void target_init(void) { unsigned offset; struct flash_info *flash_info; int i; dprintf(INFO, "target_init()\n"); keys_init(); keypad_init(); ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) offset = BOARD_FLASH_OFFSET; for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; unsigned len = ptn->length; if ((len == 0) && (i == num_parts - 1)) len = flash_info->num_blocks - offset - ptn->start; ptable_add(&flash_ptable, ptn->name, offset + ptn->start, len, ptn->flags); } ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); }
void target_init(void) { struct flash_info *flash_info; dprintf(INFO, "target_init()\n"); /* Initialize PMIC driver */ pmic.read = (pm8921_read_func) & pa1_ssbi2_read_bytes; pmic.write = (pm8921_write_func) & pa1_ssbi2_write_bytes; pm8921_init(&pmic); ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); smem_add_modem_partitions(&flash_ptable); /* Update the naming for apps partitions and type */ update_ptable_apps_partitions(); /* Update modem partitions to lower case for fastboot */ update_ptable_modem_partitions(); ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); }
void target_init(void) { struct ptentry *ptn; unsigned offset; dprintf(INFO, "target_init()\n"); keys_init(); keypad_init(); ptable_init(&flash_ptable); smem_ptable_init(); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) offset = BOARD_FLASH_OFFSET; for (ptn = &board_part_list[0]; ptn->name[0]; ptn++) { ptable_add(&flash_ptable, ptn->name, offset + ptn->start, ptn->length, ptn->flags); } ptable_dump(&flash_ptable); flash_init(&flash_ptable); }
void target_reinit(int option) { #if defined(NAND_BOOT_INCLUDE) #if defined(TNFTL_V8_INCLUDE) target_init(); #else unsigned offset; struct flash_info *flash_info; int ret, i; dprintf(INFO, "target_reinit()\n"); if (flash_get_ptable() == NULL) { target_init(); return; } flash_init_ptable(); ptable_init(&flash_ptable); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); if (flash_info->num_blocks) { offset = flash_info->offset; // TODO //dprintf(INFO, "offset: %d\n", offset); for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; dprintf(INFO, "offset: %d ptn->start: %d\n", offset, ptn->start ); ptable_add(&flash_ptable, ptn->name, offset + ptn->start, ptn->length, ptn->flags); } ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); ret = flash_set_badblktable(); ASSERT( ret == SUCCESS ); } #endif #endif }
void target_init(void) { unsigned offset; struct flash_info *flash_info; int i; dprintf(INFO, "target_init()\n"); #if (!ENABLE_NANDWRITE) keys_init(); keypad_init(); #endif if (target_is_emmc_boot()) return; ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) while(1); for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; unsigned len = ptn->length; if ((len == 0) && (i == num_parts - 1)) len = flash_info->num_blocks - offset - ptn->start; ptable_add(&flash_ptable, ptn->name, offset + ptn->start, len, ptn->flags); } ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); }
void target_init(void) { unsigned offset; struct flash_info *flash_info; struct ptentry *board_part_list; unsigned total_num_of_blocks; unsigned next_ptr_start_adr = 0; unsigned blocks_per_1MB = 8; /* Default value of 2k page size on 256MB flash drive*/ int i; dprintf(INFO, "target_init()\n"); #if (!ENABLE_NANDWRITE) keys_init(); keypad_init(); #endif /* Display splash screen if enabled */ #if DISPLAY_SPLASH_SCREEN display_init(); dprintf(SPEW, "Diplay initialized\n"); display_image_on_screen(); #endif if (target_is_emmc_boot()) { /* Must wait for modem-up before we can intialize MMC. */ while (readl(MSM_SHARED_BASE + 0x14) != 1); if(mmc_boot_main(MMC_SLOT, MSM_SDC3_BASE)) { dprintf(CRITICAL, "mmc init failed!"); ASSERT(0); } return; } ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) while(1); total_num_of_blocks = flash_info->num_blocks; blocks_per_1MB = (1 << 20) / (flash_info->block_size); if (flash_ecc_bch_enabled()) board_part_list = board_part_list_bchecc; else board_part_list = board_part_list_default; for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; unsigned len = ((ptn->length) * blocks_per_1MB); if(ptn->start != 0) ASSERT(ptn->start == DIFF_START_ADDR); ptn->start = next_ptr_start_adr; if(ptn->length == VARIABLE_LENGTH) { unsigned length_for_prt = 0; 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) * blocks_per_1MB); } len = (total_num_of_blocks - 1) - (offset + ptn->start + length_for_prt); ASSERT(len >= 0); } next_ptr_start_adr = ptn->start + len; ptable_add(&flash_ptable, ptn->name, offset + ptn->start, len, ptn->flags, TYPE_APPS_PARTITION, PERM_WRITEABLE); } smem_add_modem_partitions(&flash_ptable); ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); }
void target_init(void) { unsigned offset; struct flash_info *flash_info; unsigned total_num_of_blocks; unsigned next_ptr_start_adr = 0; unsigned blocks_per_1MB = 8; /* Default value of 2k page size on 256MB flash drive*/ unsigned base_addr; unsigned char slot; int i; dprintf(INFO, "target_init()\n"); #if (!ENABLE_NANDWRITE) keys_init(); keypad_init(); #endif if (target_is_emmc_boot()) { /* Trying Slot 2 first */ slot = 2; base_addr = mmc_sdc_base[slot-1]; if(mmc_boot_main(slot, base_addr)) { /* Trying Slot 4 next */ slot = 4; base_addr = mmc_sdc_base[slot-1]; if(mmc_boot_main(slot, base_addr)) { dprintf(CRITICAL, "mmc init failed!"); ASSERT(0); } } return; } ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); enable_interleave_mode(target_is_interleaved_mode()); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) while(1); total_num_of_blocks = flash_info->num_blocks; blocks_per_1MB = (1 << 20) / (flash_info->block_size); for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; unsigned len = ((ptn->length) * blocks_per_1MB); if(ptn->start != 0) ASSERT(ptn->start == DIFF_START_ADDR); ptn->start = next_ptr_start_adr; if(ptn->length == VARIABLE_LENGTH) { unsigned length_for_prt = 0; 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) * blocks_per_1MB); } len = (total_num_of_blocks - 1) - (offset + ptn->start + length_for_prt); ASSERT(len >= 0); } next_ptr_start_adr = ptn->start + len; if(target_is_interleaved_mode()) { ptable_add(&flash_ptable, ptn->name, offset + (ptn->start / 2), (len / 2), ptn->flags, TYPE_APPS_PARTITION, PERM_WRITEABLE); } else { ptable_add(&flash_ptable, ptn->name, offset + ptn->start, len, ptn->flags, TYPE_APPS_PARTITION, PERM_WRITEABLE); } } smem_add_modem_partitions(&flash_ptable); ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); }
void target_init(void) { unsigned offset; struct flash_info *flash_info; unsigned total_num_of_blocks; bool start_addr_changed = false; unsigned next_ptr_start_adr = 0; int i; dprintf(INFO, "target_init()\n"); #if (!ENABLE_NANDWRITE) keys_init(); keypad_init(); #endif if (target_is_emmc_boot()) return; ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) while(1); total_num_of_blocks = (flash_info->block_size)/NUM_PAGES_PER_BLOCK; for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; unsigned len = ptn->length; if(len == VARIABLE_LENGTH) { start_addr_changed = true; unsigned length_for_prt = 0; 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 - 1) - (offset + ptn->start + 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); }
void target_init(void) { unsigned offset; struct flash_info *flash_info; unsigned total_num_of_blocks; unsigned next_ptr_start_adr = 0; unsigned blocks_per_1MB = 8; /* Default value of 2k page size on 256MB flash drive*/ int i; dprintf(INFO, "target_init()\n"); #if (!ENABLE_NANDWRITE) keys_init(); keypad_init(); #endif if (target_is_emmc_boot()) return; ptable_init(&flash_ptable); smem_ptable_init(); flash_init(); flash_info = flash_get_info(); ASSERT(flash_info); offset = smem_get_apps_flash_start(); if (offset == 0xffffffff) while(1); total_num_of_blocks = flash_info->num_blocks; blocks_per_1MB = (1 << 