// SPDX-License-Identifier: GPL-2.0-only /* * Read encryption information for Opal and ATA devices. * * Copyright (C) 2024 Intel Corporation * Author: Blazej Kucman */ #include "mdadm.h" #include #include #include #include #include "drive_encryption.h" #define DEFAULT_SECTOR_SIZE (512) /* * Opal defines * TCG Storage Opal SSC 2.01 chapter 3.3.3 * NVM ExpressTM Revision 1.4c, chapter 5 */ #define TCG_SECP_01 (0x01) #define TCG_SECP_00 (0x00) #define OPAL_DISCOVERY_COMID (0x0001) #define OPAL_LOCKING_FEATURE (0x0002) #define OPAL_IO_BUFFER_LEN 2048 #define OPAL_DISCOVERY_FEATURE_HEADER_LEN (4) /* * NVMe defines * NVM ExpressTM Revision 1.4c, chapter 5 */ #define NVME_SECURITY_RECV (0x82) #define NVME_IDENTIFY (0x06) #define NVME_IDENTIFY_RESPONSE_LEN 4096 #define NVME_OACS_BYTE_POSITION (256) #define NVME_IDENTIFY_CONTROLLER_DATA (1) /* * ATA defines * ATA/ATAPI Command Set ATA8-ACS * SCSI / ATA Translation - 3 (SAT-3) * SCSI Primary Commands - 4 (SPC-4) * AT Attachment-8 - ATA Serial Transport (ATA8-AST) * ATA Command Pass-Through */ #define ATA_IDENTIFY (0xec) #define ATA_TRUSTED_RECEIVE (0x5c) #define ATA_SECURITY_WORD_POSITION (128) #define HDIO_DRIVE_CMD (0x031f) #define ATA_TRUSTED_COMPUTING_POS (48) #define ATA_PASS_THROUGH_12 (0xa1) #define ATA_IDENTIFY_RESPONSE_LEN (512) #define ATA_PIO_DATA_IN (4) #define SG_CHECK_CONDITION (0x02) #define ATA_STATUS_RETURN_DESCRIPTOR (0x09) #define ATA_PT_INFORMATION_AVAILABLE_ASCQ (0x1d) #define ATA_PT_INFORMATION_AVAILABLE_ASC (0x00) #define ATA_INQUIRY_LENGTH (0x0c) #define SG_INTERFACE_ID 'S' #define SG_IO_TIMEOUT (60000) #define SG_SENSE_SIZE (32) #define SENSE_DATA_CURRENT_FIXED (0x70) #define SENSE_DATA_CURRENT_DESC (0x72) #define SENSE_CURRENT_RES_DESC_POS (8) #define SG_DRIVER_SENSE (0x08) typedef enum drive_feature_support_status { /* Drive feature is supported. */ DRIVE_FEAT_SUP_ST = 0, /* Drive feature is not supported. */ DRIVE_FEAT_NOT_SUP_ST, /* Drive feature support check failed. */ DRIVE_FEAT_CHECK_FAILED_ST } drive_feat_sup_st; /* TCG Storage Opal SSC 2.01 chapter 3.1.1.3 */ typedef struct opal_locking_feature { /* feature header */ __u16 feature_code; __u8 reserved : 4; __u8 version : 4; __u8 description_length; /* feature description */ __u8 locking_supported : 1; __u8 locking_enabled : 1; __u8 locked : 1; __u8 media_encryption : 1; __u8 mbr_enabled : 1; __u8 mbr_done : 1; __u8 mbr_shadowing_not_supported : 1; __u8 hw_reset_for_dor_supported : 1; __u8 reserved1[11]; } __attribute__((__packed__)) opal_locking_feature_t; /* TCG Storage Opal SSC 2.01 chapter 3.1.1.1 */ typedef struct opal_level0_header { __u32 length; __u32 version; __u64 reserved; __u8 vendor_specific[32]; } opal_level0_header_t; /** * NVM ExpressTM Revision 1.4c, Figure 249 * Structure specifies only OACS filed, which is needed in the current use case. */ typedef struct nvme_identify_ctrl { __u8 reserved[255]; __u16 oacs; __u8 reserved2[3839]; } nvme_identify_ctrl_t; /* SCSI Primary Commands - 4 (SPC-4), Table 512 */ typedef struct supported_security_protocols { __u8 reserved[6]; __u16 list_length; __u8 list[504]; } supported_security_protocols_t; /* ATA/ATAPI Command Set - 3 (ACS-3), Table 45 */ typedef struct ata_security_status { __u16 security_supported : 1; __u16 