/* * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public * License v2 as published by the Free Software Foundation. * * 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. * * You should have received a copy of the GNU General Public * License along with this program; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 021110-1307, USA. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "mmc.h" #include "mmc_cmds.h" #include "3rdparty/hmac_sha/hmac_sha2.h" int read_extcsd(int fd, __u8 *ext_csd) { int ret = 0; struct mmc_ioc_cmd idata; memset(&idata, 0, sizeof(idata)); memset(ext_csd, 0, sizeof(__u8) * 512); idata.write_flag = 0; idata.opcode = MMC_SEND_EXT_CSD; idata.arg = 0; idata.flags = MMC_RSP_SPI_R1 | MMC_RSP_R1 | MMC_CMD_ADTC; idata.blksz = 512; idata.blocks = 1; mmc_ioc_cmd_set_data(idata, ext_csd); ret = ioctl(fd, MMC_IOC_CMD, &idata); if (ret) perror("ioctl"); return ret; } int write_extcsd_value(int fd, __u8 index, __u8 value) { int ret = 0; struct mmc_ioc_cmd idata; memset(&idata, 0, sizeof(idata)); idata.write_flag = 1; idata.opcode = MMC_SWITCH; idata.arg = (MMC_SWITCH_MODE_WRITE_BYTE << 24) | (index << 16) | (value << 8) | EXT_CSD_CMD_SET_NORMAL; idata.flags = MMC_RSP_SPI_R1B | MMC_RSP_R1B | MMC_CMD_AC; ret = ioctl(fd, MMC_IOC_CMD, &idata); if (ret) perror("ioctl"); return ret; } int send_status(int fd, __u32 *response) { int ret = 0; struct mmc_ioc_cmd idata; memset(&idata, 0, sizeof(idata)); idata.opcode = MMC_SEND_STATUS; idata.arg = (1 << 16); idata.flags = MMC_RSP_R1 | MMC_CMD_AC; ret = ioctl(fd, MMC_IOC_CMD, &idata); if (ret) perror("ioctl"); *response = idata.response[0]; return ret; } void print_writeprotect_status(__u8 *ext_csd) { __u8 reg; __u8 ext_csd_rev = ext_csd[EXT_CSD_REV]; /* A43: reserved [174:0] */ if (ext_csd_rev >= 5) { printf("Boot write protection status registers" " [BOOT_WP_STATUS]: 0x%02x\n", ext_csd[174]); reg = ext_csd[EXT_CSD_BOOT_WP]; printf("Boot Area Write protection [BOOT_WP]: 0x%02x\n", reg); printf(" Power ro locking: "); if (reg & EXT_CSD_BOOT_WP_B_PWR_WP_DIS) printf("not possible\n"); else printf("possible\n"); printf(" Permanent ro locking: "); if (reg & EXT_CSD_BOOT_WP_B_PERM_WP_DIS) printf("not possible\n"); else printf("possible\n"); printf(" ro lock status: "); if (reg & EXT_CSD_BOOT_WP_B_PWR_WP_EN) printf("locked until next power on\n"); else if (reg & EXT_CSD_BOOT_WP_B_PERM_WP_EN) printf("locked permanently\n"); else printf("not locked\n"); } } int do_writeprotect_get(int nargs, char **argv) { __u8 ext_csd[512]; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc writeprotect get \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } print_writeprotect_status(ext_csd); return ret; } int do_writeprotect_set(int nargs, char **argv) { __u8 ext_csd[512], value; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc writeprotect set \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } value = ext_csd[EXT_CSD_BOOT_WP] | EXT_CSD_BOOT_WP_B_PWR_WP_EN; ret = write_extcsd_value(fd, EXT_CSD_BOOT_WP, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_BOOT_WP, device); exit(1); } return ret; } int do_disable_512B_emulation(int nargs, char **argv) { __u8 ext_csd[512], native_sector_size, data_sector_size, wr_rel_param; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc disable 512B emulation \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } wr_rel_param = ext_csd[EXT_CSD_WR_REL_PARAM]; native_sector_size = ext_csd[EXT_CSD_NATIVE_SECTOR_SIZE]; data_sector_size = ext_csd[EXT_CSD_DATA_SECTOR_SIZE]; if (native_sector_size && !data_sector_size && (wr_rel_param & EN_REL_WR)) { ret = write_extcsd_value(fd, EXT_CSD_USE_NATIVE_SECTOR, 1); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", 1, EXT_CSD_BOOT_WP, device); exit(1); } printf("MMC disable 512B emulation successful. Now reset the device to switch to 4KB native sector mode.\n"); } else if (native_sector_size && data_sector_size) { printf("MMC 512B emulation mode is already disabled; doing nothing.\n"); } else { printf("MMC does not support disabling 512B emulation mode.\n"); } return ret; } int do_write_boot_en(int nargs, char **argv) { __u8 ext_csd[512]; __u8 value = 0; int fd, ret; char *device; int boot_area, send_ack; CHECK(nargs != 4, "Usage: mmc bootpart enable " " \n", exit(1)); /* * If is 1, the device will send acknowledgment * pattern "010" to the host when boot operation begins. * If is 0, it won't. */ boot_area = strtol(argv[1], NULL, 10); send_ack = strtol(argv[2], NULL, 10); device = argv[3]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } value = ext_csd[EXT_CSD_PART_CONFIG]; switch (boot_area) { case EXT_CSD_PART_CONFIG_ACC_BOOT0: value |= (1 << 3); value &= ~(3 << 4); break; case EXT_CSD_PART_CONFIG_ACC_BOOT1: value |= (1 << 4); value &= ~(1 << 3); value &= ~(1 << 5); break; case EXT_CSD_PART_CONFIG_ACC_USER_AREA: value |= (boot_area << 3); break; default: fprintf(stderr, "Cannot enable the boot area\n"); exit(1); } if (send_ack) value |= EXT_CSD_PART_CONFIG_ACC_ACK; else value &= ~EXT_CSD_PART_CONFIG_ACC_ACK; ret = write_extcsd_value(fd, EXT_CSD_PART_CONFIG, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_PART_CONFIG, device); exit(1); } return ret; } int