/* * * (C) Copyright 2015 Phytec Messtechnik GmbH * Author: Daniel Schultz * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ #include #include #include #include #include #include #include #define EXT_CSD_BLOCKSIZE 512 /* Access types */ #define R "R" #define RW "R/W" #define RWaR "R/W & R" #define RWaRWE "R/W & R/W/E" #define RWaRWC_P "R/W & R/W/C_P" #define RWaRWC_PaRWE_P "R/W, R/W/C_P & R/W/E_P" #define WE "W/E" #define RWE "R/W/E" #define RWEaR "R/W/E & R" #define RWEaRWE_P "R/W/E & R/W/E_P" #define RWC_P "R/W/C_P" #define RWE_P "R/W/E_P" #define WE_P "W/E_P" #define print_field_caption(reg_name, access_mode) \ do { \ printf(#reg_name"[%u]:\n", EXT_CSD_##reg_name); \ printf("\tValue: %#02x\n", reg[index]); \ printf("\tAccess: "access_mode"\n"); \ } while (false); #define print_field_caption_with_offset(reg_name, offset, access_mode) \ do { \ printf(#reg_name"[%u]:\n", EXT_CSD_##reg_name + offset); \ printf("\tValue: %#02x\n", reg[index]); \ printf("\tAccess: "access_mode"\n"); \ } while (false); #define get_field_val(reg_name, offset, mask) \ ((reg[EXT_CSD_##reg_name] >> offset) & mask) #define get_field_val_with_index(index, offset, mask) \ ((reg[index] >> offset) & mask) static void print_access_type_key(void) { printf("\nR:\tRead only\n" "W:\tOne time programmable\n" "E:\tMultiple programmable\n" "C_P:\tValue cleared by power failure\n" "E_P:\tValue cleared by power failure and CMD0\n"); } static int print_field_ge_v7(u8 *reg, int index) { int rev; u32 val; u32 tmp; u64 tmp64; char *str = NULL; rev = reg[EXT_CSD_REV]; switch (index) { case EXT_CSD_CMDQ_MODE_EN: print_field_caption(CMDQ_MODE_EN, RWE_P); val = get_field_val(CMDQ_MODE_EN, 0, 0x1); printf("\tCommand queuing is %sabled\n", val ? "en" : "dis"); return 1; case EXT_CSD_SECURE_REMOVAL_TYPE: print_field_caption(SECURE_REMOVAL_TYPE, RWaR); val = get_field_val(SECURE_REMOVAL_TYPE, 0, 0xF); switch (val) { case 0x0: str = "erase"; break; case 0x1: str = "overwrite, then erase"; break; case 0x2: str = "overwrite, complement, then random"; break; case 0x3: str = "vendor defined"; break; } printf("\t[3-0] Supported Secure Removal Type: %s\n", str); val = get_field_val(SECURE_REMOVAL_TYPE, 4, 0xF); switch (val) { case 0x0: str = "erase"; break; case 0x1: str = "overwrite, then erase"; break; case 0x2: str = "overwrite, complement, then random"; break; case 0x3: str = "vendor defined"; break; } printf("\t[7-4] Configure Secure Removal Type: %s\n", str); return 1; case EXT_CSD_PRODUCT_ST8_AWARENSS_ENABLEMENT: print_field_caption(PRODUCT_ST8_AWARENSS_ENABLEMENT, RWEaR); val = get_field_val(PRODUCT_ST8_AWARENSS_ENABLEMENT, 0, 0x1); printf("\t[0] Manual mode is %ssupported\n", val ? "" : "not "); val = get_field_val(PRODUCT_ST8_AWARENSS_ENABLEMENT, 1, 0x1); printf("\t[1] Auto mode is %ssupported\n", (val ? "" : "not ")); val = get_field_val(PRODUCT_ST8_AWARENSS_ENABLEMENT, 4, 0x1); printf("\t[4] Production State Awareness is %sabled\n", val ? "en" : "dis"); val = get_field_val(PRODUCT_ST8_AWARENSS_ENABLEMENT, 5, 0x1); printf("\t[5] Auto mode is %sabled\n", (val ? "en" : "dis")); return 1; /* EXT_CSD_MAX_PRE_LOADING_DATA_SIZE */ case 25: case 24: case 23: case 22: print_field_caption_with_offset(MAX_PRE_LOADING_DATA_SIZE, index - EXT_CSD_MAX_PRE_LOADING_DATA_SIZE, R); tmp64 = get_field_val(MAX_PRE_LOADING_DATA_SIZE, 0, 0xFF); tmp64 = tmp64 | get_field_val( MAX_PRE_LOADING_DATA_SIZE + 1, 0, 0xFF) << 8; tmp64 = tmp64 | get_field_val( MAX_PRE_LOADING_DATA_SIZE + 2, 0, 0xFF) << 16; tmp64 = tmp64 | get_field_val( MAX_PRE_LOADING_DATA_SIZE + 3, 0, 0xFF) << 24; tmp = get_field_val(DATA_SECTOR_SIZE, 0, 0x1); if (tmp64 == 0xFFFFFFFF) if (tmp) str = strdup("16 TB"); else str = strdup("2 TB"); else if (tmp) str = basprintf("%llu B", tmp64 * 4096); else str = basprintf("%llu B", tmp64 * 512); printf("\tMax_Pre_Loading_Data_Size: %s\n", str); free(str); return 1; /* EXT_CSD_PRE_LOADING_DATA_SIZE */ case 21: case 20: case 19: case 18: print_field_caption_with_offset(PRE_LOADING_DATA_SIZE, index - EXT_CSD_PRE_LOADING_DATA_SIZE, RWE_P); tmp64 = get_field_val(PRE_LOADING_DATA_SIZE, 0, 0xFF); tmp64 = tmp64 | get_field_val( PRE_LOADING_DATA_SIZE + 1, 0, 0xFF) << 8; tmp64 = tmp64 | get_field_val( PRE_LOADING_DATA_SIZE + 2, 0, 0xFF) << 16; tmp64 = tmp64 | get_field_val( PRE_LOADING_DATA_SIZE + 3, 0, 0xFF) << 24; tmp = get_field_val(DATA_SECTOR_SIZE, 0, 0x1); if (tmp64 == 0xFFFFFFFF) if (tmp) str = strdup("16 TB"); else str = strdup("2 TB"); else if (tmp) str = basprintf("%llu B", tmp64 * 4096); else str = basprintf("%llu B", tmp64 * 512); printf("\tPre_Loading_Data_Size: %s\n", str); free(str); return 1; case EXT_CSD_FFU_STATUS: print_field_caption(FFU_STATUS, R); val = get_field_val(FFU_STATUS, 0, 0x13); switch (val) { case 0x0: str = "success"; break; case 0x10: str = "general error"; break; case 0x11: str = "firmware install error"; break; case 0x12: str = "firmware download error"; break; } printf("\t[5-0] Code: %s\n", str); return 1; case EXT_CSD_MODE_CONFIG: print_field_caption(MODE_CONFIG, RWE_P); val = get_field_val(MODE_CONFIG, 0, 0xFF); switch (val) { case 0x0: str = "normal"; break; case 0x1: str = "FFU"; break; case 0x10: str = "vendor"; break; } printf("\t[7-0] Value: %s\n", str); return 1; case EXT_CSD_BARRIER_CTRL: print_field_caption(BARRIER_CTRL, RW); val = get_field_val(BARRIER_CTRL, 0, 0x1); printf("\t[0] BARRIER_EN: %s\n", val ? "ON" : "OFF"); return 1; case EXT_CSD_OUT_OF_INTERRUPT_TIME: print_field_caption(OUT_OF_INTERRUPT_TIME, R); val = get_field_val(OUT_OF_INTERRUPT_TIME, 0, 0xFF); val = val * 10; if (val) printf("\tOut-of-interrupt timeout definition: %u ms\n", val); else printf("\tNot Defined\n"); return 1; case EXT_CSD_PARTITION_SWITCH_TIME: print_field_caption(PARTITION_SWITCH_TIME, R); val = get_field_val(PARTITION_SWITCH_TIME, 0, 0xFF); val = val * 10; if (val) printf("\tPartition switch timeout definition: %u ms\n", val); else printf("\tNot Defined\n"); return 1; case EXT_CSD_DRIVER_STRENGTH: print_field_caption(DRIVER_STRENGTH, R); val = get_field_val(DRIVER_STRENGTH, 0, 0x1); printf("\t[0] Type 0: %ssupported\n", val ? "" : "not "); val = get_field_val(DRIVER_STRENGTH, 1, 0x1); printf("\t[1] Type 1: %ssupported\n", val ? "" : "not "); val = get_field_val(DRIVER_STRENGTH, 2, 0x1); printf("\t[2] Type 2: %ssupported\n", val ? "" : "not "); val = get_field_val(DRIVER_STRENGTH, 3, 0x1); printf("\t[3] Type 3: %ssupported\n", val ? "" : "not "); val = get_field_val(DRIVER_STRENGTH, 4, 0x1); printf("\t[4] Type 4: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_CACHE_FLUSH_POLICY: print_field_caption(CACHE_FLUSH_POLICY, R); val = get_field_val(CACHE_FLUSH_POLICY, 0, 0x1); if (val) str = "FIFO policy for cache"; else str = "not provided"; printf("\t[0] Device flushing: %s", str); return 1; case EXT_CSD_OPTIMAL_READ_SIZE: print_field_caption(OPTIMAL_READ_SIZE, R); val = get_field_val(OPTIMAL_READ_SIZE, 0, 0xFF); val = val * 4048; printf("\t[7-0] Minimum optimal read unit size: %u\n", val); return 1; case EXT_CSD_OPTIMAL_WRITE_SIZE: print_field_caption(OPTIMAL_WRITE_SIZE, R); val = get_field_val(OPTIMAL_WRITE_SIZE, 0, 0xFF); val = val * 4048; printf("\t[7-0] Minimum optimal write unit size: %u\n", val); return 1; case EXT_CSD_PRE_EOL_INFO: print_field_caption(PRE_EOL_INFO, R); val = get_field_val(PRE_EOL_INFO, 0, 0x3); switch (val) { case 1: str = "normal"; break; case 2: str = "warning"; break; case 3: str = "urgent"; break; default: str = "Not defined"; } printf("\t[1-0] Device life time: %s\n", str); return 1; case EXT_CSD_DEVICE_LIFE_TIME_EST_TYP_A: print_field_caption(DEVICE_LIFE_TIME_EST_TYP_A, R); val = get_field_val(DEVICE_LIFE_TIME_EST_TYP_A, 0, 0xFF); val = val * 10; if (val == 0) str = strdup("not defined"); else if (val == 0xB) str = strdup("maximum"); else str = basprintf("%u%% - %u%%", (val - 10), val); printf("\tDevice life time, type A (estimation): %s\n", str); free(str); return 1; case EXT_CSD_DEVICE_LIFE_TIME_EST_TYP_B: print_field_caption(DEVICE_LIFE_TIME_EST_TYP_B, R); val = get_field_val(DEVICE_LIFE_TIME_EST_TYP_B, 0, 0xFF); val = val * 10; if (val == 0) str = strdup("not defined"); else if (val == 0xB) str = strdup("maximum"); else str = basprintf("%u%% - %u%%", (val - 10), val); printf("\tDevice life time, type B (estimation): %s\n", str); free(str); return 1; /* EXT_CSD_NMBR_OF_FW_SCTRS_CRRCTLY_PRGRMD */ case 305: case 304: case 303: case 302: print_field_caption_with_offset(NMBR_OF_FW_SCTRS_CRRCTLY_PRGRMD, index - EXT_CSD_NMBR_OF_FW_SCTRS_CRRCTLY_PRGRMD, R); return 1; case EXT_CSD_CMDQ_DEPTH: print_field_caption(CMDQ_DEPTH, R); val = get_field_val(CMDQ_DEPTH, 0, 0xF); ++val; printf("\t[3-0] Queue Depth: %u", val); return 1; case EXT_CSD_CMDQ_SUPPORT: print_field_caption(CMDQ_SUPPORT, R); val = get_field_val(CMDQ_SUPPORT, 0, 0x1); printf("\t[0] Command queuing: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_BARRIER_SUPPORT: print_field_caption(BARRIER_SUPPORT, R); val = get_field_val(BARRIER_SUPPORT, 0, 0x1); printf("\t[0] Barrier command: %ssupported\n", val ? "" : "not "); return 1; /* EXT_CSD_FFU_ARG */ case 490: case 489: case 488: case 487: print_field_caption_with_offset(FFU_ARG, index - EXT_CSD_FFU_ARG, R); return 1; case EXT_CSD_OPERATION_CODES_TIMEOUT: print_field_caption(OPERATION_CODES_TIMEOUT, R); val = get_field_val(OPERATION_CODES_TIMEOUT, 0, 0xFF); printf("\t[7-0] Timeout Values: %#02x\n", val); return 1; case EXT_CSD_FFU_FEATURES: print_field_caption(FFU_FEATURES, R); val = get_field_val(FFU_FEATURES, 0, 0x1); printf("\t[0] NUMBER_OF_FW_SECTORS_CORRECTLY_PROGRAMMED:\n" "%ssupported\n", val ? "" : " not"); return 1; case EXT_CSD_SUPPORTED_MODES: print_field_caption(SUPPORTED_MODES, R); val = get_field_val(SUPPORTED_MODES, 0, 0x1); printf("\t[0] FFU: %ssupported\n", val ? "" : "not "); val = get_field_val(SUPPORTED_MODES, 1, 0x1); printf("\t[1] VSM: %ssupported\n", val ? "" : "not "); return 1; } return 0; } static int print_field_ge_v6(u8 *reg, int index) { int rev; u32 val; u32 tmp; char *str = NULL; rev = reg[EXT_CSD_REV]; switch (index) { case EXT_CSD_CACHE_CTRL: print_field_caption(CACHE_CTRL, RWE_P); val = get_field_val(CACHE_CTRL, 0, 0x1); printf("\t[0] CACHE_EN: %s\n", val ? "ON" : "OFF"); return 1; case EXT_CSD_POWER_OFF_NOTIFICATION: print_field_caption(POWER_OFF_NOTIFICATION, RWE_P); val = get_field_val(POWER_OFF_NOTIFICATION, 0, 0x7); switch (val) { case 0x0: printf("\t[2-0] NO_POWER_NOTIFICATION\n"); break; case 0x1: printf("\t[2-0] POWERED_ON\n"); break; case 0x2: printf("\t[2-0] POWER_OFF_SHORT\n"); break; case 0x3: printf("\t[2-0] POWER_OFF_LONG\n"); break; case 0x4: printf("\t[2-0] SLEEP_NOTIFICATION\n"); break; } return 1; case EXT_CSD_PACKED_FAILURE_INDEX: print_field_caption(PACKED_FAILURE_INDEX, R); val = get_field_val(PACKED_FAILURE_INDEX, 0, 0xFF); printf("\t[7-0] PACKED_FAILURE_INDEX: %u\n", val); return 1; case EXT_CSD_PACKED_COMMAND_STATUS: print_field_caption(PACKED_COMMAND_STATUS, R); val = get_field_val(PACKED_COMMAND_STATUS, 0, 0x1); printf("\t[0] Error: %u\n", val); val = get_field_val(PACKED_COMMAND_STATUS, 1, 0x1); printf("\t[1] Indexed Error: %u\n", val); return 1; /* EXT_CSD_CONTEXT_CONF */ case 51: case 50: case 49: case 48: case 47: case 46: case 45: case 44: case 43: case 42: case 41: case 40: case 39: case 38: case 37: print_field_caption_with_offset(CONTEXT_CONF, index - EXT_CSD_CONTEXT_CONF, RWE_P); val = get_field_val_with_index(index, 0, 0x3); switch (val) { case 0x0: str = "closed, not active"; break; case 0x1: str = "configured and activated as write-only"; break; case 0x2: str = "configured and activated as read-only"; break; case 0x3: str = "configured and activated as read/write"; break; } printf("\t[1-0] Activation and direction: context is %s\n", str); val = get_field_val_with_index(index, 2, 0x1); if (val) str = "follows rules"; else str = "doesn't follow rules"; printf("\t[2] Large Unit context: %s\n", str); val = get_field_val_with_index(index, 3, 0x3); printf("\t[5-3] Large Unit multiplier: %u\n", val); val = get_field_val_with_index(index, 0, 0x3); switch (val) { case 0x0: str = "MODE0"; break; case 0x1: str = "MODE1"; break; case 0x2: str = "MODE2"; break; } printf("\t[7-6] Reliability mode: %s\n", str); return 1; /* EXT_CSD_EXT_PARTITIONS_ATTRIBUTE */ case 52: print_field_caption_with_offset( EXT_PARTITIONS_ATTRIBUTE, index - EXT_CSD_EXT_PARTITIONS_ATTRIBUTE, RW); printf("\t[3-0] EXT_1\n"); printf("\t[7-4] EXT_2\n"); return 1; case 53: print_field_caption_with_offset( EXT_PARTITIONS_ATTRIBUTE, index - EXT_CSD_EXT_PARTITIONS_ATTRIBUTE, RW); printf("\t[11-8] EXT_3\n"); printf("\t[15-12] EXT_4\n"); return 1; /* EXT_CSD_EXCEPTION_EVENTS_STATUS */ case 54: print_field_caption_with_offset( EXCEPTION_EVENTS_STATUS, index - EXT_CSD_EXCEPTION_EVENTS_STATUS, R); val = get_field_val(EXCEPTION_EVENTS_STATUS, 0, 0x1); printf("\t[0] URGENT_BKOPS: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_STATUS, 1, 0x1); printf("\t[1] DYNCAP_NEEDED: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_STATUS, 2, 0x1); printf("\t[2] SYSPOOL_EXHAUSTED: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_STATUS, 3, 0x1); printf("\t[3] PACKED_FAILURE: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_STATUS, 4, 0x1); printf("\t[4] EXTENDED_SECURITY_FAILURE: %i\n", val); return 1; case 55: print_field_caption_with_offset( EXCEPTION_EVENTS_STATUS, index - EXT_CSD_EXCEPTION_EVENTS_STATUS, R); return 1; /* EXT_CSD_EXCEPTION_EVENTS_CTRL */ case 56: print_field_caption_with_offset(EXCEPTION_EVENTS_CTRL, index - EXT_CSD_EXCEPTION_EVENTS_CTRL, RWE_P); val = get_field_val(EXCEPTION_EVENTS_CTRL, 1, 0x1); printf("\t[1] DYNCAP_EVENT_EN: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_CTRL, 2, 0x1); printf("\t[2] SYSPOOL_EVENT_EN: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_CTRL, 3, 0x1); printf("\t[3] PACKED_EVENT_EN: %i\n", val); val = get_field_val(EXCEPTION_EVENTS_CTRL, 4, 0x1); printf("\t[4] EXTENDED_SECURITY_EN: %i\n", val); return 1; case 57: print_field_caption(EXCEPTION_EVENTS_CTRL, RWE_P); printf("\tR/W/E_P\n"); printf("\tValue: %#02x\n", reg[index]); return 1; case EXT_CSD_CLASS_6_CTRL: print_field_caption(CLASS_6_CTRL, RWE_P); val = get_field_val(CLASS_6_CTRL, 0, 0x1); if (val) printf("\t[0] Dynamic Capacity\n"); else printf("\t[0] Write Protect\n"); return 1; case EXT_CSD_INI_TIMEOUT_EMU: print_field_caption(INI_TIMEOUT_EMU, R); val = get_field_val(INI_TIMEOUT_EMU, 0, 0xFF); val = val * 100; printf("\tInitialization Time out value: %u ms\n", val); return 1; case EXT_CSD_DATA_SECTOR_SIZE: print_field_caption(DATA_SECTOR_SIZE, R); val = get_field_val(DATA_SECTOR_SIZE, 0, 0x1); if (val) str = "4 KB"; else str = "512 B"; printf("\t[0] Data sector size is %s\n", str); return 1; case EXT_CSD_USE_NATIVE_SECTOR: print_field_caption(USE_NATIVE_SECTOR, RW); val = get_field_val(USE_NATIVE_SECTOR, 0, 0x1); if (val) printf("\t[0] Device sector size is larger than 512 B\n"); else printf("\t[0] Device sector size is 512 B\n" "(emulated or native)\n"); return 1; case EXT_CSD_NATIVE_SECTOR_SIZE: print_field_caption(NATIVE_SECTOR_SIZE, R); val = get_field_val(NATIVE_SECTOR_SIZE, 0, 0x1); if (val) str = "4 KB"; else str = "512 B"; printf("\t[0] Native sector size is %s\n", str); return 1; case EXT_CSD_PROGRAM_CID_CSD_DDR_SUPPORT: print_field_caption(PROGRAM_CID_CSD_DDR_SUPPORT, R); val = get_field_val(PROGRAM_CID_CSD_DDR_SUPPORT, 0, 0x1); if (val) str = "single data rate and dual data rate"; else str = "single data rate"; printf("\t[0] PROGRAM_CID_CSD_DDR_SUPPORT: CMD26 and CMD27\n" "%s mode\n", str); return 1; case EXT_CSD_PERIODIC_WAKEUP: print_field_caption(PERIODIC_WAKEUP, RWE); val = get_field_val(PERIODIC_WAKEUP, 0, 0x1F); printf("\t[5-0] WAKEUP_PERIOD: %u\n", val); val = get_field_val(PERIODIC_WAKEUP, 5, 0x7); switch (val) { case 0x0: str = "infinity"; break; case 0x1: str = "months"; break; case 0x2: str = "weeks"; break; case 0x3: str = "days"; break; case 0x4: str = "hours"; break; case 0x5: str = "minutes"; break; } printf("\t[7-5] WAKEUP_UNIT: %s\n", str); return 1; case EXT_CSD_PWR_CL_200_195: print_field_caption(PWR_CL_200_195, R); val = get_field_val(PWR_CL_200_195, 0, 0xFF); printf("\tPower class for 200MHz, at 1.95V %#02x\n", val); return 1; case EXT_CSD_PWR_CL_200_360: print_field_caption(PWR_CL_200_360, R); val = get_field_val(PWR_CL_200_360, 0, 0xFF); printf("\tPower class for 200MHz, at 3.6V %#02x\n", val); return 1; case EXT_CSD_POWER_OFF_LONG_TIME: print_field_caption(POWER_OFF_LONG_TIME, R); val = get_field_val(POWER_OFF_LONG_TIME, 0, 0xFF); val = val * 10; printf("\tGeneric Switch Timeout Definition: %u ms\n", val); return 1; case EXT_CSD_GENERIC_CMD6_TIME: print_field_caption(GENERIC_CMD6_TIME, R); val = get_field_val(GENERIC_CMD6_TIME, 0, 0xFF); val = val * 10; printf("\tGeneric Switch Timeout Definition: %u ms\n", val); return 1; /* EXT_CSD_CACHE_SIZE */ case 252: case 251: case 250: case 249: print_field_caption_with_offset(CACHE_SIZE, index - EXT_CSD_CACHE_SIZE, R); val = get_field_val(CACHE_SIZE, 0, 0xFF); val = val | get_field_val(CACHE_SIZE + 1, 0, 0xFF) << 8; val = val | get_field_val(CACHE_SIZE + 2, 0, 0xFF) << 16; val = val | get_field_val(CACHE_SIZE + 3, 0, 0xFF) << 24; printf("\tCache Size: %u KiB\n", val); return 1; case EXT_CSD_EXT_SUPPORT: print_field_caption(EXT_SUPPORT, R); val = get_field_val(EXT_SUPPORT, 0, 0x1); printf("\t[0] System code: %ssupported\n", val ? "" : "not "); val = get_field_val(EXT_SUPPORT, 1, 0x1); printf("\t[1] Non-persistent: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_LARGE_UNIT_SIZE_M1: print_field_caption(LARGE_UNIT_SIZE_M1, R); val = get_field_val(LARGE_UNIT_SIZE_M1, 0, 0xFF); printf("\tLarge Unit size: %#02x\n", val); return 1; case EXT_CSD_CONTEXT_CAPABILITIES: print_field_caption(CONTEXT_CAPABILITIES, R); val = get_field_val(CONTEXT_CAPABILITIES, 0, 0xF); printf("\t[3-0] MAX_CONTEXT_ID: %#02x\n", val); val = get_field_val(CONTEXT_CAPABILITIES, 4, 0x7); printf("\t[6-4] LARGE_UNIT_MAX_MULTIPLIER_M1: %#02x\n", val); return 1; case EXT_CSD_TAG_RES_SIZE: print_field_caption(TAG_RES_SIZE, R); val = get_field_val(TAG_RES_SIZE, 0, 0xFF); printf("\tSystem Data Tag Resources Size: %#02x\n", val); return 1; case EXT_CSD_TAG_UNIT_SIZE: print_field_caption(TAG_UNIT_SIZE, R); tmp = get_field_val(NATIVE_SECTOR_SIZE, 0, 0x1); tmp = (tmp == 0) ? 512 : 4048; val = 2 << (1 - get_field_val(TAG_UNIT_SIZE, 0, 0xFF)); val = val * tmp; printf("\tTag Unit Size: %u\n", val); return 1; case EXT_CSD_DATA_TAG_SUPPORT: print_field_caption(DATA_TAG_SUPPORT, R); val = get_field_val(DATA_TAG_SUPPORT, 0, 0x1); printf("\t[0] SYSTEM_DATA_TAG_SUPPORT: %u\n", val); return 1; case EXT_CSD_MAX_PACKED_WRITES: print_field_caption(MAX_PACKED_WRITES, R); val = get_field_val(MAX_PACKED_WRITES, 0, 0xFF); printf("\tmaximum number of commands in write command: %u\n", val); return 1; case EXT_CSD_MAX_PACKED_READS: print_field_caption(MAX_PACKED_READS, R); val = get_field_val(MAX_PACKED_READS, 0, 0xFF); printf("\tmaximum number of commands in read command: %u\n", val); return 1; } return 0; } static int print_field_ge_v5(u8 *reg, int index) { int rev; u32 val; u32 tmp; u64 tmp64; char *str = NULL; rev = reg[EXT_CSD_REV]; switch (index) { case EXT_CSD_TCASE_SUPPORT: print_field_caption(TCASE_SUPPORT, WE_P); val = get_field_val(TCASE_SUPPORT, 0, 0xFF); printf("\t[7-0] TCASE_SUPPORT: %#02x\n", val); return 1; case EXT_CSD_PRODUCTION_STATE_AWARENESS: print_field_caption(PRODUCTION_STATE_AWARENESS, RWE); val = get_field_val(PRODUCTION_STATE_AWARENESS, 0, 0xFF); switch (val) { case 0x0: str = "NORMAL"; break; case 0x1: str = "PRE_SOLDERING_WRITES"; break; case 0x2: str = "PRE_SOLDERING_POST_WRITES"; break; case 0x3: str = "AUTO_PRE_SOLDERING"; break; } printf("\t[7-0] State: %s\n", str); return 1; case EXT_CSD_SEC_BAD_BLK_MGMNT: print_field_caption(SEC_BAD_BLK_MGMNT, RW); val = get_field_val(SEC_BAD_BLK_MGMNT, 0, 