diff options
Diffstat (limited to 'lib/sg_pt_freebsd.c')
-rw-r--r-- | lib/sg_pt_freebsd.c | 3168 |
1 files changed, 3168 insertions, 0 deletions
diff --git a/lib/sg_pt_freebsd.c b/lib/sg_pt_freebsd.c new file mode 100644 index 00000000..e0cd9575 --- /dev/null +++ b/lib/sg_pt_freebsd.c @@ -0,0 +1,3168 @@ +/* + * Copyright (c) 2005-2022 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. + * + * SPDX-License-Identifier: BSD-2-Clause + */ + +/* sg_pt_freebsd version 1.48 20220811 */ + +#include <stdio.h> +#include <stdlib.h> +#include <stdarg.h> +#include <stdbool.h> +#include <string.h> +#include <sys/types.h> +#include <dirent.h> +#include <limits.h> +#include <libgen.h> /* for basename */ +#include <fcntl.h> +#include <errno.h> +#define __STDC_FORMAT_MACROS 1 +#include <inttypes.h> /* from PRIx macros */ +#include <err.h> +#include <camlib.h> +#include <cam/scsi/scsi_message.h> +// #include <sys/ata.h> +#include <sys/stat.h> +#include <unistd.h> +#include <fcntl.h> +#include <glob.h> +#include <fcntl.h> +#include <stddef.h> + +#ifdef HAVE_CONFIG_H +#include "config.h" +#endif + +#include "sg_pt.h" +#include "sg_lib.h" +#include "sg_unaligned.h" +#include "sg_pt_nvme.h" +#include "sg_pr2serr.h" + +#if (HAVE_NVME && (! IGNORE_NVME)) +#include "freebsd_nvme_ioctl.h" +#else +#define NVME_CTRLR_PREFIX "/dev/nvme" +#define NVME_NS_PREFIX "ns" +#endif + +#define SG_NVME_NVD_PREFIX "/dev/nvd" /* >= FreeBSD 9.2 */ +#define SG_NVME_NDA_PREFIX "/dev/nda" /* >= FreeBSD 12.0, CAM compatible */ + +#define FREEBSD_MAXDEV 64 +#define FREEBSD_FDOFFSET 16; + +#if __FreeBSD_version > 500000 +#define CAM_ERROR_PRINT(a, b, c, d, e) cam_error_print(a, b, c, d, e); +#else +#define CAM_ERROR_PRINT(a, b, c, d, e) +#endif + + +struct freebsd_dev_channel { /* one instance per open file descriptor */ + bool is_nvme_dev; /* true if NVMe device attached, else SCSI */ + bool is_cam_nvme; /* NVMe via /dev/nda<n> or /dev/pass<n> devices */ + bool is_pass; /* CAM passthrough device (i.e. 'pass<n>') */ + int unitnum; /* the SCSI unit number, NVMe controller id? */ + uint32_t nsid; + // uint32_t nv_ctrlid; /* unitnum seems to have this role */ + int nvme_fd_ns; // for non-CAM NVMe, use -1 to indicate not provided + int nvme_fd_ctrl; // open("/dev/nvme<n>") if needed */ + char* devname; // from cam_get_device() or ioctl(NVME_GET_NSID) + struct cam_device* cam_dev; + uint8_t * nvme_id_ctlp; + uint8_t * free_nvme_id_ctlp; + struct sg_sntl_dev_state_t dev_stat; // owner +}; + +// Private table of open devices: guaranteed zero on startup since +// part of static data. +static struct freebsd_dev_channel *devicetable[FREEBSD_MAXDEV]; + +#define DEF_TIMEOUT 60000 /* 60,000 milliseconds (60 seconds) */ + +struct sg_pt_freebsd_scsi { /* context of one SCSI/NVME command (pt object) */ + union ccb *ccb; + uint8_t * cdb; + int cdb_len; + uint8_t * sense; + int sense_len; + uint8_t * dxferp; + int dxfer_len; + int dxfer_dir; /* CAM_DIR_NONE, _IN, _OUT and _BOTH */ + uint8_t * dxferip; + uint8_t * dxferop; + uint8_t * mdxferp; + uint32_t dxfer_ilen; + uint32_t dxfer_olen; + uint32_t mdxfer_len; + uint32_t nvme_result; // cdw0 from completion + uint16_t nvme_status; // from completion: ((sct << 8) | sc) + uint8_t cq_dw0_3[16]; + int timeout_ms; + int scsi_status; + int resid; + int sense_resid; + int in_err; + int os_err; + int transport_err; + int dev_han; // should be >= FREEBSD_FDOFFSET then + // (dev_han - FREEBSD_FDOFFSET) is the + // index into devicetable[] + bool mdxfer_out; + bool is_nvme_dev; /* copied from owning mchanp */ + bool nvme_our_sntl; /* true: our SNTL; false: received NVMe command */ + struct freebsd_dev_channel * mchanp; /* associated device info */ +}; + +struct sg_pt_base { + struct sg_pt_freebsd_scsi impl; +}; + +// static const uint32_t broadcast_nsid = SG_NVME_BROADCAST_NSID; + +#if (HAVE_NVME && (! IGNORE_NVME)) +static int sg_do_nvme_pt(struct sg_pt_freebsd_scsi * ptp, int fd, + bool is_admin, int timeout_secs, int vb); +#endif + + + +static struct freebsd_dev_channel * +get_fdc_p(struct sg_pt_freebsd_scsi * ptp) +{ + int han = ptp->dev_han - FREEBSD_FDOFFSET; + + if ((han < 0) || (han >= FREEBSD_MAXDEV)) + return NULL; + return devicetable[han]; +} + +static const struct freebsd_dev_channel * +get_fdc_cp(const struct sg_pt_freebsd_scsi * ptp) +{ + int han = ptp->dev_han - FREEBSD_FDOFFSET; + + if ((han < 0) || (han >= FREEBSD_MAXDEV)) + return NULL; + return devicetable[han]; +} + +#if __FreeBSD_version >= 1100000 +/* This works with /dev/nvme*, /dev/nvd* and /dev/nda* but not /dev/pass* */ +static int +nvme_get_nsid(int fd, uint32_t *nsid, char *b, int blen, int vb) +{ + struct nvme_get_nsid gnsid; + int n_cdev = sizeof(gnsid.cdev); + + if (ioctl(fd, NVME_GET_NSID, &gnsid) < 0) { + int err = errno; + + if (vb > 2) + pr2ws("%s: ioctl(NVME_GET_NSID) failed, errno=%d\n", __func__, + err); + return -err; + } + if (n_cdev < blen) { + strncpy(b, gnsid.cdev, n_cdev); + b[n_cdev] = '\0'; + } else { + strncpy(b, gnsid.cdev, blen); + b[blen - 1] = '\0'; + } + if (nsid != NULL) + *nsid = gnsid.nsid; + return 0; +} +#endif + +/* Returns >= 0 if successful. If error in Unix returns negated errno. */ +int +scsi_pt_open_device(const char * device_name, bool read_only, int vb) +{ + int oflags = 0 /* O_NONBLOCK*/ ; + + oflags |= (read_only ? O_RDONLY : O_RDWR); + return scsi_pt_open_flags(device_name, oflags, vb); +} + +#if __FreeBSD_version >= 1100000 +/* Get a get device CCB for the specified device, borrowed from camdd.c */ +int +sg_cam_get_cgd(struct cam_device *device, struct ccb_getdev *cgd, int vb) +{ + union ccb *ccb; + FILE * ferrp = sg_warnings_strm ? sg_warnings_strm : stderr; + int retval = 0; + + ccb = cam_getccb(device); + if (ccb == NULL) { + if (vb) + pr2ws("%s: couldn't allocate CCB\n", __func__); + return -ENOMEM; + } + CCB_CLEAR_ALL_EXCEPT_HDR(&ccb->cgd); + ccb->ccb_h.func_code = XPT_GDEV_TYPE; + + if (cam_send_ccb(device, ccb) < 0) { + if (vb > 1) { + pr2ws("%s: error sending Get Device Information CCB\n", __func__); + CAM_ERROR_PRINT(device, ccb, CAM_ESF_ALL, CAM_EPF_ALL, ferrp); + } + retval = -ENODEV; + goto bailout; + } + if ((ccb->ccb_h.status & CAM_STATUS_MASK) != CAM_REQ_CMP) { + if (vb > 1) + CAM_ERROR_PRINT(device, ccb, CAM_ESF_ALL, CAM_EPF_ALL, ferrp); + retval = -ENODEV; + goto bailout; + } + bcopy(&ccb->cgd, cgd, sizeof(struct ccb_getdev)); +bailout: + cam_freeccb(ccb); + return retval; +} +#endif + +/* Similar to scsi_pt_open_device() but takes Unix style open flags OR-ed + * together. The 'oflags' is only used on NVMe devices. It is ignored on + * SCSI and ATA devices in FreeBSD. + * Returns >= 0 if successful, otherwise returns negated errno. */ +int +scsi_pt_open_flags(const char * device_name, int oflags, int vb) +{ + bool maybe_non_cam_nvme = false; + bool basnam0_n = false; + char first_ch; + int k, err, dev_fd, ret, handle_idx; + ssize_t s; + struct freebsd_dev_channel *fdc_p = NULL; + struct cam_device* cam_dev; + struct stat a_stat; + char dev_nm[PATH_MAX]; + + if (vb > 6) + pr2ws("%s: device_name=%s, oflags=0x%x\n", __func__, device_name, + oflags); + // Search table for a free entry + for (k = 0; k < FREEBSD_MAXDEV; k++) + if (! devicetable[k]) + break; + + // If no free entry found, return error. We have max allowed number + // of "file descriptors" already allocated. + if (k == FREEBSD_MAXDEV) { + if (vb) + pr2ws("too many open file descriptors (%d)\n", FREEBSD_MAXDEV); + ret = -EMFILE; + goto err_out; + } + handle_idx = k; + fdc_p = (struct freebsd_dev_channel *) + calloc(1,sizeof(struct freebsd_dev_channel)); + if (fdc_p == NULL) { + // errno already set by call to calloc() + ret = -ENOMEM; + goto err_out; + } + fdc_p->nvme_fd_ns = -1; + fdc_p->nvme_fd_ctrl = -1; + if (! (fdc_p->devname = (char *)calloc(1, DEV_IDLEN+1))) { + ret = -ENOMEM; + goto err_out; + } + /* Don't know yet whether device_name is a SCSI, NVME(non-CAM) or + * NVME(CAM) device. Start by assuming it is CAM. */ + if (cam_get_device(device_name, fdc_p->devname, DEV_IDLEN, + &(fdc_p->unitnum)) == -1) { + if (vb > 3) + pr2ws("%s: cam_get_device(%s) fails, should work for SCSI and " + "NVMe devices\n", __func__, device_name, errno); + ret = -EINVAL; + goto err_out; + } else if (vb > 6) + pr2ws("%s: cam_get_device() works, devname=%s unit=%u\n", __func__, + fdc_p->devname, fdc_p->unitnum); + + if (! (cam_dev = cam_open_spec_device(fdc_p->devname, + fdc_p->unitnum, O_RDWR, NULL))) { + if (vb > 6) { + pr2ws("cam_open_spec_device: %s\n", cam_errbuf); + pr2ws("%s: so not CAM, but still maybe NVME\n", __func__); + } + maybe_non_cam_nvme = true; + } else { /* found CAM, could be SCSI or NVME(CAM) [nda driver] */ +#if __FreeBSD_version >= 1100000 + struct ccb_getdev cgd; + + fdc_p->cam_dev = cam_dev; + ret = sg_cam_get_cgd(cam_dev, &cgd, vb); + if (ret) + goto err_out; + switch (cgd.protocol) { + case PROTO_SCSI: + fdc_p->is_nvme_dev = false; + break; + case PROTO_NVME: + fdc_p->is_nvme_dev = true; + fdc_p->is_cam_nvme = true; + fdc_p->nsid = cam_dev->target_lun & UINT32_MAX; + break; + case PROTO_ATA: + case PROTO_ATAPI: + case PROTO_SATAPM: + case PROTO_SEMB: /* SATA Enclosure Management bridge */ + if (vb) { + pr2ws("%s: ATA and derivative devices not supported\n", + __func__); + if (vb > 2) + pr2ws(" ... FreeBSD doesn't have a SAT in its kernel\n"); + } + ret = -EINVAL; + break; +#if __FreeBSD_version > 1200058 + case PROTO_MMCSD: + if (vb) + pr2ws("%s: MMC and SD devices not supported\n", + __func__); + ret = -EINVAL; + break; +#endif + default: + if (vb) + pr2ws("%s: unexpected device protocol\n", __func__); + ret = -EINVAL; + break; + } + if (ret) + goto err_out; + if (0 == memcpy(fdc_p->devname, "pass", 4)) + fdc_p->is_pass = true; +#else + ret = 0; + fdc_p->is_nvme_dev = false; +#endif + } + if (maybe_non_cam_nvme) { + first_ch = device_name[0]; + if (('/' != first_ch) && ('.' != first_ch)) { + char b[PATH_MAX]; + + /* Step 1: if device_name is symlink, follow it */ + s = readlink(device_name, b, sizeof(b)); + if (s <= 0) { + strncpy(b, device_name, PATH_MAX - 1); + b[PATH_MAX - 1] = '\0'; + } + /* Step 2: if no leading '/' nor '.' given, prepend '/dev/' */ + first_ch = b[0]; + basnam0_n = ('n' == first_ch); + if (('/' != first_ch) && ('.' != first_ch)) + snprintf(dev_nm, PATH_MAX, "%s%s", "/dev/", b); + else + strcpy(dev_nm, b); + } else { + const char * cp; + + strcpy(dev_nm, device_name); + cp = basename(dev_nm); + basnam0_n = ('n' == *cp); + strcpy(dev_nm, device_name); + } + if (stat(dev_nm, &a_stat) < 0) { + err = errno; + if (vb) + pr2ws("%s: unable to stat(%s): %s; basnam0_n=%d\n", + __func__, dev_nm, strerror(err), basnam0_n); + ret = -err; + goto err_out; + } + if (! (S_ISCHR(a_stat.st_mode))) { + if (vb > 1) + pr2ws("%s: %s is not a char device ??