security_enabled : 1; __u16 security_locked : 1; __u16 security_frozen : 1; __u16 security_count_expired : 1; __u16 enhanced_security_erase_supported : 1; __u16 reserved1 : 2; __u16 security_level : 1; __u16 reserved2 : 7; } __attribute__((__packed__)) ata_security_status_t; /* ATA/ATAPI Command Set - 3 (ACS-3), Table 45 */ typedef struct ata_trusted_computing { __u16 tc_feature :1; __u16 reserved : 13; __u16 var1 : 1; __u16 var2 : 1; } __attribute__((__packed__)) ata_trusted_computing_t; mapping_t encryption_ability_map[] = { { "None", ENC_ABILITY_NONE }, { "Other", ENC_ABILITY_OTHER }, { "SED", ENC_ABILITY_SED }, { NULL, UnSet } }; mapping_t encryption_status_map[] = { { "Unencrypted", ENC_STATUS_UNENCRYPTED }, { "Locked", ENC_STATUS_LOCKED }, { "Unlocked", ENC_STATUS_UNLOCKED }, { NULL, UnSet } }; /** * get_encryption_ability_string() - get encryption ability name string. * @ability: encryption ability enum. * * Return: encryption ability string. */ const char *get_encryption_ability_string(enum encryption_ability ability) { return map_num_s(encryption_ability_map, ability); } /** * get_encryption_status_string() - get encryption status name string. * @ability: encryption status enum. * * Return: encryption status string. */ const char *get_encryption_status_string(enum encryption_status status) { return map_num_s(encryption_status_map, status); } /** * get_opal_locking_feature_description() - get opal locking feature description. * @response: response from Opal Discovery Level 0. * * Based on the documentation TCG Storage Opal SSC 2.01 chapter 3.1.1, * a Locking feature is searched for in Opal Level 0 Discovery response. * * Return: if locking feature is found, pointer to struct %opal_locking_feature_t, NULL otherwise. */ static opal_locking_feature_t *get_opal_locking_feature_description(__u8 *response) { opal_level0_header_t *response_header = (opal_level0_header_t *)response; int features_length = __be32_to_cpu(response_header->length); int current_position = sizeof(*response_header); while (current_position < features_length) { opal_locking_feature_t *feature; feature = (opal_locking_feature_t *)(response + current_position); if (__be16_to_cpu(feature->feature_code) == OPAL_LOCKING_FEATURE) return feature; current_position += feature->description_length + OPAL_DISCOVERY_FEATURE_HEADER_LEN; } return NULL; } /** * nvme_security_recv_ioctl() - nvme security receive ioctl. * @disk_fd: a disk file descriptor. * @sec_protocol: security protocol. * @comm_id: command id. * @response_buffer: response buffer to fill out. * @buf_size: response buffer size. * @verbose: verbose flag. * * Based on the documentations TCG Storage Opal SSC 2.01 chapter 3.3.3 and * NVM ExpressTM Revision 1.4c, chapter 5.25, * read security receive command via ioctl(). * On success, @response_buffer is completed. * * Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise. */ static mdadm_status_t nvme_security_recv_ioctl(int disk_fd, __u8 sec_protocol, __u16 comm_id, void *response_buffer, size_t buf_size, const int verbose) { struct nvme_admin_cmd nvme_cmd = {0}; int status; nvme_cmd.opcode = NVME_SECURITY_RECV; nvme_cmd.cdw10 = sec_protocol << 24 | comm_id << 8; nvme_cmd.cdw11 = buf_size; nvme_cmd.data_len = buf_size; nvme_cmd.addr = (__u64)response_buffer; status = ioctl(disk_fd, NVME_IOCTL_ADMIN_CMD, &nvme_cmd); if (status != 0) { pr_vrb("Failed to read NVMe security receive ioctl() for device /dev/%s, status: %d\n", fd2kname(disk_fd), status); return MDADM_STATUS_ERROR; } return MDADM_STATUS_SUCCESS; } /** * nvme_identify_ioctl() - NVMe identify ioctl. * @disk_fd: a disk file descriptor. * @response_buffer: response buffer to fill out. * @buf_size: response buffer size. * @verbose: verbose flag. * * Based on the documentations TCG Storage Opal SSC 2.01 chapter 3.3.3 and * NVM ExpressTM Revision 1.4c, chapter 5.25, * read NVMe identify via ioctl(). * On success, @response_buffer will be completed. * * Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise. */ static mdadm_status_t nvme_identify_ioctl(int disk_fd, void *response_buffer, size_t buf_size, const int verbose) { struct nvme_admin_cmd nvme_cmd = {0}; int status; nvme_cmd.opcode = NVME_IDENTIFY; nvme_cmd.cdw10 = NVME_IDENTIFY_CONTROLLER_DATA; nvme_cmd.data_len = buf_size; nvme_cmd.addr = (__u64)response_buffer; status = ioctl(disk_fd, NVME_IOCTL_ADMIN_CMD, &nvme_cmd); if (status != 0) { pr_vrb("Failed to read NVMe identify ioctl() for device /dev/%s, status: %d\n", fd2kname(disk_fd), status); return MDADM_STATUS_ERROR; } return MDADM_STATUS_SUCCESS; } /** * is_sec_prot_01h_supported() - check if security protocol 01h supported. * @security_protocols: struct with response from disk (NVMe, SATA) describing supported * security protocols. * * Return: true if TCG_SECP_01 found, false otherwise. */ static bool is_sec_prot_01h_supported(supported_security_protocols_t *security_protocols) { int list_length = be16toh(security_protocols->list_length); int index; for (index = 0 ; index < list_length; index++) { if (security_protocols->list[index] == TCG_SECP_01) return true; } return false; } /** * is_sec_prot_01h_supported_nvme() - check if security protocol 01h supported for given NVMe disk. * @disk_fd: a disk file descriptor. * @verbose: verbose flag. * * Return: %DRIVE_FEAT_SUP_ST if TCG_SECP_01 supported, %DRIVE_FEAT_NOT_SUP_ST if not supported, * %DRIVE_FEAT_CHECK_FAILED_ST if failed to check. */ static drive_feat_sup_st is_sec_prot_01h_supported_nvme(int disk_fd, const int verbose) { supported_security_protocols_t security_protocols = {0}; /* security_protocol: TCG_SECP_00, comm_id: not applicable */ if (nvme_security_recv_ioctl(disk_fd, TCG_SECP_00, 0x0, &security_protocols, sizeof(security_protocols), verbose)) return DRIVE_FEAT_CHECK_FAILED_ST; if (is_sec_prot_01h_supported(&security_protocols)) return DRIVE_FEAT_SUP_ST; return DRIVE_FEAT_NOT_SUP_ST; } /** * is_nvme_sec_send_recv_supported() - check if Security Send and Security Receive is supported. * @disk_fd: a disk file descriptor. * @verbose: verbose flag. * * Check if "Optional Admin Command Support" bit 0 is set in NVMe identify. * Bit 0 set to 1 means controller supports the Security Send and Security Receive commands. * * Return: %DRIVE_FEAT_SUP_ST if security send/receive supported, * %DRIVE_FEAT_NOT_SUP_ST if not supported, %DRIVE_FEAT_CHECK_FAILED_ST if check failed. */ static drive_feat_sup_st is_nvme_sec_send_recv_supported(int disk_fd, const int verbose) { nvme_identify_ctrl_t nvme_identify = {0}; int