0x1); printf("\t[0] SEC_BAD_BLK: %sabled\n", val ? "en" : "dis"); return 1; /* EXT_CSD_ENH_START_ADDR */ case 139: case 138: case 137: case 136: print_field_caption_with_offset(ENH_START_ADDR, index - EXT_CSD_ENH_START_ADDR, RW); val = get_field_val(ENH_START_ADDR, 0, 0xFF); val = val | get_field_val(ENH_START_ADDR + 1, 0, 0xFF) << 8; val = val | get_field_val(ENH_START_ADDR + 2, 0, 0xFF) << 16; val = val | get_field_val(ENH_START_ADDR + 3, 0, 0xFF) << 24; printf("\tEnhanced User Data Start Address: 0x%x\n", val); return 1; /* EXT_CSD_ENH_SIZE_MULT */ case 142: case 141: case 140: print_field_caption_with_offset(ENH_SIZE_MULT, index - EXT_CSD_ENH_SIZE_MULT, RW); val = get_field_val(ENH_SIZE_MULT, 0, 0xFF); val = val | get_field_val(ENH_SIZE_MULT + 1, 0, 0xFF) << 8; val = val | get_field_val(ENH_SIZE_MULT + 2, 0, 0xFF) << 16; tmp = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); tmp = tmp + get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); tmp64 = val * tmp * 524288; printf("\tEnhanced User Data Area %i Size: %llu B\n", index - EXT_CSD_ENH_SIZE_MULT, tmp64); return 1; /* EXT_CSD_GP_SIZE_MULT_GPX */ case 154: case 153: case 152: tmp = index - EXT_CSD_GP_SIZE_MULT; print_field_caption_with_offset(GP_SIZE_MULT, tmp, RW); val = get_field_val_with_index(tmp, 0, 0xFF); val = val | get_field_val_with_index(tmp + 1, 0, 0xFF) << 8; val = val | get_field_val_with_index(tmp + 2, 0, 0xFF) << 16; tmp = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); tmp = tmp + get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); tmp64 = val * tmp * 524288; printf("\tGeneral_Purpose_Partition_%i Size: %llu B\n", index - EXT_CSD_GP_SIZE_MULT, tmp64); return 1; case 151: case 150: case 149: tmp = index - EXT_CSD_GP_SIZE_MULT; print_field_caption_with_offset(GP_SIZE_MULT, tmp, RW); val = get_field_val_with_index(tmp, 0, 0xFF); val = val | get_field_val_with_index(tmp + 1, 0, 0xFF) << 8; val = val | get_field_val_with_index(tmp + 2, 0, 0xFF) << 16; tmp = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); tmp = tmp + get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); tmp64 = val * tmp * 524288; printf("\tGeneral_Purpose_Partition_%i Size: %llu B\n", index - EXT_CSD_GP_SIZE_MULT, tmp64); return 1; case 148: case 147: case 146: tmp = index - EXT_CSD_GP_SIZE_MULT; print_field_caption_with_offset(GP_SIZE_MULT, tmp, RW); val = get_field_val_with_index(tmp, 0, 0xFF); val = val | get_field_val_with_index(tmp + 1, 0, 0xFF) << 8; val = val | get_field_val_with_index(tmp + 2, 0, 0xFF) << 16; tmp = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); tmp = tmp + get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); tmp64 = val * tmp * 524288; printf("\tGeneral_Purpose_Partition_%i Size: %llu B\n", index - EXT_CSD_GP_SIZE_MULT, tmp64); return 1; case 145: case 144: case 143: tmp = index - EXT_CSD_GP_SIZE_MULT; print_field_caption_with_offset(GP_SIZE_MULT, tmp, RW); val = get_field_val_with_index(tmp, 0, 0xFF); val = val | get_field_val_with_index(tmp + 1, 0, 0xFF) << 8; val = val | get_field_val_with_index(tmp + 2, 0, 0xFF) << 16; tmp = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); tmp = tmp + get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); tmp64 = val * tmp * 524288; printf("\tGeneral_Purpose_Partition_%i Size: %llu B\n", index - EXT_CSD_GP_SIZE_MULT, tmp64); return 1; case EXT_CSD_PARTITION_SETTING_COMPLETED: print_field_caption(PARTITION_SETTING_COMPLETED, RW); val = get_field_val(PARTITION_SETTING_COMPLETED, 0, 0x1); printf("\t[0] PARTITION_SETTING_COMPLETED: %u\n", val); return 1; case EXT_CSD_PARTITIONS_ATTRIBUTE: print_field_caption(PARTITIONS_ATTRIBUTE, RW); val = get_field_val(PARTITIONS_ATTRIBUTE, 0, 0x1); if (val) str = "enhanced attribute in user data area"; else str = "default"; printf("\t[0] ENH_USR: %s\n", str); val = get_field_val(PARTITIONS_ATTRIBUTE, 1, 0x1); if (val) str = "enhanced attribute in general purpose part 1"; else str = "default"; printf("\t[1] ENH_1: %s\n", str); val = get_field_val(PARTITIONS_ATTRIBUTE, 2, 0x1); if (val) str = "enhanced attribute in general purpose part 2"; else str = "default"; printf("\t[2] ENH_2: %s\n", str); val = get_field_val(PARTITIONS_ATTRIBUTE, 3, 0x1); if (val) str = "enhanced attribute in general purpose part 3"; else str = "default"; printf("\t[3] ENH_3: %s\n", str); val = get_field_val(PARTITIONS_ATTRIBUTE, 4, 0x1); if (val) str = "enhanced attribute in general purpose part 4"; else str = "default"; printf("\t[4] ENH_4: %s\n", str); val = get_field_val(PARTITIONS_ATTRIBUTE, 5, 0x1); if (val) str = "enhanced attribute in general purpose part 5"; else str = "default"; printf("\t[5] ENH_5: %s\n", str); return 1; /* EXT_CSD_MAX_ENH_SIZE_MULT */ case 159: case 158: case 157: print_field_caption_with_offset(MAX_ENH_SIZE_MULT, index - EXT_CSD_MAX_ENH_SIZE_MULT, R); val = get_field_val(MAX_ENH_SIZE_MULT, 0, 0xFF); val = val | get_field_val(MAX_ENH_SIZE_MULT + 1, 0, 0xFF) << 8; val = val | get_field_val(MAX_ENH_SIZE_MULT + 2, 0, 0xFF) << 16; tmp = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); tmp = tmp + get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); tmp64 = val * tmp * 524288; printf("\tMax Enhanced Area: %llu B\n", tmp64); return 1; case EXT_CSD_PARTITIONING_SUPPORT: print_field_caption(PARTITIONING_SUPPORT, R); val = get_field_val(PARTITIONING_SUPPORT, 0, 0x1); printf("\t[0] PARTITIONING_EN: %ssupported\n", val ? "" : "not "); val = get_field_val(PARTITIONING_SUPPORT, 1, 0x1); printf("\t[1] ENH_ATTRIBUTE_EN: %ssupported\n", val ? "" : "not "); val = get_field_val(PARTITIONING_SUPPORT, 2, 0x1); printf("\t[2] EXT_ATTRIBUTE_EN: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_HPI_MGMT: print_field_caption(HPI_MGMT, R); val = get_field_val(HPI_MGMT, 0, 0xFF); printf("\t[7-0] HPI_EN: %sactivated\n", val ? "" : "not "); return 1; case EXT_CSD_RST_N_FUNCTION: print_field_caption(RST_N_FUNCTION, R); val = get_field_val(RST_N_FUNCTION, 0, 0x3); switch (val) { case 0x0: str = "temporarily disabled"; break; case 0x1: str = "permanently enabled"; break; case 0x2: str = "permanently disabled"; break; } printf("\t[1-0] RST_N_ENABLE: RST_n signal is %s\n", str); return 1; case EXT_CSD_BKOPS_EN: print_field_caption(BKOPS_EN, RWaRWE); val = get_field_val(BKOPS_EN, 0, 0x1); if (val) str = "Host is indicated"; else str = "not supported by Host"; printf("\t[0] MANUAL_EN: %s\n", str); val = get_field_val(BKOPS_EN, 1, 0x1); if (val) str = "may"; else str = "shall not"; printf("\t[1] AUTO_EN: Device %s perform background ops while\n" "not servicing the host\n", str); return 1; case EXT_CSD_BKOPS_START: print_field_caption(BKOPS_START, WE_P); printf("\t[7-0] Writing shall start a background operations.