\n", __func__, dev_nm); + ret = -ENODEV; + goto err_out; + } + dev_fd = open(dev_nm, oflags); + if (dev_fd < 0) { + err = errno; + if (vb > 1) + pr2ws("%s: open(%s) failed: %s (errno=%d), try SCSI/ATA\n", + __func__, dev_nm, strerror(err), err); + ret = -err; + goto err_out; + } +#if __FreeBSD_version >= 1100000 + ret = nvme_get_nsid(dev_fd, &fdc_p->nsid, fdc_p->devname, DEV_IDLEN, + vb); + if (ret) + goto err_out; +#else + { + unsigned int u; + + /* only support /dev/nvme<n> and /dev/nvme<n>ns<m> */ + k = sscanf(dev_nm, "nvme%uns%u", &u, &fdc_p->nsid); + if (2 == k) { + char * cp = strchr(dev_nm, 's'); + + *(cp - 2) = '\0'; + strcpy(fdc_p->devname, dev_nm); + } else if (1 == k) { + strncpy(fdc_p->devname, dev_nm, DEV_IDLEN); + fdc_p->nsid = 0; + } else if (vb > 1) { + pr2ws("%s: only support '[/dev/]nvme<n>[ns<m>]'\n", __func__); + goto err_out; + } + } +#endif + if (vb > 6) + pr2ws("%s: nvme_dev_nm: %s, nsid=%u\n", __func__, fdc_p->devname, + fdc_p->nsid); + fdc_p->is_nvme_dev = true; + fdc_p->is_cam_nvme = false; + if (fdc_p->nsid > 0) + fdc_p->nvme_fd_ns = dev_fd; + else + fdc_p->nvme_fd_ctrl = dev_fd; + } + // return pointer to "file descriptor" table entry, properly offset. + devicetable[handle_idx] = fdc_p; + return handle_idx + FREEBSD_FDOFFSET; + +err_out: /* ret should be negative value (negated errno) */ + if (fdc_p) { + if (fdc_p->devname) + free(fdc_p->devname); + if (fdc_p->nvme_fd_ns >= 0) + close(fdc_p->nvme_fd_ns); + if (fdc_p->nvme_fd_ctrl >= 0) + close(fdc_p->nvme_fd_ctrl); + free(fdc_p); + fdc_p = NULL; + } + return ret; +} + +/* Returns 0 if successful. If error in Unix returns negated errno. */ +int +scsi_pt_close_device(int device_han) +{ + struct freebsd_dev_channel *fdc_p; + int han = device_han - FREEBSD_FDOFFSET; + + if ((han < 0) || (han >= FREEBSD_MAXDEV)) { + errno = ENODEV; + return -errno; + } + fdc_p = devicetable[han]; + if (NULL == fdc_p) { + errno = ENODEV; + return -errno; + } + if (fdc_p->devname) + free(fdc_p->devname); + if (fdc_p->cam_dev) /* N.B. can be cam_nvme devices */ + cam_close_device(fdc_p->cam_dev); + else if (fdc_p->is_nvme_dev) { + if (fdc_p->nvme_fd_ns >= 0) + close(fdc_p->nvme_fd_ns); + if (fdc_p->nvme_fd_ctrl >= 0) + close(fdc_p->nvme_fd_ctrl); + if (fdc_p->free_nvme_id_ctlp) { + free(fdc_p->free_nvme_id_ctlp); + fdc_p->nvme_id_ctlp = NULL; + fdc_p->free_nvme_id_ctlp = NULL; + } + } + free(fdc_p); + devicetable[han] = NULL; + errno = 0; + return 0; +} + +/* Assumes device_han is an "open" file handle associated with some device. + * Returns 1 if SCSI generic pass-though device [SCSI CAM primary: nda0], + * returns 2 if secondary * SCSI pass-through device [SCSI CAM: pass<n>]; + * returns 3 if non-CAM NVMe with no nsid [nvme0]; returns 4 if non-CAM + * NVMe device with nsid (> 0) [nvme0ns1, nvd0]; returns 5 if CAM NVMe + * (with or without nsid) [nda0]; or returns 0 if something else (e.g. ATA + * block device) or device_han < 0. + * If error, returns negated errno (operating system) value. */ +int +check_pt_file_handle(int device_han, const char * device_name, int vb) +{ + struct freebsd_dev_channel *fdc_p; + int han = device_han - FREEBSD_FDOFFSET; + + if (vb > 6) + pr2ws("%s: device_handle=%d, device_name: %s\n", __func__, + device_han, device_name); + if ((han < 0) || (han >= FREEBSD_MAXDEV)) + return -ENODEV; + fdc_p = devicetable[han]; + if (NULL == fdc_p) + return -ENODEV; + if (fdc_p->is_nvme_dev) { + if (fdc_p->is_cam_nvme) + return 5; + else if (fdc_p->nsid == 0) + return 3; + else + return 4; /* Something like nvme0ns1 or nvd0 */ + } else if (fdc_p->cam_dev) + return fdc_p->is_pass ? 2 : 1; + else { + if (vb > 1) + pr2ws("%s: neither SCSI nor NVMe ... hmm, device name: %s\n", + __func__, device_name); + return 0; + } +} + +#if (HAVE_NVME && (! IGNORE_NVME)) +static bool checked_ev_dsense = false; +static bool ev_dsense = false; +#endif + +struct sg_pt_base * +construct_scsi_pt_obj_with_fd(int dev_han, int vb) +{ + struct sg_pt_freebsd_scsi * ptp; + + ptp = (struct sg_pt_freebsd_scsi *) + calloc(1, sizeof(struct sg_pt_freebsd_scsi)); + if (ptp) { + ptp->dxfer_dir = CAM_DIR_NONE; + ptp->dev_han = (dev_han < 0) ? -1 : dev_han; + if (ptp->dev_han >= 0) { + struct freebsd_dev_channel *fdc_p; + + fdc_p = get_fdc_p(ptp); + if (fdc_p) { + ptp->mchanp = fdc_p; +#if (HAVE_NVME && (! IGNORE_NVME)) + sntl_init_dev_stat(&fdc_p->dev_stat); + if (! checked_ev_dsense) { + ev_dsense = sg_get_initial_dsense(); + checked_ev_dsense = true; + } + fdc_p->dev_stat.scsi_dsense = ev_dsense; +#endif + } else if (vb) + pr2ws("%s: bad dev_han=%d\n", __func__, dev_han); + } + } else if (vb) + pr2ws("%s: calloc() out of memory\n", __func__); + return (struct sg_pt_base *)ptp; +} + + +struct sg_pt_base * +construct_scsi_pt_obj() +{ + return construct_scsi_pt_obj_with_fd(-1, 0); +} + +void +destruct_scsi_pt_obj(struct sg_pt_base * vp) +{ + struct sg_pt_freebsd_scsi * ptp; + + if (NULL == vp) { + pr2ws(">>>> %s: given NULL pointer\n", __func__); + return; + } + if ((ptp = &vp->impl)) { + if (ptp->ccb) + cam_freeccb(ptp->ccb); + free(vp); + } +} + +void +clear_scsi_pt_obj(struct sg_pt_base * vp) +{ + struct sg_pt_freebsd_scsi * ptp; + + if (NULL == vp) { + pr2ws(">>>>> %s: NULL pointer given\n", __func__); + return; + } + if ((ptp = &vp->impl)) { + int dev_han = ptp->dev_han; + struct freebsd_dev_channel *fdc_p = ptp->mchanp; + + if (ptp->ccb) + cam_freeccb(ptp->ccb); + memset(ptp, 0, sizeof(struct sg_pt_freebsd_scsi)); + ptp->dxfer_dir = CAM_DIR_NONE; + ptp->dev_han = dev_han; + ptp->mchanp = fdc_p; + } +} + +void +partial_clear_scsi_pt_obj(struct sg_pt_base * vp) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (NULL == ptp) + return; + ptp->in_err = 0; + ptp->os_err = 0; + ptp->transport_err = 0; + ptp->scsi_status = 0; + ptp->dxfer_dir = CAM_DIR_NONE; + ptp->dxferip = NULL; + ptp->dxfer_ilen = 0; + ptp->dxferop = NULL; + ptp->dxfer_olen = 0; + ptp->nvme_result = 0; +} + +/* Forget any previous dev_han and install the one given. May attempt to + * find file type (e.g. if pass-though) from OS so there could be an error. + * Returns 0 for success or the same value as get_scsi_pt_os_err() + * will return. dev_han should be >= 0 for a