int *pActualStart,
unsigned int *pActualEnd)
{
AT91S_EFC *pEfc;
unsigned int actualStart, actualEnd;
unsigned short startPage, endPage;
unsigned char error;
unsigned short numPagesInRegion = AT91C_IFLASH_LOCK_REGION_SIZE / AT91C_IFLASH_PAGE_SIZE;
// Compute actual lock range and store it
ComputeLockRange(start, end, &actualStart, &actualEnd);
if (pActualStart) {
*pActualStart = actualStart;
}
if (pActualEnd) {
*pActualEnd = actualEnd;
}
// Compute page numbers
EFC_TranslateAddress(&pEfc, actualStart, &startPage, 0);
EFC_TranslateAddress(0, actualEnd, &endPage, 0);
// Lock all pages
while (startPage < endPage) {
error = EFC_PerformCommand(pEfc, AT91C_EFC_FCMD_SLB, startPage);
if (error) {
return error;
}
startPage += numPagesInRegion;
}
return 0;
}
//------------------------------------------------------------------------------
/// Unlocks all the regions in the given address range. The actual unlock range is
/// reported through two output parameters.
/// Returns 0 if successful; otherwise returns an error code.
/// \param start Start address of unlock range.
/// \param end End address of unlock range.
/// \param pActualStart Start address of the actual unlock range (optional).
/// \param pActualEnd End address of the actual unlock range (optional).
//------------------------------------------------------------------------------
unsigned char FLASHD_Unlock(
unsigned int start,
unsigned int end,
unsigned int *pActualStart,
unsigned int *pActualEnd)
{
AT91S_EFC *pEfc;
unsigned int actualStart, actualEnd;
unsigned short startPage, endPage;
unsigned char error;
unsigned short numPagesInRegion = AT91C_IFLASH_LOCK_REGION_SIZE / AT91C_IFLASH_PAGE_SIZE;
// Compute actual unlock range and store it
ComputeLockRange(start, end, &actualStart, &actualEnd);
if (pActualStart) {
*pActualStart = actualStart;
}
if (pActualEnd) {
*pActualEnd = actualEnd;
}
// Compute page numbers
EFC_TranslateAddress(&pEfc, actualStart, &startPage, 0);
EFC_TranslateAddress(0, actualEnd, &endPage, 0);
// Unlock all pages
while (startPage < endPage) {
error = EFC_PerformCommand(pEfc, AT91C_EFC_FCMD_CLB, startPage);
if (error) {
return error;
}
startPage += numPagesInRegion;
}
return 0;
}
//------------------------------------------------------------------------------
/// Returns the number of locked regions inside the given address range.
/// \param start Start address of range.
/// \param end End address of range.
//------------------------------------------------------------------------------
unsigned char FLASHD_IsLocked(unsigned int start, unsigned int end)
{
AT91S_EFC *pEfc;
unsigned short startPage, endPage;
unsigned char startRegion, endRegion;
unsigned int numPagesInRegion;
unsigned int status;
unsigned char error;
unsigned int numLockedRegions = 0;
SANITY_CHECK(end >= start);
#ifdef AT91C_BASE_EFC1
// Convert wrapped address to physical address.
start &= 0x19FFFF;
end &= 0x19FFFF;
// Check EFC crossover 2 bank
SANITY_CHECK(((start >=AT91C_IFLASH) && (end <= AT91C_IFLASH + AT91C_IFLASH_SIZE))
|| ((start >=AT91C_IFLASH1) && (end <= AT91C_IFLASH1 + AT91C_IFLASH1_SIZE)));
#else
SANITY_CHECK((start >=AT91C_IFLASH) && (end <= AT91C_IFLASH + AT91C_IFLASH_SIZE));
#endif
// Compute page numbers
EFC_TranslateAddress(&pEfc, start, &startPage, 0);
EFC_TranslateAddress(0, end, &endPage, 0);
// Compute region numbers
numPagesInRegion = AT91C_IFLASH_LOCK_REGION_SIZE / AT91C_IFLASH_PAGE_SIZE;
startRegion = startPage / numPagesInRegion;
endRegion = endPage / numPagesInRegion;
if ((endPage % numPagesInRegion) != 0) {
endRegion++;
}
// Retrieve lock status
error = EFC_PerformCommand(pEfc, AT91C_EFC_FCMD_GLB, 0);
ASSERT(!error, "-F- Error while trying to fetch lock bits status (0x%02X)\n\r", error);
status = EFC_GetResult(pEfc);
// Check status of each involved region
while (startRegion < endRegion) {
if ((status & (1 << startRegion)) != 0) {
numLockedRegions++;
}
startRegion++;
}
return numLockedRegions;
}
//------------------------------------------------------------------------------
/// Returns 1 if the given GPNVM bit is currently set; otherwise returns 0.