status = 0; status = nvme_identify_ioctl(disk_fd, &nvme_identify, sizeof(nvme_identify), verbose); if (status) return DRIVE_FEAT_CHECK_FAILED_ST; if ((__le16_to_cpu(nvme_identify.oacs) & 0x1) == 0x1) return DRIVE_FEAT_SUP_ST; return DRIVE_FEAT_NOT_SUP_ST; } /** * get_opal_encryption_information() - get Opal encryption information. * @buffer: buffer with Opal Level 0 Discovery response. * @information: struct to fill out, describing encryption status of disk. * * If Locking feature frame is in response from Opal Level 0 discovery, &encryption_information_t * structure is completed with status and ability otherwise the status is set to &None. * For possible encryption statuses and abilities, * please refer to enums &encryption_status and &encryption_ability. * * Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise. */ static mdadm_status_t get_opal_encryption_information(__u8 *buffer, encryption_information_t *information) { opal_locking_feature_t *opal_locking_feature = get_opal_locking_feature_description(buffer); if (!opal_locking_feature) return MDADM_STATUS_ERROR; if (opal_locking_feature->locking_supported == 1) { information->ability = ENC_ABILITY_SED; if (opal_locking_feature->locking_enabled == 0) information->status = ENC_STATUS_UNENCRYPTED; else if (opal_locking_feature->locked == 1) information->status = ENC_STATUS_LOCKED; else information->status = ENC_STATUS_UNLOCKED; } else { information->ability = ENC_ABILITY_NONE; information->status = ENC_STATUS_UNENCRYPTED; } return MDADM_STATUS_SUCCESS; } /** * get_nvme_opal_encryption_information() - get NVMe Opal encryption information. * @disk_fd: a disk file descriptor. * @information: struct to fill out, describing encryption status of disk. * @verbose: verbose flag. * * In case the disk supports Opal Level 0 discovery, &encryption_information_t structure * is completed with status and ability based on ioctl response, * otherwise the ability is set to %ENC_ABILITY_NONE and &status to %ENC_STATUS_UNENCRYPTED. * As the current use case does not need the knowledge of Opal support, if there is no support, * %MDADM_STATUS_SUCCESS will be returned, with the values described above. * For possible encryption statuses and abilities, * please refer to enums &encryption_status and &encryption_ability. * * %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise. */ mdadm_status_t get_nvme_opal_encryption_information(int disk_fd, encryption_information_t *information, const int verbose) { __u8 buffer[OPAL_IO_BUFFER_LEN]; int sec_send_recv_supported = 0; int protocol_01h_supported = 0; mdadm_status_t status; information->ability = ENC_ABILITY_NONE; information->status = ENC_STATUS_UNENCRYPTED; sec_send_recv_supported = is_nvme_sec_send_recv_supported(disk_fd, verbose); if (sec_send_recv_supported == DRIVE_FEAT_CHECK_FAILED_ST) return MDADM_STATUS_ERROR; /* Opal not supported */ if (sec_send_recv_supported == DRIVE_FEAT_NOT_SUP_ST) return MDADM_STATUS_SUCCESS; /** * sec_send_recv_supported determine that it should be possible to read * supported sec protocols */ protocol_01h_supported = is_sec_prot_01h_supported_nvme(disk_fd, verbose); if (protocol_01h_supported == DRIVE_FEAT_CHECK_FAILED_ST) return MDADM_STATUS_ERROR; /* Opal not supported */ if (sec_send_recv_supported == DRIVE_FEAT_SUP_ST && protocol_01h_supported == DRIVE_FEAT_NOT_SUP_ST) return MDADM_STATUS_SUCCESS; if (nvme_security_recv_ioctl(disk_fd, TCG_SECP_01, OPAL_DISCOVERY_COMID, (void *)&buffer, OPAL_IO_BUFFER_LEN, verbose)) return MDADM_STATUS_ERROR; status = get_opal_encryption_information((__u8 *)&buffer, information); if (status) pr_vrb("Locking feature description not found in Level 0 discovery response. Device /dev/%s.