valid file handle or -1 . */ +int +set_pt_file_handle(struct sg_pt_base * vp, int dev_han, int vb) +{ + struct sg_pt_freebsd_scsi * ptp; + + if (NULL == vp) { + if (vb) + pr2ws(">>>> %s: pointer to object is NULL\n", __func__); + return EINVAL; + } + if ((ptp = &vp->impl)) { + struct freebsd_dev_channel *fdc_p; + + if (dev_han < 0) { + ptp->dev_han = -1; + ptp->dxfer_dir = CAM_DIR_NONE; + return 0; + } + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: dev_han (%d) is invalid\n", __func__, dev_han); + ptp->os_err = EINVAL; + return ptp->os_err; + } + ptp->os_err = 0; + ptp->transport_err = 0; + ptp->in_err = 0; + ptp->scsi_status = 0; + ptp->dev_han = dev_han; + ptp->dxfer_dir = CAM_DIR_NONE; + ptp->mchanp = fdc_p; + } + return 0; +} + +/* Valid file handles (which is the return value) are >= 0 . Returns -1 + * if there is no valid file handle. */ +int +get_pt_file_handle(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return ptp ? ptp->dev_han : -1; +} + +void +set_scsi_pt_cdb(struct sg_pt_base * vp, const uint8_t * cdb, int cdb_len) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + ptp->cdb = (uint8_t *)cdb; + ptp->cdb_len = cdb_len; +} + +int +get_scsi_pt_cdb_len(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return ptp->cdb_len; +} + +uint8_t * +get_scsi_pt_cdb_buf(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return ptp->cdb; +} + +void +set_scsi_pt_sense(struct sg_pt_base * vp, uint8_t * sense, + int max_sense_len) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (sense) { + if (max_sense_len > 0) + memset(sense, 0, max_sense_len); + } + ptp->sense = sense; + ptp->sense_len = max_sense_len; +} + +/* Setup for data transfer from device */ +void +set_scsi_pt_data_in(struct sg_pt_base * vp, uint8_t * dxferp, + int dxfer_len) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp->dxferip) + ++ptp->in_err; + ptp->dxferip = dxferp; + ptp->dxfer_ilen = dxfer_len; + if (dxfer_len > 0) { + ptp->dxferp = dxferp; + ptp->dxfer_len = dxfer_len; + if (ptp->dxfer_dir == CAM_DIR_OUT) + ptp->dxfer_dir = CAM_DIR_BOTH; + else + ptp->dxfer_dir = CAM_DIR_IN; + } +} + +/* Setup for data transfer toward device */ +void +set_scsi_pt_data_out(struct sg_pt_base * vp, const uint8_t * dxferp, + int dxfer_len) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp->dxferop) + ++ptp->in_err; + ptp->dxferop = (uint8_t *)dxferp; + ptp->dxfer_olen = dxfer_len; + if (dxfer_len > 0) { + ptp->dxferp = (uint8_t *)dxferp; + ptp->dxfer_len = dxfer_len; + if (ptp->dxfer_dir == CAM_DIR_IN) + ptp->dxfer_dir = CAM_DIR_BOTH; + else + ptp->dxfer_dir = CAM_DIR_OUT; + } +} + +void +set_pt_metadata_xfer(struct sg_pt_base * vp, uint8_t * mdxferp, + uint32_t mdxfer_len, bool out_true) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp->mdxferp) + ++ptp->in_err; + ptp->mdxferp = mdxferp; + ptp->mdxfer_len = mdxfer_len; + if (mdxfer_len > 0) + ptp->mdxfer_out = out_true; +} + +void +set_scsi_pt_packet_id(struct sg_pt_base * vp __attribute__ ((unused)), + int pack_id __attribute__ ((unused))) +{ +} + +void +set_scsi_pt_tag(struct sg_pt_base * vp, uint64_t tag __attribute__ ((unused))) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + ++ptp->in_err; +} + +void +set_scsi_pt_task_management(struct sg_pt_base * vp, + int tmf_code __attribute__ ((unused))) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + ++ptp->in_err; +} + +void +set_scsi_pt_task_attr(struct sg_pt_base * vp, + int attrib __attribute__ ((unused)), + int priority __attribute__ ((unused))) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + ++ptp->in_err; +} + +void +set_scsi_pt_flags(struct sg_pt_base * objp, int flags) +{ + if (objp) { ; } /* unused, suppress warning */ + if (flags) { ; } /* unused, suppress warning */ +} + +/* Executes SCSI command (or at least forwards it to lower layers). + * Clears os_err field prior to active call (whose result may set it + * again). */ +int +do_scsi_pt(struct sg_pt_base * vp, int dev_han, int time_secs, int vb) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + struct freebsd_dev_channel *fdc_p; + FILE * ferrp = sg_warnings_strm ? sg_warnings_strm : stderr; + union ccb *ccb; + + if (vb > 6) + pr2ws("%s: dev_han=%d, time_secs=%d\n", __func__, dev_han, time_secs); + ptp->os_err = 0; + if (ptp->in_err) { + if (vb) + pr2ws("Replicated or unused set_scsi_pt...\n"); + return SCSI_PT_DO_BAD_PARAMS; + } + if (dev_han < 0) { + if (ptp->dev_han < 0) { + if (vb) + pr2ws("%s: No device file handle given\n", __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + dev_han = ptp->dev_han; + } else { + if (ptp->dev_han >= 0) { + if (dev_han != ptp->dev_han) { + if (vb) + pr2ws("%s: file handle given to create and this " + "differ\n", __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + } else + ptp->dev_han = dev_han; + } + + if (NULL == ptp->cdb) { + if (vb) + pr2ws("No command (cdb) given\n"); + return SCSI_PT_DO_BAD_PARAMS; + } + + fdc_p = ptp->mchanp; + if (NULL == fdc_p) { + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("File descriptor bad or closed??