/// \param gpnvm GPNVM bit index.
//------------------------------------------------------------------------------
unsigned char FLASHD_IsGPNVMSet(unsigned char gpnvm)
{
unsigned char error;
unsigned int status;
SANITY_CHECK(gpnvm < CHIP_EFC_NUM_GPNVMS);
// Get GPNVMs status
error = EFC_PerformCommand(AT91C_BASE_EFC, AT91C_EFC_FCMD_GFB, 0);
ASSERT(!error, "-F- Error while trying to fetch GPNVMs status (0x%02X)\n\r", error);
status = EFC_GetResult(AT91C_BASE_EFC);
// Check if GPNVM is set
if ((status & (1 << gpnvm)) != 0) {
return 1;
}
else {
return 0;
}
}
//------------------------------------------------------------------------------
/// Sets the selected GPNVM bit.
/// Returns 0 if successful; otherwise returns an error code.
/// \param gpnvm GPNVM index.
//------------------------------------------------------------------------------
unsigned char FLASHD_SetGPNVM(unsigned char gpnvm)
{
SANITY_CHECK(gpnvm < CHIP_EFC_NUM_GPNVMS);
if (!FLASHD_IsGPNVMSet(gpnvm)) {
return EFC_PerformCommand(AT91C_BASE_EFC, AT91C_EFC_FCMD_SFB, gpnvm);
}
else {
return 0;
}
}
//------------------------------------------------------------------------------
/// Clears the selected GPNVM bit.
/// Returns 0 if successful; otherwise returns an error code.
/// \param gpnvm GPNVM index.
//------------------------------------------------------------------------------
unsigned char FLASHD_ClearGPNVM(unsigned char gpnvm)
{
SANITY_CHECK(gpnvm < CHIP_EFC_NUM_GPNVMS);
if (FLASHD_IsGPNVMSet(gpnvm)) {
return EFC_PerformCommand(AT91C_BASE_EFC, AT91C_EFC_FCMD_CFB, gpnvm);
}
else {
return 0;
}
}
//------------------------------------------------------------------------------
/// Read the unique ID.
/// Returns 0 if successful; otherwise returns an error code.
/// \param uniqueID pointer on a 4bytes char containing the unique ID value.
//------------------------------------------------------------------------------
#ifdef AT91C_EFC_FCMD_STUI
__attribute__ ((section (".ramfunc")))
unsigned char FLASHD_ReadUniqueID (unsigned long * uniqueID)
{
unsigned char error;
AT91S_EFC *pEfc = AT91C_BASE_EFC0;
SANITY_CHECK(uniqueID != NULL);
uniqueID[0] = 0;
uniqueID[1] = 0;
uniqueID[2] = 0;
uniqueID[3] = 0;
/* SAM3U Errata 46.2.1.4 */
pEfc->EFC_FMR |= (1 << 16);
EFC_StartCommand(AT91C_BASE_EFC, AT91C_EFC_FCMD_STUI, 0);
uniqueID[0] = *(unsigned int *)AT91C_IFLASH;
uniqueID[1] = *(unsigned int *)(AT91C_IFLASH + 4);
uniqueID[2] = *(unsigned int *)(AT91C_IFLASH + 8);
uniqueID[3] = *(unsigned int *)(AT91C_IFLASH + 12);
error = EFC_PerformCommand(AT91C_BASE_EFC, AT91C_EFC_FCMD_SPUI, 0);
/* SAM3U Errata 46.2.1.4 */
pEfc->EFC_FMR &= ~(1 << 16);
if (error) return error;
return 0;
}
#endif
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