do_boot_bus_conditions_set(int nargs, char **argv) { __u8 ext_csd[512]; __u8 value = 0; int fd, ret; char *device; CHECK(nargs != 5, "Usage: mmc: bootbus set " " \n", exit(1)); if (strcmp(argv[1], "single_backward") == 0) value |= 0; else if (strcmp(argv[1], "single_hs") == 0) value |= 0x8; else if (strcmp(argv[1], "dual") == 0) value |= 0x10; else { fprintf(stderr, "illegal specified\n"); exit(1); } if (strcmp(argv[2], "x1") == 0) value |= 0; else if (strcmp(argv[2], "retain") == 0) value |= 0x4; else { fprintf(stderr, "illegal specified\n"); exit(1); } if (strcmp(argv[3], "x1") == 0) value |= 0; else if (strcmp(argv[3], "x4") == 0) value |= 0x1; else if (strcmp(argv[3], "x8") == 0) value |= 0x2; else { fprintf(stderr, "illegal specified\n"); exit(1); } device = argv[4]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } printf("Changing ext_csd[BOOT_BUS_CONDITIONS] from 0x%02x to 0x%02x\n", ext_csd[EXT_CSD_BOOT_BUS_CONDITIONS], value); ret = write_extcsd_value(fd, EXT_CSD_BOOT_BUS_CONDITIONS, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_BOOT_BUS_CONDITIONS, device); exit(1); } close(fd); return ret; } int do_hwreset(int value, int nargs, char **argv) { __u8 ext_csd[512]; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc hwreset enable \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } if ((ext_csd[EXT_CSD_RST_N_FUNCTION] & EXT_CSD_RST_N_EN_MASK) == EXT_CSD_HW_RESET_EN) { fprintf(stderr, "H/W Reset is already permanently enabled on %s\n", device); exit(1); } if ((ext_csd[EXT_CSD_RST_N_FUNCTION] & EXT_CSD_RST_N_EN_MASK) == EXT_CSD_HW_RESET_DIS) { fprintf(stderr, "H/W Reset is already permanently disabled on %s\n", device); exit(1); } ret = write_extcsd_value(fd, EXT_CSD_RST_N_FUNCTION, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", value, EXT_CSD_RST_N_FUNCTION, device); exit(1); } return ret; } int do_hwreset_en(int nargs, char **argv) { return do_hwreset(EXT_CSD_HW_RESET_EN, nargs, argv); } int do_hwreset_dis(int nargs, char **argv) { return do_hwreset(EXT_CSD_HW_RESET_DIS, nargs, argv); } int do_write_bkops_en(int nargs, char **argv) { __u8 ext_csd[512], value = 0; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc bkops enable \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } if (!(ext_csd[EXT_CSD_BKOPS_SUPPORT] & 0x1)) { fprintf(stderr, "%s doesn't support BKOPS\n", device); exit(1); } ret = write_extcsd_value(fd, EXT_CSD_BKOPS_EN, BKOPS_ENABLE); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", value, EXT_CSD_BKOPS_EN, device); exit(1); } return ret; } int do_status_get(int nargs, char **argv) { __u32 response; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc status get \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = send_status(fd, &response); if (ret) { fprintf(stderr, "Could not read response to SEND_STATUS from %s\n", device); exit(1); } printf("SEND_STATUS response: 0x%08x\n", response); return ret; } unsigned int get_sector_count(__u8 *ext_csd) { return (ext_csd[EXT_CSD_SEC_COUNT_3] << 24) | (ext_csd[EXT_CSD_SEC_COUNT_2] << 16) | (ext_csd[EXT_CSD_SEC_COUNT_1] << 8) | ext_csd[EXT_CSD_SEC_COUNT_0]; } int is_blockaddresed(__u8 *ext_csd) { unsigned int sectors = get_sector_count(ext_csd); return (sectors > (2u * 1024 * 1024 * 1024) / 512); } unsigned int get_hc_wp_grp_size(__u8 *ext_csd) { return ext_csd[221]; } unsigned int get_hc_erase_grp_size(__u8 *ext_csd) { return ext_csd[224]; } int set_partitioning_setting_completed(int dry_run, const char * const device, int fd) { int ret; if (dry_run) { fprintf(stderr, "NOT setting PARTITION_SETTING_COMPLETED\n"); fprintf(stderr, "These changes will not take effect neither " "now nor after a power cycle\n"); return 1; } fprintf(stderr, "setting OTP PARTITION_SETTING_COMPLETED!\n"); ret = write_extcsd_value(fd, EXT_CSD_PARTITION_SETTING_COMPLETED, 0x1); if (ret) { fprintf(stderr, "Could not write 0x1 to " "EXT_CSD[%d] in %s\n", EXT_CSD_PARTITION_SETTING_COMPLETED, device); return 1; } __u32 response; ret = send_status(fd, &response); if (ret) { fprintf(stderr, "Could not get response to SEND_STATUS " "from %s\n", device); return 1; } if (response & R1_SWITCH_ERROR) { fprintf(stderr, "Setting OTP PARTITION_SETTING_COMPLETED " "failed on %s\n", device); return 1; } fprintf(stderr, "Setting OTP PARTITION_SETTING_COMPLETED on " "%s SUCCESS\n", device); fprintf(stderr, "Device power cycle needed for settings to " "take effect.\n" "Confirm that PARTITION_SETTING_COMPLETED bit is set " "using 'extcsd read' after power cycle\n"); return 0; } int check_enhanced_area_total_limit(const char * const device, int fd) { __u8 ext_csd[512]; __u32 regl; unsigned long max_enh_area_sz, user_area_sz, enh_area_sz = 0; unsigned long gp4_part_sz, gp3_part_sz, gp2_part_sz, gp1_part_sz; unsigned long total_sz, total_gp_user_sz; unsigned int wp_sz, erase_sz; int ret; ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } wp_sz = get_hc_wp_grp_size(ext_csd); erase_sz = get_hc_erase_grp_size(ext_csd); regl = (ext_csd[EXT_CSD_GP_SIZE_MULT_4_2] << 16) | (ext_csd[EXT_CSD_GP_SIZE_MULT_4_1] << 8) | ext_csd[EXT_CSD_GP_SIZE_MULT_4_0]; gp4_part_sz = 512l * regl * erase_sz * wp_sz; if (ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE] & EXT_CSD_ENH_4) { enh_area_sz += gp4_part_sz; printf("Enhanced GP4 Partition Size [GP_SIZE_MULT_4]: 0x%06x\n", regl); printf(" i.e. %lu KiB\n", gp4_part_sz); } regl = (ext_csd[EXT_CSD_GP_SIZE_MULT_3_2] << 16) | (ext_csd[EXT_CSD_GP_SIZE_MULT_3_1] << 8) | ext_csd[EXT_CSD_GP_SIZE_MULT_3_0]; gp3_part_sz = 512l * regl * erase_sz * wp_sz; if (ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE] & EXT_CSD_ENH_3) { enh_area_sz += gp3_part_sz; printf("Enhanced GP3 Partition Size [GP_SIZE_MULT_3]: 0x%06x\n", regl); printf(" i.e. %lu KiB\n", gp3_part_sz); } regl = (ext_csd[EXT_CSD_GP_SIZE_MULT_2_2] << 16) | (ext_csd[EXT_CSD_GP_SIZE_MULT_2_1] << 8) | ext_csd[EXT_CSD_GP_SIZE_MULT_2_0]; gp2_part_sz = 512l * regl * erase_sz * wp_sz; if (ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE] & EXT_CSD_ENH_2) { enh_area_sz += gp2_part_sz; printf("Enhanced GP2 Partition Size [GP_SIZE_MULT_2]: 0x%06x\n", regl); printf(" i.e. %lu KiB\n", gp2_part_sz); } regl = (ext_csd[EXT_CSD_GP_SIZE_MULT_1_2] << 16) | (ext_csd[EXT_CSD_GP_SIZE_MULT_1_1] << 8) | ext_csd[EXT_CSD_GP_SIZE_MULT_1_0]; gp1_part_sz = 512l * regl * erase_sz * wp_sz; if (ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE] & EXT_CSD_ENH_1) { enh_area_sz += gp1_part_sz; printf("Enhanced GP1 Partition Size [GP_SIZE_MULT_1]: 0x%06x\n", regl); printf(" i.e. %lu KiB\n", gp1_part_sz); } regl = (ext_csd[EXT_CSD_ENH_SIZE_MULT_2] << 16) | (ext_csd[EXT_CSD_ENH_SIZE_MULT_1] << 8) | ext_csd[EXT_CSD_ENH_SIZE_MULT_0]; user_area_sz = 512l * regl * erase_sz * wp_sz; if (ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE] & EXT_CSD_ENH_USR) { enh_area_sz += user_area_sz; printf("Enhanced User Data Area Size [ENH_SIZE_MULT]: 0x%06x\n", regl); printf(" i.e. %lu KiB\n", user_area_sz); } regl = (ext_csd[EXT_CSD_MAX_ENH_SIZE_MULT_2] << 16) | (ext_csd[EXT_CSD_MAX_ENH_SIZE_MULT_1] << 8) | ext_csd[EXT_CSD_MAX_ENH_SIZE_MULT_0]; max_enh_area_sz = 512l * regl * erase_sz * wp_sz; printf("Max Enhanced Area Size [MAX_ENH_SIZE_MULT]: 0x%06x\n", regl); printf(" i.e. %lu KiB\n", max_enh_area_sz); if (enh_area_sz > max_enh_area_sz) { fprintf(stderr, "Programmed total enhanced size %lu KiB cannot exceed max enhanced area %lu KiB %s\n", enh_area_sz, max_enh_area_sz, device); return 1; } total_sz = get_sector_count(ext_csd) / 2; total_gp_user_sz = gp4_part_sz + gp3_part_sz + gp2_part_sz + gp1_part_sz + user_area_sz; if (total_gp_user_sz > total_sz) { fprintf(stderr, "requested total partition size %lu KiB cannot exceed card capacity %lu KiB %s\n", total_gp_user_sz, total_sz, device); return 1; } return 0; } int do_create_gp_partition(int nargs, char **argv) { __u8 value; __u8 ext_csd[512]; __u8 address; int fd, ret; char *device; int dry_run = 1; int partition, enh_attr, ext_attr; unsigned int length_kib, gp_size_mult; unsigned long align; CHECK(nargs != 7, "Usage: mmc gp create <-y|-n> " " \n", exit(1)); if (!strcmp("-y", argv[1])) dry_run = 0; length_kib = strtol(argv[2], NULL, 10); partition = strtol(argv[3], NULL, 10); enh_attr = strtol(argv[4], NULL, 10); ext_attr = strtol(argv[5], NULL, 10); device = argv[6]; if (partition < 0 || partition > 4) { printf("Invalid gp parition number valid range [1-4]\n"); exit(1); } if (enh_attr && ext_attr) { printf("Not allowed to set both enhanced attribute and extended attribute\n"); exit(1); } fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } /* assert not PARTITION_SETTING_COMPLETED */ if (ext_csd[EXT_CSD_PARTITION_SETTING_COMPLETED]) { printf(" Device is already partitioned\n"); exit(1); } align = 512l * get_hc_wp_grp_size(ext_csd) * get_hc_erase_grp_size(ext_csd); gp_size_mult = (length_kib + align/2l) / align; /* set EXT_CSD_ERASE_GROUP_DEF bit 0 */ ret = write_extcsd_value(fd, EXT_CSD_ERASE_GROUP_DEF, 0x1); if (ret) { fprintf(stderr, "Could not write 0x1 to EXT_CSD[%d] in %s\n", EXT_CSD_ERASE_GROUP_DEF, device); exit(1); } value = (gp_size_mult >> 16) & 0xff; address = EXT_CSD_GP_SIZE_MULT_1_2 + (partition - 1) * 3; ret = write_extcsd_value(fd, address, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", value, address, device); exit(1); } value = (gp_size_mult >> 8) & 0xff; address = EXT_CSD_GP_SIZE_MULT_1_1 + (partition - 1) * 3; ret = write_extcsd_value(fd, address, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", value, address, device); exit(1); } value = gp_size_mult & 0xff; address = EXT_CSD_GP_SIZE_MULT_1_0 + (partition - 1) * 3; ret = write_extcsd_value(fd, address, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", value, address, device); exit(1); } value = ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE]; if (enh_attr) value |= (1 << partition); else value &= ~(1 << partition); ret = write_extcsd_value(fd, EXT_CSD_PARTITIONS_ATTRIBUTE, value); if (ret) { fprintf(stderr, "Could not write EXT_CSD_ENH_%x to EXT_CSD[%d] in %s\n", partition, EXT_CSD_PARTITIONS_ATTRIBUTE, device); exit(1); } address = EXT_CSD_EXT_PARTITIONS_ATTRIBUTE_0 + (partition - 1) / 2; value = ext_csd[address]; if (ext_attr) value |= (ext_attr << (4 * ((partition - 1) % 2))); else value &= (0xF << (4 * ((partition % 2)))); ret = write_extcsd_value(fd, address, value); if (ret) { fprintf(stderr, "Could not write 0x%x to EXT_CSD[%d] in %s\n", value, address, device); exit(1); } ret = check_enhanced_area_total_limit(device, fd); if (ret) exit(1); if (!set_partitioning_setting_completed(dry_run, device, fd)) exit(1); return 0; } int do_enh_area_set(int nargs, char **argv) { __u8 value; __u8 ext_csd[512]; int fd, ret; char *device; int dry_run = 1; unsigned int start_kib, length_kib, enh_start_addr, enh_size_mult; unsigned long align; CHECK(nargs != 5, "Usage: mmc enh_area set <-y|-n> " "\n", exit(1)); if (!strcmp("-y", argv[1])) dry_run = 0; start_kib = strtol(argv[2], NULL, 10); length_kib = strtol(argv[3], NULL, 10); device = argv[4]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } /* assert ENH_ATTRIBUTE_EN */ if (!