\n"); + ptp->os_err = ENODEV; + return -ptp->os_err; + } + ptp->mchanp = fdc_p; + } +#if (HAVE_NVME && (! IGNORE_NVME)) + if (fdc_p->is_nvme_dev) + return sg_do_nvme_pt(ptp, -1, true /* assume Admin */, time_secs, vb); +#endif + + /* SCSI CAM pass-through follows */ + ptp->is_nvme_dev = fdc_p->is_nvme_dev; + if (NULL == fdc_p->cam_dev) { + if (vb) + pr2ws("No open CAM device\n"); + return SCSI_PT_DO_BAD_PARAMS; + } + + if (NULL == ptp->ccb) { /* re-use if we have one already */ + if (! (ccb = cam_getccb(fdc_p->cam_dev))) { + if (vb) + pr2ws("cam_getccb: failed\n"); + ptp->os_err = ENOMEM; + return -ptp->os_err; + } + ptp->ccb = ccb; + } else + ccb = ptp->ccb; + + // clear out structure, except for header that was filled in for us + bzero(&(&ccb->ccb_h)[1], + sizeof(struct ccb_scsiio) - sizeof(struct ccb_hdr)); + + ptp->timeout_ms = (time_secs > 0) ? (time_secs * 1000) : DEF_TIMEOUT; + cam_fill_csio(&ccb->csio, + /* retries */ 1, + /* cbfcnp */ NULL, + /* flags */ ptp->dxfer_dir, + /* tagaction */ MSG_SIMPLE_Q_TAG, + /* dataptr */ ptp->dxferp, + /* datalen */ ptp->dxfer_len, + /* senselen */ ptp->sense_len, + /* cdblen */ ptp->cdb_len, + /* timeout (millisecs) */ ptp->timeout_ms); + memcpy(ccb->csio.cdb_io.cdb_bytes, ptp->cdb, ptp->cdb_len); + + if (cam_send_ccb(fdc_p->cam_dev, ccb) < 0) { + if (vb) { + pr2serr("%s: cam_send_ccb() error\n", __func__); + CAM_ERROR_PRINT(fdc_p->cam_dev, ccb, CAM_ESF_ALL, + CAM_EPF_ALL, ferrp); + } + cam_freeccb(ptp->ccb); + ptp->ccb = NULL; + ptp->os_err = EIO; + return -ptp->os_err; + } + + if (((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_CMP) || + ((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_SCSI_STATUS_ERROR)) { + ptp->scsi_status = ccb->csio.scsi_status; + ptp->resid = ccb->csio.resid; + ptp->sense_resid = ccb->csio.sense_resid; + + if ((SAM_STAT_CHECK_CONDITION == ptp->scsi_status) || + (SAM_STAT_COMMAND_TERMINATED == ptp->scsi_status)) { + int len; + + if (ptp->sense_resid > ptp->sense_len) + len = ptp->sense_len; /* crazy; ignore sense_resid */ + else + len = ptp->sense_len - ptp->sense_resid; + if (len > 0) + memcpy(ptp->sense, &(ccb->csio.sense_data), len); + } + } else + ptp->transport_err = 1; + + return 0; +} + +int +get_scsi_pt_result_category(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp->os_err) + return SCSI_PT_RESULT_OS_ERR; + else if (ptp->transport_err) + return SCSI_PT_RESULT_TRANSPORT_ERR; + else if ((SAM_STAT_CHECK_CONDITION == ptp->scsi_status) || + (SAM_STAT_COMMAND_TERMINATED == ptp->scsi_status)) + return SCSI_PT_RESULT_SENSE; + else if (ptp->scsi_status) + return SCSI_PT_RESULT_STATUS; + else + return SCSI_PT_RESULT_GOOD; +} + +int +get_scsi_pt_resid(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if ((NULL == ptp) || (NULL == ptp->mchanp)) + return 0; + return ((ptp->is_nvme_dev && ! ptp->nvme_our_sntl)) ? 0 : ptp->resid; +} + +void +get_pt_req_lengths(const struct sg_pt_base * vp, int * req_dinp, + int * req_doutp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + bool bidi = (ptp->dxfer_dir == CAM_DIR_BOTH); + + if (req_dinp) { + if (ptp->dxfer_ilen > 0) + *req_dinp = ptp->dxfer_ilen; + else + *req_dinp = 0; + } + if (req_doutp) { + if ((!bidi) && (ptp->dxfer_olen > 0)) + *req_doutp = ptp->dxfer_olen; + else + *req_doutp = 0; + } +} + +void +get_pt_actual_lengths(const struct sg_pt_base * vp, int * act_dinp, + int * act_doutp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + bool bidi = (ptp->dxfer_dir == CAM_DIR_BOTH); + + if (act_dinp) { + if (ptp->dxfer_ilen > 0) + *act_dinp = ptp->dxfer_ilen - ptp->resid; + else + *act_dinp = 0; + } + if (act_doutp) { + if ((!bidi) && (ptp->dxfer_olen > 0)) + *act_doutp = ptp->dxfer_olen - ptp->resid; + else + *act_doutp = 0; + } +} + +/* Returns SCSI status value (from device that received the command). If an + * NVMe command was issued directly (i.e. through do_scsi_pt() then return + * NVMe status (i.e. ((SCT << 8) | SC)). If problem returns -1. */ +int +get_scsi_pt_status_response(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp) { + const struct freebsd_dev_channel * fdc_p = ptp->mchanp; + + if (NULL == fdc_p) + return -1; + if (ptp->is_nvme_dev && ! ptp->nvme_our_sntl) + return (int)ptp->nvme_status; + else + return ptp->scsi_status; + } + return -1; +} + +/* For NVMe command: CDW0 from completion (32 bits); for SCSI: the status */ +uint32_t +get_pt_result(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp) { + const struct freebsd_dev_channel * fdc_p = ptp->mchanp; + + if (NULL == fdc_p) + return -1; + if (ptp->is_nvme_dev && ! ptp->nvme_our_sntl) + return ptp->nvme_result; + else + return (uint32_t)ptp->scsi_status; + } + return 0xffffffff; +} + +int +get_scsi_pt_sense_len(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp->sense_resid > ptp->sense_len) + return ptp->sense_len; /* strange; ignore ptp->sense_resid */ + else + return ptp->sense_len - ptp->sense_resid; +} + +uint8_t * +get_scsi_pt_sense_buf(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return ptp->sense; +} + +/* Not implemented so return -1 . */ +int +get_scsi_pt_duration_ms(const struct sg_pt_base * vp __attribute__ ((unused))) +{ + // const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return -1; +} + +/* If not available return 0 otherwise return number of nanoseconds that the + * lower layers (and hardware) took to execute the command just completed. */ +uint64_t +get_pt_duration_ns(const struct sg_pt_base * vp __attribute__ ((unused))) +{ + return 0; +} + +int +get_scsi_pt_transport_err(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return ptp->transport_err; +} + +void +set_scsi_pt_transport_err(struct sg_pt_base * vp, int err) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + ptp->transport_err = err; +} + +int +get_scsi_pt_os_err(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + return ptp->os_err; +} + +char * +get_scsi_pt_transport_err_str(const struct sg_pt_base * vp, int max_b_len, + char * b) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (0 == ptp->transport_err) { + strncpy(b, "no transport error available", max_b_len); + b[max_b_len - 1] = '\0'; + return b; + } + if (ptp->mchanp && ptp->mchanp->is_nvme_dev) { + snprintf(b, max_b_len, "NVMe has no transport errors at present " + "but tranport_err=%d ??