\n", fd2kname(disk_fd)); if (information->ability == ENC_ABILITY_NONE) assert(information->status == ENC_STATUS_UNENCRYPTED); return status; } /** * ata_pass_through12_ioctl() - ata pass through12 ioctl. * @disk_fd: a disk file descriptor. * @ata_command: ata command. * @sec_protocol: security protocol. * @comm_id: additional command id. * @response_buffer: response buffer to fill out. * @buf_size: response buffer size. * @verbose: verbose flag. * * Based on the documentations ATA Command Pass-Through, chapter 13.2.2 and * ATA Translation - 3 (SAT-3), send read ata pass through 12 command via ioctl(). * On success, @response_buffer will be completed. * * Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR on fail. */ static mdadm_status_t ata_pass_through12_ioctl(int disk_fd, __u8 ata_command, __u8 sec_protocol, __u16 comm_id, void *response_buffer, size_t buf_size, const int verbose) { __u8 cdb[ATA_INQUIRY_LENGTH] = {0}; __u8 sense[SG_SENSE_SIZE] = {0}; __u8 *sense_desc = NULL; sg_io_hdr_t sg = {0}; /* * ATA Command Pass-Through, chapter 13.2.2 * SCSI Primary Commands - 4 (SPC-4) * ATA Translation - 3 (SAT-3) */ cdb[0] = ATA_PASS_THROUGH_12; /* protocol, bits 1-4 */ cdb[1] = ATA_PIO_DATA_IN << 1; /* Bytes: CK_COND=1, T_DIR = 1, BYTE_BLOCK = 1, Length in Sector Count = 2 */ cdb[2] = 0x2E; cdb[3] = sec_protocol; /* Sector count */ cdb[4] = buf_size / DEFAULT_SECTOR_SIZE; cdb[6] = (comm_id) & 0xFF; cdb[7] = (comm_id >> 8) & 0xFF; cdb[9] = ata_command; sg.interface_id = SG_INTERFACE_ID; sg.cmd_len = sizeof(cdb); sg.mx_sb_len = sizeof(sense); sg.dxfer_direction = SG_DXFER_FROM_DEV; sg.dxfer_len = buf_size; sg.dxferp = response_buffer; sg.cmdp = cdb; sg.sbp = sense; sg.timeout = SG_IO_TIMEOUT; sg.usr_ptr = NULL; if (ioctl(disk_fd, SG_IO, &sg) < 0) { pr_vrb("Failed ata passthrough12 ioctl. Device: /dev/%s.\n", fd2kname(disk_fd)); return MDADM_STATUS_ERROR; } if ((sg.status && sg.status != SG_CHECK_CONDITION) || sg.host_status || (sg.driver_status && sg.driver_status != SG_DRIVER_SENSE)) { pr_vrb("Failed ata passthrough12 ioctl. Device: /dev/%s.\n", fd2kname(disk_fd)); pr_vrb("SG_IO error: ATA_12 Status: %d Host Status: %d, Driver Status: %d\n", sg.status, sg.host_status, sg.driver_status); return MDADM_STATUS_ERROR; } /* verify expected sense response code */ if (!(sense[0] == SENSE_DATA_CURRENT_DESC || sense[0] == SENSE_DATA_CURRENT_FIXED)) { pr_vrb("Failed ata passthrough12 ioctl. Device: /dev/%s.\n", fd2kname(disk_fd)); return MDADM_STATUS_ERROR; } sense_desc = sense + SENSE_CURRENT_RES_DESC_POS; /* verify sense data current response with descriptor format */ if (sense[0] == SENSE_DATA_CURRENT_DESC && !(sense_desc[0] == ATA_STATUS_RETURN_DESCRIPTOR && sense_desc[1] == ATA_INQUIRY_LENGTH)) { pr_vrb("Failed ata passthrough12 ioctl. Device: /dev/%s. Sense data ASC: %d, ASCQ: %d.