(ext_csd[EXT_CSD_PARTITIONING_SUPPORT] & EXT_CSD_ENH_ATTRIBUTE_EN)) { printf(" Device cannot have enhanced tech.\n"); exit(1); } /* assert not PARTITION_SETTING_COMPLETED */ if (ext_csd[EXT_CSD_PARTITION_SETTING_COMPLETED]) { printf(" Device is already partitioned\n"); exit(1); } align = 512l * get_hc_wp_grp_size(ext_csd) * get_hc_erase_grp_size(ext_csd); enh_size_mult = (length_kib + align/2l) / align; enh_start_addr = start_kib * 1024 / (is_blockaddresed(ext_csd) ? 512 : 1); enh_start_addr /= align; enh_start_addr *= align; /* set EXT_CSD_ERASE_GROUP_DEF bit 0 */ ret = write_extcsd_value(fd, EXT_CSD_ERASE_GROUP_DEF, 0x1); if (ret) { fprintf(stderr, "Could not write 0x1 to " "EXT_CSD[%d] in %s\n", EXT_CSD_ERASE_GROUP_DEF, device); exit(1); } /* write to ENH_START_ADDR and ENH_SIZE_MULT and PARTITIONS_ATTRIBUTE's ENH_USR bit */ value = (enh_start_addr >> 24) & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_START_ADDR_3, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_START_ADDR_3, device); exit(1); } value = (enh_start_addr >> 16) & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_START_ADDR_2, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_START_ADDR_2, device); exit(1); } value = (enh_start_addr >> 8) & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_START_ADDR_1, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_START_ADDR_1, device); exit(1); } value = enh_start_addr & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_START_ADDR_0, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_START_ADDR_0, device); exit(1); } value = (enh_size_mult >> 16) & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_SIZE_MULT_2, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_SIZE_MULT_2, device); exit(1); } value = (enh_size_mult >> 8) & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_SIZE_MULT_1, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_SIZE_MULT_1, device); exit(1); } value = enh_size_mult & 0xff; ret = write_extcsd_value(fd, EXT_CSD_ENH_SIZE_MULT_0, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to " "EXT_CSD[%d] in %s\n", value, EXT_CSD_ENH_SIZE_MULT_0, device); exit(1); } value = ext_csd[EXT_CSD_PARTITIONS_ATTRIBUTE] | EXT_CSD_ENH_USR; ret = write_extcsd_value(fd, EXT_CSD_PARTITIONS_ATTRIBUTE, value); if (ret) { fprintf(stderr, "Could not write EXT_CSD_ENH_USR to " "EXT_CSD[%d] in %s\n", EXT_CSD_PARTITIONS_ATTRIBUTE, device); exit(1); } ret = check_enhanced_area_total_limit(device, fd); if (ret) exit(1); printf("Done setting ENH_USR area on %s\n", device); if (!set_partitioning_setting_completed(dry_run, device, fd)) exit(1); return 0; } int do_write_reliability_set(int nargs, char **argv) { __u8 value; __u8 ext_csd[512]; int fd, ret; int dry_run = 1; int partition; char *device; CHECK(nargs != 4, "Usage: mmc write_reliability set <-y|-n> " " \n", exit(1)); if (!strcmp("-y", argv[1])) dry_run = 0; partition = strtol(argv[2], NULL, 10); device = argv[3]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } /* assert not PARTITION_SETTING_COMPLETED */ if (ext_csd[EXT_CSD_PARTITION_SETTING_COMPLETED]) { printf(" Device is already partitioned\n"); exit(1); } /* assert HS_CTRL_REL */ if (!(ext_csd[EXT_CSD_WR_REL_PARAM] & HS_CTRL_REL)) { printf("Cannot set write reliability parameters, WR_REL_SET is " "read-only\n"); exit(1); } value = ext_csd[EXT_CSD_WR_REL_SET] | (1<\n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } ext_csd_rev = ext_csd[EXT_CSD_REV]; switch (ext_csd_rev) { case 7: str = "5.0"; break; case 6: str = "4.5"; break; case 5: str = "4.41"; break; case 3: str = "4.3"; break; case 2: str = "4.2"; break; case 1: str = "4.1"; break; case 0: str = "4.0"; break; default: goto out_free; } printf("=============================================\n"); printf(" Extended CSD rev 1.