\n", ptp->transport_err); + return b; + } +#if __FreeBSD_version > 500000 + if (ptp->mchanp && ptp->mchanp->cam_dev) + cam_error_string(ptp->mchanp->cam_dev, ptp->ccb, b, max_b_len, + CAM_ESF_ALL, CAM_EPF_ALL); + else { + strncpy(b, "no transport error available", max_b_len); + b[max_b_len - 1] = '\0'; + } +#else + strncpy(b, "no transport error available", max_b_len); + b[max_b_len - 1] = '\0'; +#endif + return b; +} + +bool +pt_device_is_nvme(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp && (ptp->dev_han >= 0)) { + const struct freebsd_dev_channel *fdc_p; + + fdc_p = get_fdc_cp(ptp); + if (NULL == fdc_p) { + pr2ws("%s: unable to find fdc_p\n", __func__); + errno = ENODEV; + return false; + } + return fdc_p->is_nvme_dev; + } + return false; +} + +/* If a NVMe block device (which includes the NSID) handle is associated + * with 'objp', then its NSID is returned (values range from 0x1 to + * 0xffffffe). Otherwise 0 is returned. */ +uint32_t +get_pt_nvme_nsid(const struct sg_pt_base * vp) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + + if (ptp && (ptp->dev_han >= 0)) { + const struct freebsd_dev_channel *fdc_p; + + fdc_p = get_fdc_cp(ptp); + if (NULL == fdc_p) + return 0; + return fdc_p->nsid; + } + return 0; +} + +char * +get_scsi_pt_os_err_str(const struct sg_pt_base * vp, int max_b_len, char * b) +{ + const struct sg_pt_freebsd_scsi * ptp = &vp->impl; + const char * cp; + + cp = safe_strerror(ptp->os_err); + strncpy(b, cp, max_b_len); + if ((int)strlen(cp) >= max_b_len) + b[max_b_len - 1] = '\0'; + return b; +} + + +#define SCSI_INQUIRY_OPC 0x12 +#define SCSI_MAINT_IN_OPC 0xa3 +#define SCSI_MODE_SENSE10_OPC 0x5a +#define SCSI_MODE_SELECT10_OPC 0x55 +#define SCSI_READ10_OPC 0x28 +#define SCSI_READ16_OPC 0x88 +#define SCSI_READ_CAPACITY10_OPC 0x25 +#define SCSI_START_STOP_OPC 0x1b +#define SCSI_SYNC_CACHE10_OPC 0x35 +#define SCSI_SYNC_CACHE16_OPC 0x91 +#define SCSI_VERIFY10_OPC 0x2f +#define SCSI_VERIFY16_OPC 0x8f +#define SCSI_WRITE10_OPC 0x2a +#define SCSI_WRITE16_OPC 0x8a +#define SCSI_WRITE_SAME10_OPC 0x41 +#define SCSI_WRITE_SAME16_OPC 0x93 +#define SCSI_RECEIVE_DIAGNOSTIC_OPC 0x1c +#define SCSI_REP_SUP_OPCS_OPC 0xc +#define SCSI_REP_SUP_TMFS_OPC 0xd +#define SCSI_REPORT_LUNS_OPC 0xa0 +#define SCSI_REQUEST_SENSE_OPC 0x3 +#define SCSI_SEND_DIAGNOSTIC_OPC 0x1d +#define SCSI_TEST_UNIT_READY_OPC 0x0 +#define SCSI_SERVICE_ACT_IN_OPC 0x9e +#define SCSI_READ_CAPACITY16_SA 0x10 +#define SCSI_SA_MSK 0x1f + +/* Additional Sense Code (ASC) */ +#define NO_ADDITIONAL_SENSE 0x0 +#define LOGICAL_UNIT_NOT_READY 0x4 +#define LOGICAL_UNIT_COMMUNICATION_FAILURE 0x8 +#define UNRECOVERED_READ_ERR 0x11 +#define PARAMETER_LIST_LENGTH_ERR 0x1a +#define INVALID_OPCODE 0x20 +#define LBA_OUT_OF_RANGE 0x21 +#define INVALID_FIELD_IN_CDB 0x24 +#define INVALID_FIELD_IN_PARAM_LIST 0x26 +#define UA_RESET_ASC 0x29 +#define UA_CHANGED_ASC 0x2a +#define TARGET_CHANGED_ASC 0x3f +#define LUNS_CHANGED_ASCQ 0x0e +#define INSUFF_RES_ASC 0x55 +#define INSUFF_RES_ASCQ 0x3 +#define LOW_POWER_COND_ON_ASC 0x5e /* ASCQ=0 */ +#define POWER_ON_RESET_ASCQ 0x0 +#define BUS_RESET_ASCQ 0x2 /* scsi bus reset occurred */ +#define MODE_CHANGED_ASCQ 0x1 /* mode parameters changed */ +#define CAPACITY_CHANGED_ASCQ 0x9 +#define SAVING_PARAMS_UNSUP 0x39 +#define TRANSPORT_PROBLEM 0x4b +#define THRESHOLD_EXCEEDED 0x5d +#define LOW_POWER_COND_ON 0x5e +#define MISCOMPARE_VERIFY_ASC 0x1d +#define MICROCODE_CHANGED_ASCQ 0x1 /* with TARGET_CHANGED_ASC */ +#define MICROCODE_CHANGED_WO_RESET_ASCQ 0x16 +#define PCIE_ERR_ASC 0x4b +#define PCIE_UNSUPP_REQ_ASCQ 0x13 + +/* NVMe Admin commands */ +#define SG_NVME_AD_GET_FEATURE 0xa +#define SG_NVME_AD_SET_FEATURE 0x9 +#define SG_NVME_AD_IDENTIFY 0x6 /* similar to SCSI INQUIRY */ +#define SG_NVME_AD_DEV_SELT_TEST 0x14 +#define SG_NVME_AD_MI_RECEIVE 0x1e /* MI: Management Interface */ +#define SG_NVME_AD_MI_SEND 0x1d /* hmmm, same opcode as SEND DIAG */ + +/* NVMe NVM (Non-Volatile Memory) commands */ +#define SG_NVME_NVM_FLUSH 0x0 /* SCSI SYNCHRONIZE CACHE */ +#define SG_NVME_NVM_COMPARE 0x5 /* SCSI VERIFY(BYTCHK=1) */ +#define SG_NVME_NVM_READ 0x2 +#define SG_NVME_NVM_VERIFY 0xc /* SCSI VERIFY(BYTCHK=0) */ +#define SG_NVME_NVM_WRITE 0x1 +#define SG_NVME_NVM_WRITE_ZEROES 0x8 /* SCSI WRITE SAME */ + +#define SG_NVME_RW_CDW12_FUA (1 << 30) /* Force Unit Access bit */ + +#if (HAVE_NVME && (! IGNORE_NVME)) + +static void +mk_sense_asc_ascq(struct sg_pt_freebsd_scsi * ptp, int sk, int asc, int ascq, + int vb) +{ + bool dsense = ptp->mchanp ? ptp->mchanp->dev_stat.scsi_dsense : false; + int n; + uint8_t * sbp = ptp->sense; + + ptp->scsi_status = SAM_STAT_CHECK_CONDITION; + n = ptp->sense_len; + if ((n < 8) || ((! dsense) && (n < 14))) { + if (vb) + pr2ws("%s: sense_len=%d too short, want 14 or more\n", __func__, + n); + return; + } else + ptp->sense_resid = ptp->sense_len - + (dsense ? 8 : ((n < 18) ? n : 18)); + memset(sbp, 0, n); + sg_build_sense_buffer(dsense, sbp, sk, asc, ascq); + if (vb > 3) + pr2ws("%s: [sense_key,asc,ascq]: [0x%x,0x%x,0x%x]\n", __func__, + sk, asc, ascq); +} + +static void +mk_sense_from_nvme_status(struct sg_pt_freebsd_scsi * ptp, uint16_t sct_sc, + int vb) +{ + bool ok; + bool dsense = ptp->mchanp ? ptp->mchanp->dev_stat.scsi_dsense : false; + int n; + uint8_t sstatus, sk, asc, ascq; + uint8_t * sbp = ptp->sense; + + ok = sg_nvme_status2scsi(sct_sc, &sstatus, &sk, &asc, &ascq); + if (! ok) { /* can't find a mapping to a SCSI error, so ... */ + sstatus = SAM_STAT_CHECK_CONDITION; + sk = SPC_SK_ILLEGAL_REQUEST; + asc = 0xb; + ascq = 0x0; /* asc: "WARNING" purposely vague */ + } + + ptp->scsi_status = sstatus; + n = ptp->sense_len; + if ((n < 8) || ((! dsense) && (n < 14))) { + if (vb) + pr2ws("%s: sense_len=%d too short, want 14 or more\n", __func__, + n); + return; + } else + ptp->sense_resid = ptp->sense_len - + (dsense ? 