int get_emmc_serial(char* Serial)
{
ioctl_diskinfo_t disk_info;
ioctl_diskrwpage_t bootCodeRead;
unsigned char readData[512];
int res;
int i;
if(DISK_Ioctl(DISK_DEVICE_TRIFLASH, DEV_GET_DISKINFO , (void*)&disk_info) <0)
return -1;
if(disk_info.sector_size != 512)
return -1;
bootCodeRead.start_page = BOOTSD_GetHeaderAddr();
bootCodeRead.rw_size = 1;
bootCodeRead.buff = readData;
res = DISK_Ioctl(DISK_DEVICE_TRIFLASH, DEV_BOOTCODE_READ_PAGE, (void*)&bootCodeRead);
if(res !=0) return -1;
for(i=0; i<16; i++)
Serial[i] = ((BOOTSD_Header_Info_T*)readData)->ucSerialNum[i];
for(i=16 ; i<32; i++)
Serial[i]= ((BOOTSD_Header_Info_T*)readData)->ucSerialNum[i+16];
return 0;
}
void emmc_boot_main()
{
ioctl_diskinfo_t disk_info;
dprintf(INFO , "%s:init start from eMMC\n" , __func__ );
SD_BUS_Initialize();
DISK_Ioctl(DISK_DEVICE_TRIFLASH , DEV_INITIALIZE , NULL);
DISK_Ioctl(DISK_DEVICE_TRIFLASH , DEV_GET_DISKINFO , (void*)&disk_info);
emmc_boot_read_MBR();
printpartition();
}
unsigned int emmc_boot_write(unsigned int data_len, unsigned int* data)
{
ioctl_diskrwpage_t rwHiddenPage;
dprintf(INFO, "boot write\n");
rwHiddenPage.start_page =0;
rwHiddenPage.rw_size = data_len / 512;
rwHiddenPage.hidden_index = 0;
rwHiddenPage.buff = (unsigned char*)data;
return DISK_Ioctl(DISK_DEVICE_TRIFLASH , DEV_HIDDEN_WRITE_PAGE, (void*)&rwHiddenPage);
}
void target_init(void)
{
ASSERT(NAND_MTD_PARTITION_NUM == num_parts);
unsigned offset;
unsigned total_num_of_blocks;
unsigned blocks_per_megabytes;
unsigned next_ptr_start_adr = 0;
int ret, i;
struct flash_info *flash_info;
bool start_addr_changed = false;
unsigned int nMTDReserved_Num=0; // total number of MTD Reserved Area
TNFTL_MTDBadBlkInfo MTDBadBlkInfo[num_parts];
/////////////////////////////////////////////////////////////////////////////////////////////
unsigned int nROAreaSize, nPartitionSize = 0;
unsigned int nBlockSize, nBlockSize_MB;
unsigned int nDevPBpV, nDevBBpZ, nDevBBpV, nRervRate;
unsigned int j, nUserDataArea = 0;
struct ptable sPartition_List;
memset( MTDBadBlkInfo, 0, sizeof(TNFTL_MTDBadBlkInfo) * num_parts );
dprintf(ALWAYS, "target_init()\n");
#if _EMMC_BOOT_TCC
PARTITION PartitionArr[50];
unsigned int nPartitionCnt = 0;
#endif
#ifdef TRIFLASH_INCLUDE
ioctl_diskinfo_t disk_info;
#endif
#if (!ENABLE_NANDWRITE)
#ifdef BOARD_TCC930X_STB_DEMO
#else
keys_init();
keypad_init();
#endif
#endif
if (target_is_emmc_boot())
{
#if _EMMC_BOOT_TCC
dprintf(INFO, "target_init() emmc_boot\n");
ptable_init(&flash_ptable);
//SDMMC init //MCC
DISK_Ioctl(DISK_DEVICE_TRIFLASH, DEV_INITIALIZE, NULL );
//get flash info? //MCC
DISK_Ioctl(DISK_DEVICE_TRIFLASH, DEV_GET_DISKINFO, (void *)&disk_info);
dprintf(INFO, "disk info: head: %d cylinder: %d sector : %d sector size: %d Total_sectors: %d \n",disk_info.head,disk_info.cylinder,disk_info.sector,disk_info.sector_size,disk_info.Total_sectors);
//ptabel init //MCC
// offset = flash_info->offset;
offset = 0; //fixme
// total_num_of_blocks = flash_info->num_blocks;
total_num_of_blocks=10000000; // fixme
memset(&PartitionArr, 0, sizeof(PARTITION) * 50);
nPartitionCnt = GetLocalPartition(0, PartitionArr);
for(i=0; i<nPartitionCnt; i++)
PrintPartitionInfo(&PartitionArr[i], i);
/* convert partition size to block unit */ //512byte ?