%d (MMC %s)\n", ext_csd_rev, str); printf("=============================================\n\n"); if (ext_csd_rev < 3) goto out_free; /* No ext_csd */ /* Parse the Extended CSD registers. * Reserved bit should be read as "0" in case of spec older * than A441. */ reg = ext_csd[EXT_CSD_S_CMD_SET]; printf("Card Supported Command sets [S_CMD_SET: 0x%02x]\n", reg); if (!reg) printf(" - Standard MMC command sets\n"); reg = ext_csd[EXT_CSD_HPI_FEATURE]; printf("HPI Features [HPI_FEATURE: 0x%02x]: ", reg); if (reg & EXT_CSD_HPI_SUPP) { if (reg & EXT_CSD_HPI_IMPL) printf("implementation based on CMD12\n"); else printf("implementation based on CMD13\n"); } printf("Background operations support [BKOPS_SUPPORT: 0x%02x]\n", ext_csd[502]); if (ext_csd_rev >= 6) { printf("Max Packet Read Cmd [MAX_PACKED_READS: 0x%02x]\n", ext_csd[501]); printf("Max Packet Write Cmd [MAX_PACKED_WRITES: 0x%02x]\n", ext_csd[500]); printf("Data TAG support [DATA_TAG_SUPPORT: 0x%02x]\n", ext_csd[499]); printf("Data TAG Unit Size [TAG_UNIT_SIZE: 0x%02x]\n", ext_csd[498]); printf("Tag Resources Size [TAG_RES_SIZE: 0x%02x]\n", ext_csd[497]); printf("Context Management Capabilities" " [CONTEXT_CAPABILITIES: 0x%02x]\n", ext_csd[496]); printf("Large Unit Size [LARGE_UNIT_SIZE_M1: 0x%02x]\n", ext_csd[495]); printf("Extended partition attribute support" " [EXT_SUPPORT: 0x%02x]\n", ext_csd[494]); printf("Generic CMD6 Timer [GENERIC_CMD6_TIME: 0x%02x]\n", ext_csd[248]); printf("Power off notification [POWER_OFF_LONG_TIME: 0x%02x]\n", ext_csd[247]); printf("Cache Size [CACHE_SIZE] is %d KiB\n", ext_csd[249] << 0 | (ext_csd[250] << 8) | (ext_csd[251] << 16) | (ext_csd[252] << 24)); } /* A441: Reserved [501:247] A43: reserved [246:229] */ if (ext_csd_rev >= 5) { printf("Background operations status" " [BKOPS_STATUS: 0x%02x]\n", ext_csd[246]); /* CORRECTLY_PRG_SECTORS_NUM [245:242] TODO */ printf("1st Initialisation Time after programmed sector" " [INI_TIMEOUT_AP: 0x%02x]\n", ext_csd[241]); /* A441: reserved [240] */ printf("Power class for 52MHz, DDR at 3.6V" " [PWR_CL_DDR_52_360: 0x%02x]\n", ext_csd[239]); printf("Power class for 52MHz, DDR at 1.95V" " [PWR_CL_DDR_52_195: 0x%02x]\n", ext_csd[238]); /* A441: reserved [237-236] */ if (ext_csd_rev >= 6) { printf("Power class for 200MHz at 3.6V" " [PWR_CL_200_360: 0x%02x]\n", ext_csd[237]); printf("Power class for 200MHz, at 1.95V" " [PWR_CL_200_195: 0x%02x]\n", ext_csd[236]); } printf("Minimum Performance for 8bit at 52MHz in DDR mode:\n"); printf(" [MIN_PERF_DDR_W_8_52: 0x%02x]\n", ext_csd[235]); printf(" [MIN_PERF_DDR_R_8_52: 0x%02x]\n", ext_csd[234]); /* A441: reserved [233] */ printf("TRIM Multiplier [TRIM_MULT: 0x%02x]\n", ext_csd[232]); printf("Secure Feature support [SEC_FEATURE_SUPPORT: 0x%02x]\n", ext_csd[231]); } if (ext_csd_rev == 5) { /* Obsolete in 4.5 */ printf("Secure Erase Multiplier [SEC_ERASE_MULT: 0x%02x]\n", ext_csd[230]); printf("Secure TRIM Multiplier [SEC_TRIM_MULT: 0x%02x]\n", ext_csd[229]); } reg = ext_csd[EXT_CSD_BOOT_INFO]; printf("Boot Information [BOOT_INFO: 0x%02x]\n", reg); if (reg & EXT_CSD_BOOT_INFO_ALT) printf(" Device supports alternative boot method\n"); if (reg & EXT_CSD_BOOT_INFO_DDR_DDR) printf(" Device supports dual data rate during boot\n"); if (reg & EXT_CSD_BOOT_INFO_HS_MODE) printf(" Device supports high speed timing during boot\n"); /* A441/A43: reserved [227] */ printf("Boot partition size [BOOT_SIZE_MULTI: 0x%02x]\n", ext_csd[226]); printf("Access size [ACC_SIZE: 0x%02x]\n", ext_csd[225]); reg = get_hc_erase_grp_size(ext_csd); printf("High-capacity erase unit size [HC_ERASE_GRP_SIZE: 0x%02x]\n", reg); printf(" i.e. %u KiB\n", 512 * reg); printf("High-capacity erase timeout [ERASE_TIMEOUT_MULT: 0x%02x]\n", ext_csd[223]); printf("Reliable write sector count [REL_WR_SEC_C: 0x%02x]\n", ext_csd[222]); reg = get_hc_wp_grp_size(ext_csd); printf("High-capacity W protect group size [HC_WP_GRP_SIZE: 0x%02x]\n", reg); printf(" i.e. %lu KiB\n", 512l * get_hc_erase_grp_size(ext_csd) * reg); printf("Sleep current (VCC) [S_C_VCC: 0x%02x]\n", ext_csd[220]); printf("Sleep current (VCCQ) [S_C_VCCQ: 0x%02x]\n", ext_csd[219]); /* A441/A43: reserved [218] */ printf("Sleep/awake timeout [S_A_TIMEOUT: 0x%02x]\n", ext_csd[217]); /* A441/A43: reserved [216] */ unsigned int sectors = get_sector_count(ext_csd); printf("Sector Count [SEC_COUNT: 0x%08x]\n", sectors); if (is_blockaddresed(ext_csd)) printf(" Device is block-addressed\n"); else printf(" Device is NOT block-addressed\n"); /* A441/A43: reserved [211] */ printf("Minimum Write Performance for 8bit:\n"); printf(" [MIN_PERF_W_8_52: 0x%02x]\n", ext_csd[210]); printf(" [MIN_PERF_R_8_52: 0x%02x]\n", ext_csd[209]); printf(" [MIN_PERF_W_8_26_4_52: 0x%02x]\n", ext_csd[208]); printf(" [MIN_PERF_R_8_26_4_52: 0x%02x]\n", ext_csd[207]); printf("Minimum Write Performance for 4bit:\n"); printf(" [MIN_PERF_W_4_26: 0x%02x]\n", ext_csd[206]); printf(" [MIN_PERF_R_4_26: 0x%02x]\n", ext_csd[205]); /* A441/A43: reserved [204] */ printf("Power classes registers:\n"); printf(" [PWR_CL_26_360: 0x%02x]\n", ext_csd[203]); printf(" [PWR_CL_52_360: 0x%02x]\n", ext_csd[202]); printf(" [PWR_CL_26_195: 0x%02x]\n", ext_csd[201]); printf(" [PWR_CL_52_195: 0x%02x]\n", ext_csd[200]); /* A43: reserved [199:198] */ if (ext_csd_rev >= 5) { printf("Partition switching timing " "[PARTITION_SWITCH_TIME: 0x%02x]\n", ext_csd[199]); printf("Out-of-interrupt busy timing" " [OUT_OF_INTERRUPT_TIME: 0x%02x]\n", ext_csd[198]); } /* A441/A43: reserved [197] [195] [193] [190] [188] * [186] [184] [182] [180] [176] */ if (ext_csd_rev >= 6) printf("I/O Driver Strength [DRIVER_STRENGTH: 0x%02x]\n", ext_csd[197]); /* DEVICE_TYPE in A45, CARD_TYPE in A441 */ reg = ext_csd[196]; printf("Card Type [CARD_TYPE: 0x%02x]\n", reg); if (reg & 0x20) printf(" HS200 Single Data Rate eMMC @200MHz 1.2VI/O\n"); if (reg & 0x10) printf(" HS200 Single Data Rate eMMC @200MHz 1.8VI/O\n"); if (reg & 0x08) printf(" HS Dual Data Rate