20) / (flash_info->block_size); for (i = 0; i < num_parts; i++) { struct ptentry *ptn = &board_part_list[i]; unsigned len = ((ptn->length) * blocks_per_1MB); if(ptn->start != 0) ASSERT(ptn->start == DIFF_START_ADDR); ptn->start = next_ptr_start_adr; if(ptn->length == VARIABLE_LENGTH) { unsigned length_for_prt = 0; 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) * blocks_per_1MB); } len = (total_num_of_blocks - 1) - (offset + ptn->start + length_for_prt); ASSERT(len >= 0); } next_ptr_start_adr = ptn->start + len; ptable_add(&flash_ptable, ptn->name, offset + ptn->start, len, ptn->flags, TYPE_APPS_PARTITION, PERM_WRITEABLE); } smem_add_modem_partitions(&flash_ptable); ptable_dump(&flash_ptable); flash_set_ptable(&flash_ptable); }
static void zybo_common_target_init(uint level) { status_t err; /* zybo has a spiflash on qspi */ spiflash_detect(); bdev_t *spi = bio_open("spi0"); if (spi) { /* find or create a partition table at the start of flash */ if (ptable_scan(spi, 0) < 0) { ptable_create_default(spi, 0); } struct ptable_entry entry = { 0 }; /* find and recover sysparams */ if (ptable_find("sysparam", &entry) < 0) { /* didn't find sysparam partition, create it */ ptable_add("sysparam", 0x1000, 0x1000, 0); ptable_find("sysparam", &entry); } if (entry.length > 0) { sysparam_scan(spi, entry.offset, entry.length); #if SYSPARAM_ALLOW_WRITE /* for testing purposes, put at least one sysparam value in */ if (sysparam_add("dummy", "value", sizeof("value")) >= 0) { sysparam_write(); } #endif sysparam_dump(true); } /* create bootloader partition if it does not exist */ ptable_add("bootloader", 0x20000, 0x40000, 0); printf("flash partition table:\n"); ptable_dump(); } /* recover boot arguments */ const char *cmdline = bootargs_get_command_line(); if (cmdline) { printf("command line: '%s'\n", cmdline); } /* see if we came from a bootimage */ uintptr_t bootimage_phys; size_t bootimage_size; if (bootargs_get_bootimage_pointer(&bootimage_phys, &bootimage_size) >= 0) { printf("our bootimage is at phys 0x%lx, size %zx\n", bootimage_phys, bootimage_size); void *ptr = paddr_to_kvaddr(bootimage_phys); if (ptr) { bootimage_t *bi; if (bootimage_open(ptr, bootimage_size, &bi) >= 0) { /* we have a valid bootimage, find the fpga section */ const void *fpga_ptr; size_t fpga_len; if (bootimage_get_file_section(bi, TYPE_FPGA_IMAGE, &fpga_ptr, &fpga_len) >= 0) { /* we have a fpga image */ /* lookup the physical address of the bitfile */ paddr_t pa = kvaddr_to_paddr((void *)fpga_ptr); if (pa != 0) { /* program the fpga with it*/ printf("loading fpga image at %p (phys 0x%lx), len %zx\n", fpga_ptr, pa, fpga_len); zynq_reset_fpga(); err = zynq_program_fpga(pa, fpga_len); if (err < 0) { printf("error %d loading fpga\n", err); } printf("fpga image loaded\n"); } } } } } #if WITH_LIB_MINIP /* pull some network stack related params out of the sysparam block */ uint8_t mac_addr[6]; uint32_t ip_addr = IPV4_NONE; uint32_t ip_mask = IPV4_NONE; uint32_t ip_gateway = IPV4_NONE; if (sysparam_read("net0.mac_addr", mac_addr, sizeof(mac_addr)) < (ssize_t)sizeof(mac_addr)) { /* couldn't find eth address, make up a random one */ for (size_t i = 0; i < sizeof(mac_addr); i++) { mac_addr[i] = rand() & 0xff; } /* unicast and locally administered */ mac_addr[0] &= ~(1<<0); mac_addr[0] |= (1<<1); } uint8_t use_dhcp = 0; sysparam_read("net0.use_dhcp", &use_dhcp, sizeof(use_dhcp)); sysparam_read("net0.ip_addr", &ip_addr, sizeof(ip_addr)); sysparam_read("net0.ip_mask", &ip_mask, sizeof(ip_mask)); sysparam_read("net0.ip_gateway", &ip_gateway, sizeof(ip_gateway)); minip_set_macaddr(mac_addr); gem_set_macaddr(mac_addr); if (!use_dhcp && ip_addr != IPV4_NONE) { minip_init(gem_send_raw_pkt, NULL, ip_addr, ip_mask, ip_gateway); } else { /* Configure IP stack and hook to the driver */ minip_init_dhcp(gem_send_raw_pkt, NULL); } gem_set_callback(minip_rx_driver_callback); #endif }
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); } } }