\n", fd2kname(disk_fd), sense[2], sense[3]); return MDADM_STATUS_ERROR; } /* verify sense data current response with fixed format */ if (sense[0] == SENSE_DATA_CURRENT_FIXED && !(sense[12] == ATA_PT_INFORMATION_AVAILABLE_ASC && sense[13] == ATA_PT_INFORMATION_AVAILABLE_ASCQ)) { pr_vrb("Failed ata passthrough12 ioctl. Device: /dev/%s. Sense data ASC: %d, ASCQ: %d.\n", fd2kname(disk_fd), sense[12], sense[13]); return MDADM_STATUS_ERROR; } return MDADM_STATUS_SUCCESS; } /** * is_sec_prot_01h_supported_ata() - check if security protocol 01h supported for given SATA disk. * @disk_fd: a disk file descriptor. * @verbose: verbose flag. * * Return: %DRIVE_FEAT_SUP_ST if TCG_SECP_01 supported, %DRIVE_FEAT_NOT_SUP_ST if not supported, * %DRIVE_FEAT_CHECK_FAILED_ST if failed. */ static drive_feat_sup_st is_sec_prot_01h_supported_ata(int disk_fd, const int verbose) { supported_security_protocols_t security_protocols; mdadm_status_t result = ata_pass_through12_ioctl(disk_fd, ATA_TRUSTED_RECEIVE, TCG_SECP_00, 0x0, &security_protocols, sizeof(security_protocols), verbose); if (result) return DRIVE_FEAT_CHECK_FAILED_ST; if (is_sec_prot_01h_supported(&security_protocols)) return DRIVE_FEAT_SUP_ST; return DRIVE_FEAT_NOT_SUP_ST; } /** * is_ata_trusted_computing_supported() - check if ata trusted computing supported. * @buffer: buffer with ATA identify response, not NULL. * * Return: true if trusted computing bit set, false otherwise. */ bool is_ata_trusted_computing_supported(__u16 *buffer) { /* Added due to warnings from the compiler about a possible uninitialized variable below. */ assert(buffer); __u16 security_tc_frame = __le16_to_cpu(buffer[ATA_TRUSTED_COMPUTING_POS]); ata_trusted_computing_t *security_tc = (ata_trusted_computing_t *)&security_tc_frame; if (security_tc->tc_feature == 1) return true; return false; } /** * get_ata_standard_security_status() - get ATA disk encryption information from ATA identify. * @buffer: buffer with response from ATA identify, not NULL. * @information: struct to fill out, describing encryption status of disk. * * The function based on the Security status frame from ATA identify, * completed encryption information. * For possible encryption statuses and abilities, * please refer to enums &encryption_status and &encryption_ability. * * Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR on fail. */ static mdadm_status_t get_ata_standard_security_status(__u16 *buffer, struct encryption_information *information) { /* Added due to warnings from the compiler about a possible uninitialized variable below. */ assert(buffer); __u16 security_status_frame = __le16_to_cpu(buffer[ATA_SECURITY_WORD_POSITION]); ata_security_status_t *security_status = (ata_security_status_t *)&security_status_frame; if (!security_status->security_supported) { information->ability = ENC_ABILITY_NONE; information->status = ENC_STATUS_UNENCRYPTED; return MDADM_STATUS_SUCCESS; } information->ability = ENC_ABILITY_OTHER; if (security_status->security_enabled == 0) information->status = ENC_STATUS_UNENCRYPTED; else if (security_status->security_locked == 1) information->status = ENC_STATUS_LOCKED; else information->status = ENC_STATUS_UNLOCKED; return MDADM_STATUS_SUCCESS; } /** * is_ata_opal() - check