eMMC @52MHz 1.2VI/O\n"); if (reg & 0x04) printf(" HS Dual Data Rate eMMC @52MHz 1.8V or 3VI/O\n"); if (reg & 0x02) printf(" HS eMMC @52MHz - at rated device voltage(s)\n"); if (reg & 0x01) printf(" HS eMMC @26MHz - at rated device voltage(s)\n"); printf("CSD structure version [CSD_STRUCTURE: 0x%02x]\n", ext_csd[194]); /* ext_csd_rev = ext_csd[EXT_CSD_REV] (already done!!!) */ printf("Command set [CMD_SET: 0x%02x]\n", ext_csd[191]); printf("Command set revision [CMD_SET_REV: 0x%02x]\n", ext_csd[189]); printf("Power class [POWER_CLASS: 0x%02x]\n", ext_csd[187]); printf("High-speed interface timing [HS_TIMING: 0x%02x]\n", ext_csd[185]); /* bus_width: ext_csd[183] not readable */ printf("Erased memory content [ERASED_MEM_CONT: 0x%02x]\n", ext_csd[181]); reg = ext_csd[EXT_CSD_BOOT_CFG]; printf("Boot configuration bytes [PARTITION_CONFIG: 0x%02x]\n", reg); switch ((reg & EXT_CSD_BOOT_CFG_EN)>>3) { case 0x0: printf(" Not boot enable\n"); break; case 0x1: printf(" Boot Partition 1 enabled\n"); break; case 0x2: printf(" Boot Partition 2 enabled\n"); break; case 0x7: printf(" User Area Enabled for boot\n"); break; } switch (reg & EXT_CSD_BOOT_CFG_ACC) { case 0x0: printf(" No access to boot partition\n"); break; case 0x1: printf(" R/W Boot Partition 1\n"); break; case 0x2: printf(" R/W Boot Partition 2\n"); break; case 0x3: printf(" R/W Replay Protected Memory Block (RPMB)\n"); break; default: printf(" Access to General Purpose partition %d\n", (reg & EXT_CSD_BOOT_CFG_ACC) - 3); break; } printf("Boot config protection [BOOT_CONFIG_PROT: 0x%02x]\n", ext_csd[178]); printf("Boot bus Conditions [BOOT_BUS_CONDITIONS: 0x%02x]\n", ext_csd[177]); printf("High-density erase group definition" " [ERASE_GROUP_DEF: 0x%02x]\n", ext_csd[EXT_CSD_ERASE_GROUP_DEF]); print_writeprotect_status(ext_csd); if (ext_csd_rev >= 5) { /* A441]: reserved [172] */ printf("User area write protection register" " [USER_WP]: 0x%02x\n", ext_csd[171]); /* A441]: reserved [170] */ printf("FW configuration [FW_CONFIG]: 0x%02x\n", ext_csd[169]); printf("RPMB Size [RPMB_SIZE_MULT]: 0x%02x\n", ext_csd[168]); reg = ext_csd[EXT_CSD_WR_REL_SET]; const char * const fast = "existing data is at risk if a power " "failure occurs during a write operation"; const char * const reliable = "the device protects existing " "data if a power failure occurs during a write " "operation"; printf("Write reliability setting register" " [WR_REL_SET]: 0x%02x\n", reg); printf(" user area: %s\n", reg & (1<<0) ? reliable : fast); int i; for (i = 1; i <= 4; i++) { printf(" partition %d: %s\n", i, reg & (1<= 6) { int j; /* tcase_support ext_csd[132] not readable */ printf("Periodic Wake-up [PERIODIC_WAKEUP]: 0x%02x\n", ext_csd[131]); printf("Program CID/CSD in DDR mode support" " [PROGRAM_CID_CSD_DDR_SUPPORT]: 0x%02x\n", ext_csd[130]); for (j = 127; j >= 64; j--) printf("Vendor Specific Fields" " [VENDOR_SPECIFIC_FIELD[%d]]: 0x%02x\n", j, ext_csd[j]); printf("Native sector size [NATIVE_SECTOR_SIZE]: 0x%02x\n", ext_csd[63]); printf("Sector size emulation [USE_NATIVE_SECTOR]: 0x%02x\n", ext_csd[62]); printf("Sector size [DATA_SECTOR_SIZE]: 0x%02x\n", ext_csd[61]); printf("1st initialization after disabling sector" " size emulation [INI_TIMEOUT_EMU]: 0x%02x\n", ext_csd[60]); printf("Class 6 commands control [CLASS_6_CTRL]: 0x%02x\n", ext_csd[59]); printf("Number of addressed group to be Released" "[DYNCAP_NEEDED]: 0x%02x\n", ext_csd[58]); printf("Exception events control" " [EXCEPTION_EVENTS_CTRL]: 0x%04x\n", (ext_csd[57] << 8) | ext_csd[56]); printf("Exception events status" "[EXCEPTION_EVENTS_STATUS]: 0x%04x\n", (ext_csd[55] << 8) | ext_csd[54]); printf("Extended Partitions Attribute" " [EXT_PARTITIONS_ATTRIBUTE]: 0x%04x\n", (ext_csd[53] << 8) | ext_csd[52]); for (j = 51; j >= 37; j--) printf("Context configuration" " [CONTEXT_CONF[%d]]: 0x%02x\n", j, ext_csd[j]); printf("Packed command status" " [PACKED_COMMAND_STATUS]: 0x%02x\n", ext_csd[36]); printf("Packed command failure index" " [PACKED_FAILURE_INDEX]: 0x%02x\n", ext_csd[35]); printf("Power Off Notification" " [POWER_OFF_NOTIFICATION]: 0x%02x\n", ext_csd[34]); printf("Control to turn the Cache ON/OFF" " [CACHE_CTRL]: 0x%02x\n", ext_csd[33]); /* flush_cache ext_csd[32] not readable */ /*Reserved [31:0] */ } out_free: return ret; } int do_sanitize(int nargs, char **argv) { int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc sanitize \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = write_extcsd_value(fd, EXT_CSD_SANITIZE_START, 1); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", 1, EXT_CSD_SANITIZE_START, device); exit(1); } return ret; } #define DO_IO(func, fd, buf, nbyte) \ ({ \ ssize_t ret = 0, r; \ do { \ r = func(fd, buf + ret, nbyte - ret); \ if (r < 0 && errno != EINTR) { \ ret = -1; \ break; \ } \ else if (r > 0) \ ret += r; \ } while (r != 0 && (size_t)ret != nbyte); \ \ ret; \ }) enum rpmb_op_type { MMC_RPMB_WRITE_KEY = 0x01, MMC_RPMB_READ_CNT = 0x02, MMC_RPMB_WRITE = 0x03, MMC_RPMB_READ = 0x04, /* For internal usage only, do not use it directly */ MMC_RPMB_READ_RESP = 0x05 }; struct rpmb_frame { u_int8_t stuff[196]; u_int8_t key_mac[32]; u_int8_t data[256]; u_int8_t nonce[16]; u_int32_t write_counter; u_int16_t