\n"); return 1; case EXT_CSD_SANITIZE_START: print_field_caption(SANITIZE_START, WE_P); printf("\t[7-0] Writing shall start a sanitize operation.\n"); return 1; case EXT_CSD_WR_REL_PARAM: print_field_caption(WR_REL_PARAM, R); val = get_field_val(WR_REL_PARAM, 0, 0x1); if (val) str = "all the WR_DATA_REL parameters in the WR_REL_SET registers are R/W"; else str = "obsolete"; printf("\t[0] HS_CTRL_REL: %s\n", str); val = get_field_val(WR_REL_PARAM, 2, 0x1); if (val) str = "the device supports the enhanced definition of reliable write"; else str = "obsolete"; printf("\t[2] EN_REL_WR: %s\n", str); val = get_field_val(WR_REL_PARAM, 4, 0x1); printf("\t[4] EN_RPMB_REL_WR: RPMB transfer size is either\n" "256B (1 512B frame), 512B (2 512B frame)%s\n", val ? ", 8KB (32 512B frames)" : ""); return 1; case EXT_CSD_WR_REL_SET: print_field_caption(WR_REL_SET, RW); val = get_field_val(WR_REL_SET, 0, 0x1); if (val) str = "the device protects previously written data if power failure occurs"; else str = "optimized for performance,data could be at risk if on power failure"; printf("\t[0] WR_DATA_REL_USR: %s\n", str); val = get_field_val(WR_REL_SET, 1, 0x1); if (val) str = "the device protects previously written data if power failure occurs"; else str = "optimized for performance,data could be at risk if on power failure"; printf("\t[1] WR_DATA_REL_1: %s\n", str); val = get_field_val(WR_REL_SET, 2, 0x1); if (val) str = "the device protects previously written data if power failure occurs"; else str = "optimized for performance,data could be at risk if on power failure"; printf("\t[2] WR_DATA_REL_2: %s\n", str); val = get_field_val(WR_REL_SET, 3, 0x1); if (val) str = "the device protects previously written data if power failure occurs"; else str = "optimized for performance,data could be at risk if on power failure"; printf("\t[3] WR_DATA_REL_3: %s\n", str); val = get_field_val(WR_REL_SET, 4, 0x1); if (val) str = "the device protects previously written data if power failure occurs"; else str = "optimized for performance,data could be at risk if on power failure"; printf("\t[4] WR_DATA_REL_4: %s\n", str); return 1; case EXT_CSD_RPMB_SIZE_MULT: print_field_caption(RPMB_SIZE_MULT, R); val = get_field_val(RPMB_SIZE_MULT, 0, 0xFF); val = val * 131072; printf("\t[7-0] RPMB Partition Size: %u KB\n", val); return 1; case EXT_CSD_FW_CONFIG: print_field_caption(FW_CONFIG, RW); val = get_field_val(FW_CONFIG, 0, 0x1); printf("\t[0] Update_Disable: FW update %sabled\n", val ? "dis" : "en"); return 1; case EXT_CSD_USER_WP: print_field_caption(USER_WP, RWaRWC_PaRWE_P); val = get_field_val(USER_WP, 0, 0x1); if (val) str = "apply Power-On Period protection to the protection group indicated by CMD28"; else str = "power-on write protection is not applied when CMD28 is issued"; printf("\t[0] US_PWR_WP_EN: %s\n", str); val = get_field_val(USER_WP, 2, 0x1); if (val) str = "apply permanent write protection to the protection group indicated by CMD28"; else str = "permanent write protection is not applied when CMD28 is issued"; printf("\t[2] US_PERM_WP_EN: %s\n", str); val = get_field_val(USER_WP, 3, 0x1); if (val) str = "disable the use of power-on period write protection"; else str = "power-on write protection can be applied to write protection groups"; printf("\t[3] US_PWR_WP_DIS: %s\n", str); val = get_field_val(USER_WP, 4, 0x1); if (val) str = "permanently disable the use of permanent write protection"; else str = "permanent write protection can be applied to write protection groups"; printf("\t[4] US_PERM_WP_DIS: %s\n", str); val = get_field_val(USER_WP, 6, 0x1); if (val) str = "disable the use of PERM_WRITE_PROTECT (CSD[13])"; else str = "host is permitted to set PERM_WRITE_PROTECT (CSD[13])"; printf("\t[6] CD_PERM_WP_DIS: %s\n", str); val = get_field_val(USER_WP, 7, 0x1); printf("\t[7] PERM_PSWD_DS: Password protection features\n" "are %sabled\n", val ? "dis" : "en"); return 1; case EXT_CSD_BOOT_WP: print_field_caption(BOOT_WP, RWaRWC_P); val = get_field_val(BOOT_WP, 0, 0x1); if (val) str = "enable Power-On Period write protection to the boot area"; else str = "boot region is not power-on write protected"; printf("\t[0] B_PWR_WP_EN: %s\n", str); val = get_field_val(BOOT_WP, 1, 0x1); printf("\t[1] B_PWR_WP_SEC_SEL: B_PWR_WP_EN(Bit 0) applies\n" "to boot Area%s only, if B_SEC_WP_SEL (bit 7 is set)\n", val ? "2" : "1"); val = get_field_val(BOOT_WP, 2, 0x1); printf("\t[2] B_PERM_WP_EN: Boot region is %spermanently\n" "write protected\n", val ? "" : "not "); val = get_field_val(BOOT_WP, 3, 0x1); printf("\t[3] B_PERM_WP_SEC_SEL: B_PERM_WP_EN(Bit 2) applies\n" "to boot Area%s only, if B_SEC_WP_SEL (bit 7 is set)\n", val ? "2" : "1"); val = get_field_val(BOOT_WP, 4, 0x1); if (val) str = "permanently disable the use of"; else str = "master is permitted to use"; printf("\t[4] B_PERM_WP_DIS: %s B_PERM_WP_EN(bit 2)\n", str); val = get_field_val(BOOT_WP, 6, 0x1); if (val) str = "disable the use of"; else str = "master is permitted to set"; printf("\t[5] B_PWR_WP_DIS: %s B_PWR_WP_EN(bit 0)\n", str); val = get_field_val(BOOT_WP, 7, 0x1); if (val) str = "boot partition selected by B_PERM_WP_SEC_SEL (bit 3) and B_PWR_WP_SEC_SEL (bit 1)"; else str = "boot partitions and B_PERM_WP_SEC_SEL (bit 3) and B_PWR_WP_SEC_SEL (bit 1) have no impact"; printf("\t[6] B_SEC_WP_SEL: B_PERM_WP_EN(bit2) and\n" "B_PWR_WP_EN (bit 0) apply to %s\n", str); return 1; case EXT_CSD_BOOT_WP_STATUS: print_field_caption(BOOT_WP_STATUS, R); val = get_field_val(BOOT_WP_STATUS, 0, 0x3); switch (val) { case 0x0: str = "not protected"; break; case 0x1: str = "Power on protected"; break; case 0x2: str = "Permanently Protected"; break; } printf("\t[1-0] B_AREA_1_WP: Boot Area 1 is %s\n", str); val = get_field_val(BOOT_WP_STATUS, 2, 0x3); switch (val) { case 0x0: str = "not protected"; break; case 0x1: str = "Power on protected"; break; case 0x2: str = "Permanently Protected"; break; } printf("\t[3-2] B_AREA_2_WP: Boot Area 2 is %s\n", str); return 1; case EXT_CSD_SEC_FEATURE_SUPPORT: print_field_caption(SEC_FEATURE_SUPPORT, R); val = get_field_val(SEC_FEATURE_SUPPORT, 0, 0x1); printf("\t[0] SECURE_ER_EN: %ssupported\n", val ? "" : "not "); val = get_field_val(SEC_FEATURE_SUPPORT, 2, 0x1); printf("\t[1] SEC_BD_BLK_EN: %ssupported\n", val ? "" : "not "); val = get_field_val(SEC_FEATURE_SUPPORT, 4, 0x1); printf("\t[4] SEC_GB_CL_EN: %ssupported\n", val ? "" : "not "); val = get_field_val(SEC_FEATURE_SUPPORT, 6, 0x1); printf("\t[6] SEC_SANITIZE: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_TRIM_MULT: print_field_caption(TRIM_MULT, R); val = get_field_val(TRIM_MULT, 0, 0xFF); val = val * 300; printf("\t[7-0] TRIM/DISCARD Time out value: %u\n", val); return 1; case EXT_CSD_MIN_PERF_DDR_R_8_52: print_field_caption(MIN_PERF_DDR_R_8_52, R); val = get_field_val(MIN_PERF_DDR_R_8_52, 0, 0xFF); printf("\t[7-0] Minimum Read Performance for 8bit at 52MHz in\n" "DDR mode %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_DDR_W_8_52: print_field_caption(MIN_PERF_DDR_W_8_52, R); val = get_field_val(MIN_PERF_DDR_W_8_52, 0, 0xFF); printf("\tMinimum Write Performance for 8bit at 52MHz in DDR\n" "mode %#02x\n", val); return 1; case EXT_CSD_PWR_CL_DDR_52_195: print_field_caption(PWR_CL_DDR_52_195, R); val = get_field_val(PWR_CL_DDR_52_195, 0, 0xFF); printf("\tPower class for 52MHz, DDR at 1.95V %#02x\n", val); return 1; case EXT_CSD_PWR_CL_DDR_52_360: print_field_caption(PWR_CL_DDR_52_360, R); val = get_field_val(PWR_CL_DDR_52_360, 0, 0xFF); printf("\tPower class for 52MHz, DDR at 3.6V %#02x\n", val); return 1; case EXT_CSD_INI_TIMEOUT_AP: print_field_caption(INI_TIMEOUT_AP, R); val = get_field_val(INI_TIMEOUT_AP, 0, 0xFF); val = val * 100; printf("\tInitialization Time out value: %u ms\n", val); return 1; /* EXT_CSD_CORRECTLY_PRG_SECTORS_NUM */ case 245: case 244: case 243: case 242: print_field_caption_with_offset(CORRECTLY_PRG_SECTORS_NUM, index - EXT_CSD_CORRECTLY_PRG_SECTORS_NUM, R); val = get_field_val(CORRECTLY_PRG_SECTORS_NUM, 0, 0xFF); val = val | get_field_val(CORRECTLY_PRG_SECTORS_NUM + 1, 0, 0xFF) << 8; val = val | get_field_val(CORRECTLY_PRG_SECTORS_NUM + 2, 0, 0xFF) << 16; val = val | get_field_val(CORRECTLY_PRG_SECTORS_NUM + 3, 0, 0xFF) << 24; printf("\tNumber of correctly programmed sectors: %u\n", val); return 1; case EXT_CSD_BKOPS_STATUS: print_field_caption(BKOPS_STATUS, R); val = get_field_val(BKOPS_STATUS, 0, 0x3); switch (val) { case 0: str = "not required"; break; case 1: str = "outstanding (non critical)"; break; case 2: str = "outstanding (performance being impacted)"; break; case 3: str = "outstanding (critical)"; break; } printf("\t[1-0] Operations %s\n", str); return 1; } return 0; } static int print_field_eq_v5(u8 *reg, int index) { int rev; u32 val; rev = reg[EXT_CSD_REV]; switch (index) { case EXT_CSD_SEC_TRIM_MULT: print_field_caption(SEC_TRIM_MULT, R); val = get_field_val(SEC_TRIM_MULT, 0, 0xFF); val = val * 300 * get_field_val(ERASE_TIMEOUT_MULT, 0, 0xFF); printf("\tSecure Trim time-out value: %u\n", val); return 1; case EXT_CSD_SEC_ERASE_MULT: print_field_caption(SEC_ERASE_MULT, R); val = get_field_val(SEC_ERASE_MULT, 0, 0xFF); val = val * 300 * get_field_val(ERASE_TIMEOUT_MULT, 0, 0xFF); printf("\tSecure Erase time-out value: %u\n", val); return 1; } return 0; } static int print_field(u8 *reg, int index) { int rev; u32 val; u64 tmp64; char *str = NULL; rev = reg[EXT_CSD_REV]; if (rev >= 7) return print_field_ge_v7(reg, index); if (rev >= 6) return print_field_ge_v6(reg, index); if (rev >= 5) return print_field_ge_v5(reg, index); if (rev == 5) return print_field_eq_v5(reg, index); switch (index) { case EXT_CSD_ERASE_GROUP_DEF: print_field_caption(ERASE_GROUP_DEF, RWE_P); val = get_field_val(ERASE_GROUP_DEF, 0, 0x1); printf("\t[0] ENABLE: Use %s size definition\n", val ? "high-capacity" : "old"); return 1; case EXT_CSD_BOOT_BUS_CONDITIONS: print_field_caption(BOOT_BUS_CONDITIONS, RWE); val = get_field_val(BOOT_BUS_CONDITIONS, 0, 0x3); switch (val) { case 0x0: str = "x1 (sdr) or x4 (ddr)"; break; case 0x1: str = "x4 (sdr/ddr)"; break; case 0x2: str = "x8 (sdr/ddr)"; break; } printf("\t[1-0] BOOT_BUS_WIDTH: %s bus width in boot operation mode\n", str); val = get_field_val(BOOT_BUS_CONDITIONS, 2, 0x1); if (val) str = "Reset bus width to x1, SDR and backward compatible timings after boot operation"; else str = "Retain BOOT_BUS_WIDTH and BOOT_MODE values after boot operation"; printf("\t[2] RESET_BOOT_BUS_CONDITIONS: %s", str); val = get_field_val(BOOT_BUS_CONDITIONS, 3, 0x3); switch (val) { case 0x0: str = "Use SDR + backward compatible timings in boot operation"; break; case 0x1: str = "Use SDR + HS timings in boot operation mode"; break; case 0x2: str = "Use DDR in boot operation"; break; } printf("\t[3] BOOT_MODE: %s\n", str); return 1; case EXT_CSD_BOOT_CONFIG_PROT: print_field_caption(BOOT_CONFIG_PROT, RWaRWC_P); val = get_field_val(BOOT_CONFIG_PROT, 0, 0x1); printf("\t[0] PWR_BOOT_CONFIG_PROT: %u\n", val); val = get_field_val(BOOT_CONFIG_PROT, 4, 0x1); printf("\t[4] PERM_BOOT_CONFIG_PROT: %u\n", val); return 1; case EXT_CSD_PARTITION_CONFIG: print_field_caption(PARTITION_CONFIG, RWEaRWE_P); val = get_field_val(PARTITION_CONFIG, 0, 0x7); switch (val) { case 0x0: str = "No access to boot partition"; break; case 0x1: str = "R/W boot partition 1"; break; case 0x2: str = "R/W boot partition 2"; break; case 0x3: str = "R/W Replay Protected Memory Block (RPMB)"; break; case 0x4: str = "Access to General Purpose partition 1"; break; case 0x5: str = "Access to General Purpose partition 2"; break; case 0x6: str = "Access to General Purpose partition 3"; break; case 0x7: str = "Access to General Purpose partition 4"; break; } printf("\t[2-0] PARTITION_ACCESS: %s\n", str); val = get_field_val(PARTITION_CONFIG, 3, 0x7); switch (val) { case 0x0: str = "Device not boot enabled"; break; case 0x1: str = "Boot partition 1 enabled for boot"; break; case 0x2: str = "Boot partition 2 enabled for boot"; break; case 0x7: str = "User area enabled for boot"; break; } printf("\t[5-3] BOOT_PARTITION_ENABLE: %s\n", str); val = get_field_val(PARTITION_CONFIG, 6, 0x1); if (val) str = "Boot acknowledge sent during boot operation Bit"; else str = "No boot acknowledge sent"; printf("\t[6] BOOT_ACK: %s\n", str); return 1; case EXT_CSD_ERASED_MEM_CONT: print_field_caption(ERASED_MEM_CONT, R); val = get_field_val(ERASED_MEM_CONT, 0, 0x1); printf("\t[0] Erased Memory Content: %u\n", val); return 1; case EXT_CSD_BUS_WIDTH: print_field_caption(BUS_WIDTH, WE_P); val = get_field_val(BUS_WIDTH, 0, 0xF); switch (val) { case 0: str = "1 bit data bus"; break; case 1: str = "4 bit data bus"; break; case 2: str = "8 bit data bus"; break; case 5: str = "4 bit data bus (dual data rate)"; break; case 6: str = "8 bit data bus (DDR)"; break; } printf("\t[3-0] Bus Mode: %s\n", str); val = get_field_val(BUS_WIDTH, 7, 0x1); printf("\t[7] Strobe is provided during Data Out, CRC response%s\n", val ? ", CMD Response" : ""); return 1; case EXT_CSD_STROBE_SUPPORT: print_field_caption(STROBE_SUPPORT, R); val = get_field_val(STROBE_SUPPORT, 0, 0x1); printf("\t[0] Enhanced Strobe mode: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_HS_TIMING: print_field_caption(HS_TIMING, RWE_P); val = get_field_val(HS_TIMING, 0, 0xF); switch (val) { case 0x0: str = "Selecting backwards compatibility interface timing"; break; case 0x1: str = "High Speed"; break; case 0x2: str = "HS200"; break; case 0x3: str = "HS400"; break; } printf("\t[3-0] Timing Interface: %s\n", str); return 1; case EXT_CSD_POWER_CLASS: print_field_caption(POWER_CLASS, RWE_P); val = get_field_val(POWER_CLASS, 0, 0xFF); printf("\t[7-0] Device power class code: %#02x\n", val); return 1; case EXT_CSD_CMD_SET_REV: print_field_caption(CMD_SET_REV, R); val = get_field_val(CMD_SET_REV, 0, 0xFF); printf("\t[7-0] Command set revisions: %#02x\n", val); return 1; case EXT_CSD_CMD_SET: print_field_caption(CMD_SET, RWE_P); val = get_field_val(CMD_SET, 0, 0xFF); printf("\t[7-0] Command set that is currently active in the Device: %#02x\n", val); return 1; case EXT_CSD_REV: print_field_caption(REV, R); val = get_field_val(REV, 0, 0x1F); switch (val) { case 0: str = "1.0 (for MMC v4.0)"; break; case 1: str = "1.1 (for MMC v4.1)"; break; case 2: str = "1.2 (for MMC v4.2)"; break; case 3: str = "1.3 (for MMC v4.3)"; break; case 4: str = "1.4 (Obsolete)"; break; case 5: str = "1.5 (for MMC v4.41)"; break; case 6: str = "1.6 (for MMC v4.5, v4.51)"; break; case 7: str = "1.7 (for MMC v5.0, v5.01)"; break; case 8: str = "1.8 (for MMC v5.1)"; break; } printf("\t[4-0] Extended CSD Revision: Revision %s\n", str); return 1; case EXT_CSD_CSD_STRUCTURE: print_field_caption(CSD_STRUCTURE, R); val = get_field_val(CSD_STRUCTURE, 0, 0x3); switch (val) { case 0x0: str = "0"; break; case 0x1: str = "1"; break; case 0x2: str = "2"; break; } printf("\t[1-0] CSD structure version: CSD version No. 1.%s\n", str); return 1; case EXT_CSD_DEVICE_TYPE: print_field_caption(DEVICE_TYPE, R); val = get_field_val(DEVICE_TYPE, 0, 0xFF); switch (val) { case 0x1: str = "HS eMMC @26MHz - at rated device voltage(s)"; break; case 0x2: str = "HS eMMC @52MHz - at rated device voltage(s)"; break; case 0x4: str = "HS Dual Data Rate eMMC @52MHz 1.8V or 3VI/O"; break; case 0x8: str = "HS Dual Data Rate eMMC @52MHz 1.2VI/O"; break; case 0x10: str = "HS200 Single Data Rate eMMC @200MHz 1.8VI/O"; break; case 0x20: str = "HS200 Single Data Rate eMMC @200MHz 1.2VI/O"; break; } printf("\t%s\n", str); return 1; /* TODO: missing JEDEC documention */ case EXT_CSD_PWR_CL_52_195: print_field_caption(PWR_CL_52_195, R) val = get_field_val(PWR_CL_52_195, 0, 0xFF); printf("\tPower class for 52 MHz at 1.95 V 1 R: %#02x\n", val); return 1; case EXT_CSD_PWR_CL_26_195: print_field_caption(PWR_CL_26_195, R) val = get_field_val(PWR_CL_26_195, 0, 0xFF); printf("\tPower class for 26 MHz at 1.95 V 1 R: %#02x\n", val); return 1; case EXT_CSD_PWR_CL_52_360: print_field_caption(PWR_CL_52_360, R) val = get_field_val(PWR_CL_52_360, 0, 0xFF); printf("\tPower class for 52 MHz at 3.6 V 1 R: %#02x\n", val); return 1; case EXT_CSD_PWR_CL_26_360: print_field_caption(PWR_CL_26_360, R) val = get_field_val(PWR_CL_26_360, 0, 0xFF); printf("\tPower class for 26 MHz at 3.6 V 1 R: %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_R_4_26: print_field_caption(MIN_PERF_R_4_26, R) val = get_field_val(MIN_PERF_R_4_26, 0, 0xFF); printf("\tMinimum Read Performance for 4bit at 26 MHz: %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_W_4_26: print_field_caption(MIN_PERF_W_4_26, R) val = get_field_val(MIN_PERF_W_4_26, 0, 0xFF); printf("\tMinimum Write Performance for 4bit at 26 MHz: %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_R_8_26_4_52: print_field_caption(MIN_PERF_R_8_26_4_52, R) val = get_field_val(MIN_PERF_R_8_26_4_52, 0, 0xFF); printf("\tMinimum Read Performance for 8bit at 26 MHz, for 4bit at 52MHz: %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_W_8_26_4_52: print_field_caption(MIN_PERF_W_8_26_4_52, R) val = get_field_val(MIN_PERF_W_8_26_4_52, 0, 0xFF); printf("\tMinimum Write Performance for 8bit at 26 MHz, for 4bit at 52MHz: %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_R_8_52: print_field_caption(MIN_PERF_R_8_52, R) val = get_field_val(MIN_PERF_R_8_52, 0, 0xFF); printf("\tMinimum Read Performance for 8bit at 52 MHz: %#02x\n", val); return 1; case EXT_CSD_MIN_PERF_W_8_52: print_field_caption(MIN_PERF_W_8_52, R) val = get_field_val(MIN_PERF_W_8_52, 0, 0xFF); printf("\tMinimum Write Performance for 8bit at52 MHz: %#02x\n", val); return 1; case EXT_CSD_SECURE_WP_INFO: print_field_caption(SECURE_WP_INFO, R); val = get_field_val(SECURE_WP_INFO, 0, 0x1); printf("\t[0] SECURE_WP_SUPPORT: %ssupported\n", val ? "" : "not "); val = get_field_val(SECURE_WP_INFO, 1, 0x1); printf("\t[1] SECURE_WP_EN_STATUS: %s Write Protection mode\n", val ? "Secure" : "Legacy"); return 1; /* EXT_CSD_SEC_COUNT */ case 215: case 214: case 213: case 212: print_field_caption_with_offset(SEC_COUNT, index - EXT_CSD_SEC_COUNT, R); val = get_field_val(SEC_COUNT, 0, 0xFF); val = val | get_field_val(SEC_COUNT + 1, 0, 0xFF) << 8; val = val | get_field_val(SEC_COUNT + 2, 0, 0xFF) << 16; val = val | get_field_val(SEC_COUNT + 3, 0, 0xFF) << 24; tmp64 = val * 512; printf("\tDevice density: %llu B\n", tmp64); return 1; case EXT_CSD_SLEEP_NOTIFICATION_TIME: print_field_caption(SLEEP_NOTIFICATION_TIME, R); val = get_field_val(SLEEP_NOTIFICATION_TIME, 0, 0xFF); val = 100 << val; if (val) str = basprintf("Sleep Notification timeout values: %u us", val); else str = strdup("Not defined"); printf("\t[7-0] %s\n", str); free(str); return 1; case EXT_CSD_S_A_TIMEOUT: print_field_caption(S_A_TIMEOUT, R); val = get_field_val(S_A_TIMEOUT, 0, 0xFF); val = 100 << val; if (val) str = basprintf("Sleep/awake timeout values: %u ns", val); else str = strdup("Not defined"); printf("\t[7-0] %s\n", str); free(str); return 1; case EXT_CSD_PRODUCTION_ST8_AWARENSS_TIMEOUT: print_field_caption(PRODUCTION_ST8_AWARENSS_TIMEOUT, R); val = get_field_val(PRODUCTION_ST8_AWARENSS_TIMEOUT, 0, 0xFF); val = 100 << val; if (val) str = basprintf( "Production State Awareness timeout definition: %u us", val); else str = strdup("Not defined"); printf("\t[7-0] %s\n", str); free(str); return 1; case EXT_CSD_S_C_VCCQ: print_field_caption(S_C_VCCQ, R); val = get_field_val(S_C_VCCQ, 0, 0xF); val = 1 << val; if (val) str = basprintf("S_C_VCCQ Sleep Current: %u uA", val); else str = strdup("Not defined"); printf("\t[3-0] %s\n", str); free(str); return 1; case EXT_CSD_S_C_VCC: print_field_caption(S_C_VCC, R); val = get_field_val(S_C_VCC, 0, 0xFF); val = 1 << val; if (val) str = basprintf("S_C_VCC Sleep Current: %u uA", val); else str = strdup("Not defined"); printf("\t[3-0] %s\n", str); free(str); return 1; case EXT_CSD_HC_WP_GRP_SIZE: print_field_caption(HC_WP_GRP_SIZE, R); val = get_field_val(HC_WP_GRP_SIZE, 0, 0xFF); if (val) str = basprintf("Write protect group size: %u", val); else str = strdup("No support"); printf("\t[7-0] %s\n", str); free(str); return 1; case EXT_CSD_REL_WR_SEC_C: print_field_caption(REL_WR_SEC_C, R); val = get_field_val(REL_WR_SEC_C, 0, 0xFF); printf("\t[7-0] Reliable Write Sector Count: %u\n", val); return 1; case EXT_CSD_ERASE_TIMEOUT_MULT: print_field_caption(ERASE_TIMEOUT_MULT, R); val = get_field_val(ERASE_TIMEOUT_MULT, 0, 0xFF); val = val * 300; if (val) str = basprintf("Erase timeout values: %u", val); else str = strdup("No support"); printf("\t[7-0] %s\n", str); free(str); return 1; case EXT_CSD_HC_ERASE_GRP_SIZE: print_field_caption(HC_ERASE_GRP_SIZE, R); val = get_field_val(HC_ERASE_GRP_SIZE, 0, 0xFF); val = val * 524288; if (val) str = basprintf("Erase-unit size: %u", val); else str = strdup("No support"); printf("\t[7-0] %s\n", str); free(str); return 1; case EXT_CSD_ACC_SIZE: print_field_caption(ACC_SIZE, R); val = get_field_val(ACC_SIZE, 0, 0xF); val = val * 512; if (val) str = basprintf("Superpage size: %u", val); else str = strdup("Not defined"); printf("\t[3-0] %s\n", str); free(str); return 1; case EXT_CSD_BOOT_SIZE_MULT: print_field_caption(BOOT_SIZE_MULT, R); val = get_field_val(BOOT_SIZE_MULT, 0, 0xFF); val = val * 131072; printf("\tBoot partition size: %u\n", val); return 1; case EXT_CSD_BOOT_INFO: print_field_caption(BOOT_INFO, R); val = get_field_val(BOOT_INFO, 0, 0x1); printf("\t[0] ALT_BOOT_MODE: %ssupported\n", val ? "" : "not "); val = get_field_val(BOOT_INFO, 1, 0x1); printf("\t[1] DDR_BOOT_MODE: %ssupported\n", val ? "" : "not "); val = get_field_val(BOOT_INFO, 2, 0x1); printf("\t[2] HS_BOOT_MODE: %ssupported\n", val ? "" : "not "); return 1; case EXT_CSD_BKOPS_SUPPORT: print_field_caption(BKOPS_SUPPORT, R); val = get_field_val(BKOPS_SUPPORT, 0, 0x1); printf("\t[0] SUPPORTED: %u\n", val); return 1; case EXT_CSD_HPI_FEATURES: print_field_caption(HPI_FEATURES, R); val = get_field_val(HPI_FEATURES, 0, 0x1); printf("\t[0] HPI_SUPPORTED: %u\n", val); val = get_field_val(HPI_FEATURES, 1, 0x1); printf("\t[1] HPI_FEATURES: implementation based on CMD1%s\n", val ? "2" : "3"); return 1; case EXT_CSD_S_CMD_SET: print_field_caption(S_CMD_SET, R); val = get_field_val(S_CMD_SET, 0, 0xFF); printf("\t[7-0] Command Set: %#02x\n", val); return 1; case EXT_CSD_EXT_SECURITY_ERR: print_field_caption(EXT_SECURITY_ERR, R); val = get_field_val(EXT_SECURITY_ERR, 0, 0x1); printf("\t[0] SEC_INVALID_COMMAND_PARAMETERS: %u\n", val); val = get_field_val(EXT_SECURITY_ERR, 1, 0x1); printf("\t[1] ACCESS_DENIED: %u\n", val); return 1; } return 0; } static void print_register_raw(u8 *reg, int index) { if (index == 0) memory_display(reg, 0, EXT_CSD_BLOCKSIZE, 1, 0); else printf("%u: %#02x\n", index, reg[index]); } static void print_register_readable(u8 *reg, int index) { int i; if (index == 0) for (i = 0; i < EXT_CSD_BLOCKSIZE; i++) print_field(reg, i); else if (!print_field(reg, index)) printf("No field with this index found\n"); print_access_type_key(); } static int request_write_operation(void) { int c; printf("This is a one time programmable field!\nDo you want to write? [y/N] "); c = getchar(); /* default is N */ if (c == 0xD) { printf("\n"); return 0; } printf("%c", c); getchar(); /* wait for carriage return */ printf("\n"); if (c == 'y' || c == 'Y') return 1; return 0; } static void write_field(struct mci *mci, u8 *reg, u16 index, u8 value, int always_write) { switch (index) { case EXT_CSD_BOOT_CONFIG_PROT: case EXT_CSD_BOOT_WP: case EXT_CSD_USER_WP: case EXT_CSD_FW_CONFIG: case EXT_CSD_WR_REL_SET: case EXT_CSD_BKOPS_EN: case EXT_CSD_RST_N_FUNCTION: case EXT_CSD_PARTITIONS_ATTRIBUTE: case EXT_CSD_PARTITION_SETTING_COMPLETED: /* EXT_CSD_GP_SIZE_MULT */ case 154: case 153: case 152: case 151: case 150: case 149: case 148: case 147: case 146: case 145: case 144: case 143: /* EXT_CSD_ENH_SIZE_MULT */ case 142: case 141: case 140: /* EXT_CSD_ENH_START_ADDR */ case 139: case 138: case 137: case 136: case EXT_CSD_SEC_BAD_BLK_MGMNT: case EXT_CSD_USE_NATIVE_SECTOR: /* EXT_CSD_EXT_PARTITIONS_ATTRIBUTE */ case 53: case 52: case EXT_CSD_BARRIER_CTRL: case EXT_CSD_SECURE_REMOVAL_TYPE: if (!always_write) if (request_write_operation() == 0) { printf("Abort write operation!\n"); goto out; } break; } mci_switch(mci, 0, index, value); out: return; } static int do_mmc_extcsd(int argc, char *argv[]) { struct mci *mci; struct mci_host *host; u8 *dst; int retval = 0; int opt; char *devname; int index = 0; int value = 0; int write_operation = 0; int always_write = 0; int print_as_raw = 0; if (argc < 2) return COMMAND_ERROR_USAGE; while ((opt = getopt(argc, argv, "i:v:yr")) > 0) switch (opt) { case 'i': index = simple_strtoul(optarg, NULL, 0); break; case 'v': value = simple_strtoul(optarg, NULL, 0); write_operation = 1; break; case 'y': always_write = 1; break; case 'r': print_as_raw = 1; break; } if (optind == argc) return COMMAND_ERROR_USAGE; devname = argv[optind]; if (!strncmp(devname, "/dev/", 5)) devname += 5; mci = mci_get_device_by_name(devname); if (mci == NULL) { retval = -ENOENT; goto error; } host = mci->host; if (host == NULL) { retval = -ENOENT; goto error; } dst = xmalloc(EXT_CSD_BLOCKSIZE); retval = mci_send_ext_csd(mci, dst); if (retval != 0) goto error_with_mem; if (dst[EXT_CSD_REV] < 3) { printf("MMC version 4.2 or lower are not supported"); retval = 1; goto error_with_mem; } if (write_operation) if (!print_field(dst, index)) { printf("No field with this index found. Abort write operation!\n"); } else { write_field(mci, dst, index, value, always_write); printf("\nValue written!\n\n"); retval = mci_send_ext_csd(mci, dst); if (retval != 0) goto error_with_mem; print_field(dst, index); } else if (print_as_raw) print_register_raw(dst, index); else print_register_readable(dst, index); error_with_mem: free(dst); error: return retval; } BAREBOX_CMD_HELP_START(mmc_extcsd) BAREBOX_CMD_HELP_TEXT("Options:") BAREBOX_CMD_HELP_OPT("-i", "field index of the register") BAREBOX_CMD_HELP_OPT("-r", "print the register as raw data") BAREBOX_CMD_HELP_OPT("-v", "value which will be written") BAREBOX_CMD_HELP_OPT("-y", "don't request when writing to one time programmable fields") BAREBOX_CMD_HELP_OPT("", "__CAUTION__: this could damage the device!") BAREBOX_CMD_HELP_END BAREBOX_CMD_START(mmc_extcsd) .cmd = do_mmc_extcsd, BAREBOX_CMD_DESC("Read/write the extended CSD register.") BAREBOX_CMD_OPTS("dev [-r | -i index [-r | -v value [-y]]]") BAREBOX_CMD_GROUP(CMD_GRP_CONSOLE) BAREBOX_CMD_HELP(cmd_mmc_extcsd_help) BAREBOX_CMD_END