blocks_per_megabytes = 1024*1024 / (disk_info.sector_size);
ASSERT(blocks_per_megabytes);
for (i = 0; i < num_parts; i++) {
struct ptentry *ptn = &board_part_list[i];
if (ptn->length != VARIABLE_LENGTH)
ptn->length *= blocks_per_megabytes;
}
for (i = 0; i < num_parts; i++) {
struct ptentry *ptn = &board_part_list[i];
unsigned len = ptn->length;
if (ptn->start != DIFF_START_ADDR)
{
if(i==2)
{
ptn->start = PartitionArr[1].start;
}
else
{
ptn->start *= blocks_per_megabytes;
}
}
if (len == VARIABLE_LENGTH) {
start_addr_changed = true;
unsigned length_for_prt = ptn->start;
unsigned j;
for (j = i+1; j < num_parts; j++)
{
struct ptentry *temp_ptn = &board_part_list[j];
ASSERT(temp_ptn->length != VARIABLE_LENGTH);
length_for_prt += temp_ptn->length;
}
len = total_num_of_blocks - length_for_prt;
ASSERT(len >= 0);
next_ptr_start_adr = ptn->start + len;
}
if((ptn->start == DIFF_START_ADDR) && (start_addr_changed)) {
ASSERT(next_ptr_start_adr);
ptn->start = next_ptr_start_adr;
next_ptr_start_adr = ptn->start + ptn->length;
}
ptable_add(&flash_ptable, ptn->name, offset + ptn->start,
len, ptn->flags);
}
ptable_dump(&flash_ptable);
flash_set_ptable(&flash_ptable);
#endif
return;
}
if (flash_get_ptable() == NULL) {
ptable_init(&flash_ptable);
flash_set_partnum( num_parts );
flash_init();
flash_info = flash_get_info();
ASSERT(flash_info);
if ( (flash_info->num_blocks) && (!flash_check_table()) )
{
memcpy( sPartition_List.parts, board_part_list, sizeof( struct ptentry ) * num_parts );
nBlockSize = flash_info->page_size << flash_info->ShiftPpB; // Set Block Size ( Byte Size )
nROAreaSize = flash_info->num_blocks * nBlockSize; // Set Total ROArea Size ( Byte Size )
nBlockSize_MB = nBlockSize / ( 1 << 20 );
if( nBlockSize_MB > 1 ) // If Block is over the 1MB. Block must aligned.
{ // ex) Block Size 2MB, If Partition Size is 3MB. Partition Block Number must be 2. not 1.
if( nBlockSize_MB == 2 ) // If Block Size 2MB.