addr; u_int16_t block_count; u_int16_t result; u_int16_t req_resp; }; /* Performs RPMB operation. * * @fd: RPMB device on which we should perform ioctl command * @frame_in: input RPMB frame, should be properly inited * @frame_out: output (result) RPMB frame. Caller is responsible for checking * result and req_resp for output frame. * @out_cnt: count of outer frames. Used only for multiple blocks reading, * in the other cases -EINVAL will be returned. */ static int do_rpmb_op(int fd, const struct rpmb_frame *frame_in, struct rpmb_frame *frame_out, unsigned int out_cnt) { int err; u_int16_t rpmb_type; struct mmc_ioc_cmd ioc = { .arg = 0x0, .blksz = 512, .blocks = 1, .write_flag = 1, .opcode = MMC_WRITE_MULTIPLE_BLOCK, .flags = MMC_RSP_SPI_R1 | MMC_RSP_R1 | MMC_CMD_ADTC, .data_ptr = (uintptr_t)frame_in }; if (!frame_in || !frame_out || !out_cnt) return -EINVAL; rpmb_type = be16toh(frame_in->req_resp); switch(rpmb_type) { case MMC_RPMB_WRITE: case MMC_RPMB_WRITE_KEY: if (out_cnt != 1) { err = -EINVAL; goto out; } /* Write request */ ioc.write_flag |= (1<<31); err = ioctl(fd, MMC_IOC_CMD, &ioc); if (err < 0) { err = -errno; goto out; } /* Result request */ memset(frame_out, 0, sizeof(*frame_out)); frame_out->req_resp = htobe16(MMC_RPMB_READ_RESP); ioc.write_flag = 1; ioc.data_ptr = (uintptr_t)frame_out; err = ioctl(fd, MMC_IOC_CMD, &ioc); if (err < 0) { err = -errno; goto out; } /* Get response */ ioc.write_flag = 0; ioc.opcode = MMC_READ_MULTIPLE_BLOCK; err = ioctl(fd, MMC_IOC_CMD, &ioc); if (err < 0) { err = -errno; goto out; } break; case MMC_RPMB_READ_CNT: if (out_cnt != 1) { err = -EINVAL; goto out; } /* fall through */ case MMC_RPMB_READ: /* Request */ err = ioctl(fd, MMC_IOC_CMD, &ioc); if (err < 0) { err = -errno; goto out; } /* Get response */ ioc.write_flag = 0; ioc.opcode = MMC_READ_MULTIPLE_BLOCK; ioc.blocks = out_cnt; ioc.data_ptr = (uintptr_t)frame_out; err = ioctl(fd, MMC_IOC_CMD, &ioc); if (err < 0) { err = -errno; goto out; } break; default: err = -EINVAL; goto out; } out: return err; } int do_rpmb_write_key(int nargs, char **argv) { int ret, dev_fd, key_fd; struct rpmb_frame frame_in = { .req_resp = htobe16(MMC_RPMB_WRITE_KEY) }, frame_out; CHECK(nargs != 3, "Usage: mmc rpmb write-key \n", exit(1)); dev_fd = open(argv[1], O_RDWR); if (dev_fd < 0) { perror("device open"); exit(1); } if (0 == strcmp(argv[2], "-")) key_fd = STDIN_FILENO; else { key_fd = open(argv[2], O_RDONLY); if (key_fd < 0) { perror("can't open key file"); exit(1); } } /* Read the auth key */ ret = DO_IO(read, key_fd, frame_in.key_mac, sizeof(frame_in.key_mac)); if (ret < 0) { perror("read the key"); exit(1); } else if (ret != sizeof(frame_in.key_mac)) { printf("Auth key must be %lu bytes length, but we read only %d, exit\n", (unsigned long)sizeof(frame_in.key_mac), ret); exit(1); } /* Execute RPMB op */ ret = do_rpmb_op(dev_fd, &frame_in, &frame_out, 1); if (ret != 0) { perror("RPMB ioctl failed"); exit(1); } /* Check RPMB response */ if (frame_out.result != 0) { printf("RPMB operation failed, retcode 0x%04x\n", be16toh(frame_out.result)); exit(1); } close(dev_fd); if (key_fd != STDIN_FILENO) close(key_fd); return ret; } int rpmb_read_counter(int dev_fd, unsigned int *cnt) { int ret; struct rpmb_frame frame_in = { .req_resp = htobe16(MMC_RPMB_READ_CNT) }, frame_out; /* Execute RPMB op */ ret = do_rpmb_op(dev_fd, &frame_in, &frame_out, 1); if (ret != 0) { perror("RPMB ioctl failed"); exit(1); } /* Check RPMB response */ if (frame_out.result != 0) return be16toh(frame_out.result); *cnt = be32toh(frame_out.write_counter); return 0; } int do_rpmb_read_counter(int nargs, char **argv) { int ret, dev_fd; unsigned int cnt; CHECK(nargs != 2, "Usage: mmc rpmb read-counter \n", exit(1)); dev_fd = open(argv[1], O_RDWR); if (dev_fd < 0) { perror("device open"); exit(1); } ret = rpmb_read_counter(dev_fd, &cnt); /* Check RPMB response */ if (ret != 0) { printf("RPMB operation failed, retcode 0x%04x\n", ret); exit(1); } close(dev_fd); printf("Counter value: 0x%08x\n", cnt); return ret; } int do_rpmb_read_block(int nargs, char **argv) { int i, ret, dev_fd, data_fd, key_fd = -1; uint16_t addr, blocks_cnt; unsigned char key[32]; struct rpmb_frame frame_in = { .req_resp = htobe16(MMC_RPMB_READ), }, *frame_out_p; CHECK(nargs != 5 && nargs != 6, "Usage: mmc rpmb read-block
[/path/to/key]\n", exit(1)); dev_fd = open(argv[1], O_RDWR); if (dev_fd < 0) { perror("device open"); exit(1); } /* Get block address */ errno = 0; addr = strtol(argv[2], NULL, 0); if (errno) { perror("incorrect address"); exit(1); } frame_in.addr = htobe16(addr); /* Get blocks count */ errno = 0; blocks_cnt = strtol(argv[3], NULL, 0); if (errno) { perror("incorrect blocks count"); exit(1); } if (!blocks_cnt) { printf("please, specify valid blocks count number\n"); exit(1); } frame_out_p = calloc(sizeof(*frame_out_p), blocks_cnt); if (!frame_out_p) { printf("can't allocate memory for RPMB outer frames\n"); exit(1); } /* Write 256b data */ if (0 == strcmp(argv[4], "-")) data_fd = STDOUT_FILENO; else { data_fd = open(argv[4], O_WRONLY | O_CREAT | O_APPEND, S_IRUSR | S_IWUSR); if (data_fd < 0) { perror("can't open output file"); exit(1); } } /* Key is specified */ if (nargs == 6) { if (0 == strcmp(argv[5], "-")) key_fd = STDIN_FILENO; else { key_fd = open(argv[5], O_RDONLY); if (key_fd < 0) { perror("can't open input key file"); exit(1); } } ret = DO_IO(read, key_fd, key, sizeof(key)); if (ret < 0) { perror("read the key data"); exit(1); } else if (ret != sizeof(key)) { printf("Data must be %lu bytes length, but we read only %d, exit\n", (unsigned long)sizeof(key), ret); exit(1); } } /* Execute RPMB op */ ret = do_rpmb_op(dev_fd, &frame_in, frame_out_p, blocks_cnt); if (ret != 0) { perror("RPMB ioctl failed"); exit(1); } /* Check RPMB response */ if (frame_out_p[blocks_cnt - 1].result != 0) { printf("RPMB operation failed, retcode 0x%04x\n", be16toh(frame_out_p[blocks_cnt - 1].result)); exit(1); } /* Do we have to verify data against key? */ if (nargs == 6) { unsigned char mac[32]; hmac_sha256_ctx ctx; struct rpmb_frame *frame_out = NULL; hmac_sha256_init(&ctx, key, sizeof(key)); for (i = 0; i < blocks_cnt; i++) { frame_out = &frame_out_p[i]; hmac_sha256_update(&ctx, frame_out->data, sizeof(*frame_out) - offsetof(struct rpmb_frame, data)); } hmac_sha256_final(&ctx, mac, sizeof(mac)); /* Impossible */ assert(frame_out); /* Compare calculated MAC and MAC from last frame */ if (memcmp(mac, frame_out->key_mac, sizeof(mac))) { printf("RPMB MAC missmatch\n"); exit(1); } } /* Write data */ for (i = 0; i < blocks_cnt; i++) { struct rpmb_frame *frame_out = &frame_out_p[i]; ret = DO_IO(write, data_fd, frame_out->data, sizeof(frame_out->data)); if (ret < 0) { perror("write the data"); exit(1); } else if (ret != sizeof(frame_out->data)) { printf("Data must be %lu bytes length, but we wrote only %d, exit\n", (unsigned long)sizeof(frame_out->data), ret); exit(1); } } free(frame_out_p); close(dev_fd); if (data_fd != STDOUT_FILENO) close(data_fd); if (key_fd != -1 && key_fd != STDIN_FILENO) close(key_fd); return ret; } int do_rpmb_write_block(int nargs, char **argv) { int ret, dev_fd, key_fd, data_fd; unsigned char key[32]; uint16_t addr; unsigned int cnt; struct rpmb_frame frame_in = { .req_resp = htobe16(MMC_RPMB_WRITE), .block_count = htobe16(1) }, frame_out; CHECK(nargs != 5, "Usage: mmc rpmb write-block
\n", exit(1)); dev_fd = open(argv[1], O_RDWR); if (dev_fd < 0) { perror("device open"); exit(1); } ret = rpmb_read_counter(dev_fd, &cnt); /* Check RPMB response */ if (ret != 0) { printf("RPMB read counter operation failed, retcode 0x%04x\n", ret); exit(1); } frame_in.write_counter = htobe32(cnt); /* Get block address */ errno = 0; addr = strtol(argv[2], NULL, 0); if (errno) { perror("incorrect address"); exit(1); } frame_in.addr = htobe16(addr); /* Read 256b data */ if (0 == strcmp(argv[3], "-")) data_fd = STDIN_FILENO; else { data_fd = open(argv[3], O_RDONLY); if (data_fd < 0) { perror("can't open input file"); exit(1); } } ret = DO_IO(read, data_fd, frame_in.data, sizeof(frame_in.data)); if (ret < 0) { perror("read the data"); exit(1); } else if (ret != sizeof(frame_in.data)) { printf("Data must be %lu bytes length, but we read only %d, exit\n", (unsigned long)sizeof(frame_in.data), ret); exit(1); } /* Read the auth key */ if (0 == strcmp(argv[4], "-")) key_fd = STDIN_FILENO; else { key_fd = open(argv[4], O_RDONLY); if (key_fd < 0) { perror("can't open key file"); exit(1); } } ret = DO_IO(read, key_fd, key, sizeof(key)); if (ret < 0) { perror("read the key"); exit(1); } else if (ret != sizeof(key)) { printf("Auth key must be %lu bytes length, but we read only %d, exit\n", (unsigned long)sizeof(key), ret); exit(1); } /* Calculate HMAC SHA256 */ hmac_sha256( key, sizeof(key), frame_in.data, sizeof(frame_in) - offsetof(struct rpmb_frame, data), frame_in.key_mac, sizeof(frame_in.key_mac)); /* Execute RPMB op */ ret = do_rpmb_op(dev_fd, &frame_in, &frame_out, 1); if (ret != 0) { perror("RPMB ioctl failed"); exit(1); } /* Check RPMB response */ if (frame_out.result != 0) { printf("RPMB operation failed, retcode 0x%04x\n", be16toh(frame_out.result)); exit(1); } close(dev_fd); if (data_fd != STDIN_FILENO) close(data_fd); if (key_fd != STDIN_FILENO) close(key_fd); return ret; } int do_cache_ctrl(int value, int nargs, char **argv) { __u8 ext_csd[512]; int fd, ret; char *device; CHECK(nargs != 2, "Usage: mmc cache enable \n", exit(1)); device = argv[1]; fd = open(device, O_RDWR); if (fd < 0) { perror("open"); exit(1); } ret = read_extcsd(fd, ext_csd); if (ret) { fprintf(stderr, "Could not read EXT_CSD from %s\n", device); exit(1); } if (ext_csd[EXT_CSD_REV] < EXT_CSD_REV_V4_5) { fprintf(stderr, "The CACHE option is only availabe on devices >= " "MMC 4.5 %s\n", device); exit(1); } /* If the cache size is zero, this device does not have a cache */ if (!(ext_csd[EXT_CSD_CACHE_SIZE_3] || ext_csd[EXT_CSD_CACHE_SIZE_2] || ext_csd[EXT_CSD_CACHE_SIZE_1] || ext_csd[EXT_CSD_CACHE_SIZE_0])) { fprintf(stderr, "The CACHE option is not available on %s\n", device); exit(1); } ret = write_extcsd_value(fd, EXT_CSD_CACHE_CTRL, value); if (ret) { fprintf(stderr, "Could not write 0x%02x to EXT_CSD[%d] in %s\n", value, EXT_CSD_CACHE_CTRL, device); exit(1); } return ret; } int do_cache_en(int nargs, char **argv) { return do_cache_ctrl(1, nargs, argv); } int do_cache_dis(int nargs, char **argv) { return do_cache_ctrl(0, nargs, argv); }