if SATA disk support Opal. * @disk_fd: a disk file descriptor. * @buffer: buffer with ATA identify response. * @verbose: verbose flag. * * Return: %DRIVE_FEAT_SUP_ST if TCG_SECP_01 supported, %DRIVE_FEAT_NOT_SUP_ST if not supported, * %DRIVE_FEAT_CHECK_FAILED_ST if failed to check. */ static drive_feat_sup_st is_ata_opal(int disk_fd, __u16 *buffer_identify, const int verbose) { bool tc_status = is_ata_trusted_computing_supported(buffer_identify); drive_feat_sup_st tcg_sec_prot_status; if (!tc_status) return DRIVE_FEAT_NOT_SUP_ST; tcg_sec_prot_status = is_sec_prot_01h_supported_ata(disk_fd, verbose); if (tcg_sec_prot_status == DRIVE_FEAT_CHECK_FAILED_ST) { pr_vrb("Failed to verify if security protocol 01h supported. Device /dev/%s.\n", fd2kname(disk_fd)); return DRIVE_FEAT_CHECK_FAILED_ST; } if (tc_status && tcg_sec_prot_status == DRIVE_FEAT_SUP_ST) return DRIVE_FEAT_SUP_ST; return DRIVE_FEAT_NOT_SUP_ST; } /** * get_ata_encryption_information() - get ATA disk encryption information. * @disk_fd: a disk file descriptor. * @information: struct to fill out, describing encryption status of disk. * @verbose: verbose flag. * * The function reads information about encryption, if the disk supports Opal, * the information is completed based on Opal Level 0 discovery, otherwise, * based on ATA security status frame from ATA identification response. * For possible encryption statuses and abilities, * please refer to enums &encryption_status and &encryption_ability. * * Based on the documentations ATA/ATAPI Command Set ATA8-ACS and * AT Attachment-8 - ATA Serial Transport (ATA8-AST). * * Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR on fail. */ mdadm_status_t get_ata_encryption_information(int disk_fd, struct encryption_information *information, const int verbose) { __u8 buffer_opal_level0_discovery[OPAL_IO_BUFFER_LEN] = {0}; __u16 buffer_identify[ATA_IDENTIFY_RESPONSE_LEN] = {0}; drive_feat_sup_st ata_opal_status; mdadm_status_t status; /* Get disk ATA identification */ status = ata_pass_through12_ioctl(disk_fd, ATA_IDENTIFY, 0x0, 0x0, buffer_identify, sizeof(buffer_identify), verbose); if (status == MDADM_STATUS_ERROR) return MDADM_STATUS_ERROR; /* Possible OPAL support, further checks require tpm_enabled.*/ if (is_ata_trusted_computing_supported(buffer_identify)) { /* OPAL SATA encryption checking disabled. */ if (conf_get_sata_opal_encryption_no_verify()) return MDADM_STATUS_SUCCESS; if (!sysfs_is_libata_allow_tpm_enabled(verbose)) { pr_vrb("Detected SATA drive /dev/%s with Trusted Computing support.\n", fd2kname(disk_fd)); pr_vrb("Cannot verify encryption state. Requires libata.tpm_enabled=1.\n"); return MDADM_STATUS_ERROR; } } ata_opal_status = is_ata_opal(disk_fd, buffer_identify, verbose); if (ata_opal_status == DRIVE_FEAT_CHECK_FAILED_ST) return MDADM_STATUS_ERROR; if (ata_opal_status == DRIVE_FEAT_NOT_SUP_ST) return get_ata_standard_security_status(buffer_identify, information); /* SATA Opal */ status = ata_pass_through12_ioctl(disk_fd, ATA_TRUSTED_RECEIVE, TCG_SECP_01, OPAL_DISCOVERY_COMID, buffer_opal_level0_discovery, OPAL_IO_BUFFER_LEN, verbose); if (status != MDADM_STATUS_SUCCESS) return MDADM_STATUS_ERROR; return get_opal_encryption_information(buffer_opal_level0_discovery, information); }