{
for( i = 0; i < num_parts; i++ )
{
if( sPartition_List.parts[i].length & 0x01 )
sPartition_List.parts[i].length++;
}
}
else if ( nBlockSize_MB == 4 ) // If Block Size 4MB
{
unsigned int nDiff_Val;
for( i = 0; i < num_parts; i++ )
{
nDiff_Val = sPartition_List.parts[i].length & 0x03;
if( nDiff_Val )
sPartition_List.parts[i].length += ( 4 - nDiff_Val );
}
}
}
flash_get_DevPBpV( &nDevPBpV, &nDevBBpZ, &nMTDReserved_Num );
nMTDReserved_Num = ( nMTDReserved_Num << 20 ) / nBlockSize;
nDevBBpV = ( nDevPBpV / 1024 ) * nDevBBpZ;
nRervRate = ( nMTDReserved_Num * 100 ) / nDevPBpV;
nDevBBpV = ( nDevBBpV * nRervRate ) / 100;
nRervRate = ( 100 / nRervRate );
nMTDReserved_Num = nRervRate + nDevBBpV; // Setup ROArea Reserved Block
if( nMTDReserved_Num & 0x01 )
nMTDReserved_Num++;
if( flash_info->ExtInterrupt == TRUE )
nMTDReserved_Num = nMTDReserved_Num << 1;
for( i = 0; i < num_parts; i++ )
{
if( sPartition_List.parts[i].length != VARIABLE_LENGTH )
{
sPartition_List.parts[i].length = sPartition_List.parts[i].length << 20; // Convert Length Unit. MByte -> Byte
nPartitionSize += sPartition_List.parts[i].length;
}
else
{
nUserDataArea = i;
}
}
sPartition_List.parts[nUserDataArea].length = nROAreaSize - nPartitionSize; // Calculate UserDataArea Size ( include Rerv Block )
sPartition_List.parts[nUserDataArea].length -= (nMTDReserved_Num * nBlockSize ); // UserDataArea Size. Reverved Block Removed
i = 1;
sPartition_List.parts[0].length /= nBlockSize; // Partition 0 Length ( Block Unit )
MTDBadBlkInfo[0].PartBlkNum = sPartition_List.parts[0].length; // Set Block Number Each Partition
do
{
sPartition_List.parts[i].length /= nBlockSize; // Partition i Length ( Block Unit )
sPartition_List.parts[i].start = sPartition_List.parts[i-1].start + sPartition_List.parts[i-1].length;
MTDBadBlkInfo[i].PartBlkNum = sPartition_List.parts[i].length; // Set Block Number Each Partition
++i;
} while( i < num_parts );
flash_set_rervnum( nMTDReserved_Num ); // Set Reserved Block Number
flash_set_badblkinfo( MTDBadBlkInfo ); // Set Bad Block Table Info. About Block Number Each Partition
for( i = 0; i < num_parts; i++ )
{
ptable_add(&flash_ptable, sPartition_List.parts[i].name, flash_info->offset + sPartition_List.parts[i].start,
sPartition_List.parts[i].length, sPartition_List.parts[i].flags);
}
ND_TRACE("\n-------------- [ Partition Table ] --------------\n");
for( i = 0; i < num_parts; i++ )
{
ND_TRACE(" [Part %2d.%9s] [Start:%4d] [Length:%4d]\n", i, sPartition_List.parts[i].name ,sPartition_List.parts[i].start + flash_info->offset, sPartition_List.parts[i].length );
}
ND_TRACE("-------------------------------------------------\n");
dprintf(INFO, "[NAND ] [Maker:0x%02x ][Device:0x%02x][Page_size:%d]\n",
flash_info->vendor, flash_info->device, flash_info->page_size);
dprintf(INFO, " [Spare_Size:%d][Block_Size:%d][MTD_Block:%d][Rerv_Block:%d]\n",
flash_info->spare_size, flash_info->block_size, flash_info->num_blocks - (U32)nMTDReserved_Num, (U32)nMTDReserved_Num);
//ptable_dump(&flash_ptable);
flash_set_ptable(&flash_ptable);
ret = flash_set_badblktable();
if( ret != SUCCESS )
{
dprintf(INFO, " !!! Fail Create Bad Block Table. [func:%s] [line:%d] !!! \n", __func__, __LINE__ );
ASSERT(-1);
}
flash_set_tablestatus(TRUE);
}
}
}
