/* * Copyright (c) 2009-2018 Douglas Gilbert. * All rights reserved. * Use of this source code is governed by a BSD-style * license that can be found in the BSD_LICENSE file. */ #include <stdio.h> #include <stdlib.h> #include <stdarg.h> #include <stdbool.h> #include <string.h> #include <ctype.h> #define __STDC_FORMAT_MACROS 1 #include <inttypes.h> #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "sg_lib.h" #include "sg_pt.h" #include "sg_pt_nvme.h" static const char * scsi_pt_version_str = "3.03 20180115"; static const char * nvme_scsi_vendor_str = "NVMe "; const char * scsi_pt_version() { return scsi_pt_version_str; } /* Given the NVMe Identify controller response and optionally the NVMe * Identify namespace response (NULL otherwise), generate the SCSI VPD * page 0x83 (device identification) descriptor(s) in dop. Return the * number of bytes written which will not exceed max_do_len. Probably use * Peripheral Device Type (pdt) of 0 (disk) for don't know. Transport * protocol (tproto) should be -1 if not known, else SCSI value. * N.B. Does not write total VPD page length into dop[2:3] . */ int sg_make_vpd_devid_for_nvme(const uint8_t * nvme_id_ctl_p, const uint8_t * nvme_id_ns_p, int pdt, int tproto, uint8_t * dop, int max_do_len) { bool have_nguid, have_eui64; int k, n; char b[4]; if ((NULL == nvme_id_ctl_p) || (NULL == dop) || (max_do_len < 56)) return 0; memset(dop, 0, max_do_len); dop[0] = 0x1f & pdt; /* (PQ=0)<<5 | (PDT=pdt); 0 or 0xd (SES) */ dop[1] = 0x83; /* Device Identification VPD page number */ /* Build a T10 Vendor ID based designator (desig_id=1) for controller */ if (tproto >= 0) { dop[4] = ((0xf & tproto) << 4) | 0x2; dop[5] = 0xa1; /* PIV=1, ASSOC=2 (target device), desig_id=1 */ } else { dop[4] = 0x2; /* Prococol id=0, code_set=2 (ASCII) */ dop[5] = 0x21; /* PIV=0, ASSOC=2 (target device), desig_id=1 */ } memcpy(dop + 8, nvme_scsi_vendor_str, 8); /* N.B. this is "NVMe " */ memcpy(dop + 16, nvme_id_ctl_p + 24, 40); /* MN */ for (k = 40; k > 0; --k) { if (' ' == dop[15 + k]) dop[15 + k] = '_'; /* convert trailing spaces */ else break; } if (40 == k) --k; n = 16 + 1 + k; if (max_do_len < (n + 20)) return 0; memcpy(dop + n, nvme_id_ctl_p + 4, 20); /* SN */ for (k = 20; k > 0; --k) { /* trim trailing spaces */ if (' ' == dop[n + k - 1]) dop[n + k - 1] = '\0'; else break; } n += k; if (0 != (n % 4)) n = ((n / 4) + 1) * 4; /* round up to next modulo 4 */ dop[7] = n - 8; if (NULL == nvme_id_ns_p) return n; /* Look for NGUID (16 byte identifier) or EUI64 (8 byte) fields in * NVME Identify for namespace. If found form a EUI and a SCSI string * descriptor for non-zero NGUID or EUI64 (prefer NGUID if both). */ have_nguid = ! sg_all_zeros(nvme_id_ns_p + 104, 16); have_eui64 = ! sg_all_zeros(nvme_id_ns_p + 120, 8); if ((! have_nguid) && (! have_eui64)) return n; if (have_nguid) { if (max_do_len < (n + 20)) return n; dop[n + 0] = 0x1; /* Prococol id=0, code_set=1 (binary) */ dop[n + 1] = 0x02; /* PIV=0, ASSOC=0 (lu), desig_id=2 (eui) */ dop[n + 3] = 16; memcpy(dop + n + 4, nvme_id_ns_p + 104, 16); n += 20; if (max_do_len < (n + 40)) return n; dop[n + 0] = 0x3; /* Prococol id=0, code_set=3 (utf8) */ dop[n + 1] = 0x08; /* PIV=0, ASSOC=0 (lu), desig_id=8 (scsi string) */ dop[n + 3] = 36; memcpy(dop + n + 4, "eui.", 4); for (k = 0; k < 16; ++k) { snprintf(b, sizeof(b), "%02X", nvme_id_ns_p[104 + k]); memcpy(dop + n + 8 + (2 * k), b, 2); } return n + 40; } else { /* have_eui64 is true, 8 byte identifier */ if (max_do_len < (n + 12)) return n; dop[n + 0] = 0x1; /* Prococol id=0, code_set=1 (binary) */ dop[n + 1] = 0x02; /* PIV=0, ASSOC=0 (lu), desig_id=2 (eui) */ dop[n + 3] = 8; memcpy(dop + n + 4, nvme_id_ns_p + 120, 8); n += 12; if (max_do_len < (n + 24)) return n; dop[n + 0] = 0x3; /* Prococol id=0, code_set=3 (utf8) */ dop[n + 1] = 0x08; /* PIV=0, ASSOC=0 (lu), desig_id=8 (scsi string) */ dop[n + 3] = 20; memcpy(dop + n + 4, "eui.", 4); for (k = 0; k < 8; ++k) { snprintf(b, sizeof(b), "%02X", nvme_id_ns_p[120 + k]); memcpy(dop + n + 8 + (2 * k), b, 2); } return n + 24; } }