8 : ((n < 18) ? n : 18)); + memset(sbp, 0, n); + sg_build_sense_buffer(dsense, sbp, sk, asc, ascq); + if (vb > 3) + pr2ws("%s: [sense_key,asc,ascq]: [0x%x,0x%x,0x%x]\n", __func__, + sk, asc, ascq); + if (dsense && (sct_sc > 0) && (ptp->sense_resid > 7)) { + sg_nvme_desc2sense(sbp, 0x4000 & sct_sc /* dnr */, + 0x2000 & sct_sc /* more */, 0x7ff & sct_sc); + ptp->sense_resid -= 8; + } +} + +/* Set in_bit to -1 to indicate no bit position of invalid field */ +static void +mk_sense_invalid_fld(struct sg_pt_freebsd_scsi * ptp, bool in_cdb, + int in_byte, int in_bit, int vb) +{ + bool ds = ptp->mchanp ? ptp->mchanp->dev_stat.scsi_dsense : false; + int asc, n; + uint8_t * sbp = (uint8_t *)ptp->sense; + uint8_t sks[4]; + + ptp->scsi_status = SAM_STAT_CHECK_CONDITION; + asc = in_cdb ? INVALID_FIELD_IN_CDB : INVALID_FIELD_IN_PARAM_LIST; + n = ptp->sense_len; + if ((n < 8) || ((! ds) && (n < 14))) { + if (vb) + pr2ws("%s: max_response_len=%d too short, want 14 or more\n", + __func__, n); + return; + } else + ptp->sense_resid = ptp->sense_len - (ds ? 8 : ((n < 18) ? n : 18)); + memset(sbp, 0, n); + sg_build_sense_buffer(ds, sbp, SPC_SK_ILLEGAL_REQUEST, asc, 0); + memset(sks, 0, sizeof(sks)); + sks[0] = 0x80; + if (in_cdb) + sks[0] |= 0x40; + if (in_bit >= 0) { + sks[0] |= 0x8; + sks[0] |= (0x7 & in_bit); + } + sg_put_unaligned_be16(in_byte, sks + 1); + if (ds) { + int sl = sbp[7] + 8; + + sbp[7] = sl; + sbp[sl] = 0x2; + sbp[sl + 1] = 0x6; + memcpy(sbp + sl + 4, sks, 3); + } else + memcpy(sbp + 15, sks, 3); + if (vb > 3) + pr2ws("%s: [sense_key,asc,ascq]: [0x5,0x%x,0x0] %c byte=%d, bit=%d\n", + __func__, asc, in_cdb ? 'C' : 'D', in_byte, + ((in_bit > 0) ? (0x7 & in_bit) : 0)); +} + +#if 0 +static void +nvme_cbfcn(struct cam_periph * camperp, union ccb * ccb) +{ + pr2ws("%s: >>>> called, camperp=%p, ccb=%p\n", __func__, camperp, ccb); +} +#endif + +/* Does actual ioctl(NVME_PASSTHROUGH_CMD) or uses NVME(CAM) interface. + * Returns 0 on success; negative values are Unix negated errno values; + * positive values are NVMe status (i.e. ((SCT << 8) | SC) ). */ +static int +nvme_pt_low(struct sg_pt_freebsd_scsi * ptp, void * dxferp, uint32_t len, + bool is_admin, bool is_read, struct nvme_pt_command * npcp, + int time_secs, int vb) +{ + int err, dev_fd; + uint16_t sct_sc; + uint8_t opcode; + struct freebsd_dev_channel *fdc_p = ptp->mchanp; + + if (vb > 6) + pr2ws("%s: is_read=%d, time_secs=%d, is_cam_nvme=%d, is_admin=%d\n", + __func__, (int)is_read, time_secs, (int)fdc_p->is_cam_nvme, + (int)is_admin); + ptp->is_nvme_dev = fdc_p->is_nvme_dev; + npcp->buf = dxferp; + npcp->len = len; + npcp->is_read = (uint32_t)is_read; + opcode = npcp->cmd.opc; +#if __FreeBSD_version >= 1100000 + if (fdc_p->is_cam_nvme) + goto cam_nvme; +#endif + + /* non-CAM NVMe processing follows */ + if (is_admin) { + if (fdc_p->nvme_fd_ctrl < 0) { + if (vb > 4) + pr2ws("%s: not CAM but nvme_fd_ctrl<0, try to open " + "controller\n", __func__); + if ((fdc_p->nsid > 0) && fdc_p->devname && *fdc_p->devname) { + int fd; + char dev_nm[PATH_MAX]; + + if ((fdc_p->devname[0] == '/') || (fdc_p->devname[0] == '.')) + strncpy(dev_nm, fdc_p->devname, PATH_MAX); + else + snprintf(dev_nm, PATH_MAX, "/dev/%s", fdc_p->devname); + fd = open(dev_nm, O_RDWR); + if (fd < 0) { + if (vb > 1) + pr2ws("%s: Unable to open %s of NVMe controller: " + "%s\n", __func__, dev_nm, strerror(errno)); + } else + fdc_p->nvme_fd_ctrl = fd; + } + if (fdc_p->nvme_fd_ctrl < 0) + return -EINVAL; + } + dev_fd = fdc_p->nvme_fd_ctrl; + } else { + if (fdc_p->nvme_fd_ns < 0) { + if (vb > 1) + pr2ws("%s: not CAM but nvme_fd_ns<0, inconsistent\n", + __func__); + return -EINVAL; + } + dev_fd = fdc_p->nvme_fd_ns; + } + err = ioctl(dev_fd, NVME_PASSTHROUGH_CMD, npcp); + if (err < 0) { + err = errno; + if (vb) + pr2ws("%s: ioctl(NVME_PASSTHROUGH_CMD) errno: %s\n", __func__, + strerror(err)); + /* when that ioctl returns an error npcp->cpl is not populated */ + return -err; + } + +#if __FreeBSD_version <= 1200058 + sct_sc = ((npcp->cpl.status.sct << 8) | npcp->cpl.status.sc); +#else + sct_sc = (NVME_STATUS_GET_SCT(npcp->cpl.status) << 8) | + NVME_STATUS_GET_SC(npcp->cpl.status); +#endif + ptp->nvme_result = npcp->cpl.cdw0; + sg_put_unaligned_le32(npcp->cpl.cdw0, + ptp->cq_dw0_3 + SG_NVME_PT_CQ_RESULT); + sg_put_unaligned_le32(npcp->cpl.rsvd1, ptp->cq_dw0_3 + 4); + sg_put_unaligned_le16(npcp->cpl.sqhd, ptp->cq_dw0_3 + 8); + sg_put_unaligned_le16(npcp->cpl.sqid, ptp->cq_dw0_3 + 10); + sg_put_unaligned_le16(npcp->cpl.cid, ptp->cq_dw0_3 + 12); + sg_put_unaligned_le16(*((const uint16_t *)&(npcp->cpl.status)), + ptp->cq_dw0_3 + SG_NVME_PT_CQ_STATUS_P); + if (sct_sc && (vb > 1)) { + char nam[64]; + char b[80]; + + sg_get_nvme_opcode_name(opcode, is_admin, sizeof(nam), nam); + pr2ws("%s: %s [0x%x], status: %s\n", __func__, nam, opcode, + sg_get_nvme_cmd_status_str(sct_sc, sizeof(b), b)); + } + return sct_sc; + +#if __FreeBSD_version >= 1100000 +cam_nvme: + { + cam_status ccb_status; + union ccb *ccb; + struct ccb_nvmeio *nviop; + FILE * ferrp = sg_warnings_strm ? sg_warnings_strm : stderr; + + if (NULL == ptp->ccb) { /* re-use if we have one already */ + if (! (ccb = cam_getccb(fdc_p->cam_dev))) { + if (vb) + pr2ws("%s: cam_getccb: failed\n", __func__); + ptp->os_err = ENOMEM; + return -ptp->os_err; + } + ptp->ccb = ccb; + } else + ccb = ptp->ccb; + nviop = &ccb->nvmeio; + CCB_CLEAR_ALL_EXCEPT_HDR(nviop); + + memcpy(&nviop->cmd, &npcp->cmd, sizeof(nviop->cmd)); + ptp->timeout_ms = (time_secs > 0) ? (time_secs * 1000) : DEF_TIMEOUT; + if (is_admin) + cam_fill_nvmeadmin(nviop, + 1 /* retries */, + NULL, + is_read ? CAM_DIR_IN : CAM_DIR_OUT, + dxferp, + len, + ptp->timeout_ms); + + else { /* NVM command set, rather than Admin */ + if (fdc_p->nsid != npcp->cmd.nsid) { + if (vb) + pr2ws("%s: device node nsid [%u] not equal to cmd nsid " + "[%u]\n", __func__, fdc_p->nsid, npcp->cmd.nsid); + return -EINVAL; + } + cam_fill_nvmeio(nviop, + 1 /* retries */, + NULL, + is_read ? CAM_DIR_IN : CAM_DIR_OUT, + dxferp, + len, + ptp->timeout_ms); + } + + if (cam_send_ccb(fdc_p->cam_dev, ccb) < 0) { + if (vb) { + pr2ws("%s: cam_send_ccb(NVME) %s ccb error\n", __func__, + (is_admin ? "Admin" : "NVM")); + CAM_ERROR_PRINT(fdc_p->cam_dev, ccb, CAM_ESF_ALL, + CAM_EPF_ALL, ferrp); + } + cam_freeccb(ptp->ccb); + ptp->ccb = NULL; + ptp->os_err = EIO; + return -ptp->os_err; + } + ccb_status = ccb->ccb_h.status & CAM_STATUS_MASK; + if (ccb_status == CAM_REQ_CMP) { + ptp->nvme_result = 0; + ptp->os_err = 0; + return 0; + } + /* error processing follows ... */ + ptp->os_err = EIO; + if (vb) { + pr2ws("%s: ccb_status != CAM_REQ_CMP\n", __func__); + CAM_ERROR_PRINT(fdc_p->cam_dev, ccb, CAM_ESF_ALL, + CAM_EPF_ALL, ferrp); + } +#if __FreeBSD_version <= 1200058 + sct_sc = ((nviop->cpl.status.sct << 8) | nviop->cpl.status.sc); +#else + sct_sc = (NVME_STATUS_GET_SCT(nviop->cpl.status) << 8) | + NVME_STATUS_GET_SC(nviop->cpl.status); +#endif + ptp->nvme_result = nviop->cpl.cdw0; + sg_put_unaligned_le32(nviop->cpl.cdw0, + ptp->cq_dw0_3 + SG_NVME_PT_CQ_RESULT); + sg_put_unaligned_le32(nviop->cpl.rsvd1, ptp->cq_dw0_3 + 4); + sg_put_unaligned_le16(nviop->cpl.sqhd, ptp->cq_dw0_3 + 8); + sg_put_unaligned_le16(nviop->cpl.sqid, ptp->cq_dw0_3 + 10); + sg_put_unaligned_le16(nviop->cpl.cid, ptp->cq_dw0_3 + 12); + sg_put_unaligned_le16(*((const uint16_t *)&(nviop->cpl.status)), + ptp->cq_dw0_3 + SG_NVME_PT_CQ_STATUS_P); + if (sct_sc && (vb > 1)) { + char nam[64]; + char b[80]; + + sg_get_nvme_opcode_name(opcode, is_admin, sizeof(nam), + nam); + pr2ws("%s: %s [0x%x], status: %s\n", __func__, nam, opcode, + sg_get_nvme_cmd_status_str(sct_sc, sizeof(b), b)); + } + return sct_sc ? sct_sc : ptp->os_err; + } +#endif + return 0; +} + +static void +sntl_check_enclosure_override(struct freebsd_dev_channel * fdc_p, int vb) +{ + uint8_t * up = fdc_p->nvme_id_ctlp; + uint8_t nvmsr; + + if (NULL == up) + return; + nvmsr = up[253]; + if (vb > 5) + pr2ws("%s: enter, nvmsr=%u\n", __func__, nvmsr); + fdc_p->dev_stat.id_ctl253 = nvmsr; + switch (fdc_p->dev_stat.enclosure_override) { + case 0x0: /* no override */ + if (0x3 == (0x3 & nvmsr)) { + fdc_p->dev_stat.pdt = PDT_DISK; + fdc_p->dev_stat.enc_serv = 1; + } else if (0x2 & nvmsr) { + fdc_p->dev_stat.pdt = PDT_SES; + fdc_p->dev_stat.enc_serv = 1; + } else if (0x1 & nvmsr) { + fdc_p->dev_stat.pdt = PDT_DISK; + fdc_p->dev_stat.enc_serv = 0; + } else { + uint32_t nn = sg_get_unaligned_le32(up + 516); + + fdc_p->dev_stat.pdt = nn ? PDT_DISK : PDT_UNKNOWN; + fdc_p->dev_stat.enc_serv = 0; + } + break; + case 0x1: /* override to SES device */ + fdc_p->dev_stat.pdt = PDT_SES; + fdc_p->dev_stat.enc_serv = 1; + break; + case 0x2: /* override to disk with attached SES device */ + fdc_p->dev_stat.pdt = PDT_DISK; + fdc_p->dev_stat.enc_serv = 1; + break; + case 0x3: /* override to SAFTE device (PDT_PROCESSOR) */ + fdc_p->dev_stat.pdt = PDT_PROCESSOR; + fdc_p->dev_stat.enc_serv = 1; + break; + case 0xff: /* override to normal disk */ + fdc_p->dev_stat.pdt = PDT_DISK; + fdc_p->dev_stat.enc_serv = 0; + break; + default: + pr2ws("%s: unknown enclosure_override value: %d\n", __func__, + fdc_p->dev_stat.enclosure_override); + break; + } +} + +static int +sntl_do_identify(struct sg_pt_freebsd_scsi * ptp, int cns, int nsid, + int u_len, uint8_t * up, int time_secs, int vb) +{ + int err; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + + if (vb > 5) + pr2ws("%s: nsid=%d\n", __func__, nsid); + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_IDENTIFY; + sg_put_unaligned_le32(nsid, npc_up + SG_NVME_PT_NSID); + /* CNS=0x1 Identify: controller */ + sg_put_unaligned_le32(cns, npc_up + SG_NVME_PT_CDW10); + sg_put_unaligned_le64((sg_uintptr_t)up, npc_up + SG_NVME_PT_ADDR); + sg_put_unaligned_le32(u_len, npc_up + SG_NVME_PT_DATA_LEN); + err = nvme_pt_low(ptp, up, u_len, true, true, &npc, time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", __func__, + strerror(-err), -err); + return err; + } else { /* non-zero NVMe command status */ + ptp->nvme_status = err; + return SG_LIB_NVME_STATUS; + } + } + return 0; +} + +/* Currently only caches associated controller response (4096 bytes) */ +static int +sntl_cache_identity(struct sg_pt_freebsd_scsi * ptp, int time_secs, int vb) +{ + int ret; + uint32_t pg_sz = sg_get_page_size(); + struct freebsd_dev_channel * fdc_p = ptp->mchanp; + + fdc_p->nvme_id_ctlp = sg_memalign(pg_sz, pg_sz, + &fdc_p->free_nvme_id_ctlp, vb > 3); + if (NULL == fdc_p->nvme_id_ctlp) { + if (vb) + pr2ws("%s: sg_memalign() failed to get memory\n", __func__); + return -ENOMEM; + } + ret = sntl_do_identify(ptp, 0x1 /* CNS */, 0 /* nsid */, pg_sz, + fdc_p->nvme_id_ctlp, time_secs, vb); + if (0 == ret) + sntl_check_enclosure_override(fdc_p, vb); + return (ret < 0) ? sg_convert_errno(-ret) : ret; +} + +static const char * nvme_scsi_vendor_str = "NVMe "; +static const uint16_t inq_resp_len = 36; + +static int +sntl_inq(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, int time_secs, + int vb) +{ + bool evpd; + int res; + uint16_t n, alloc_len, pg_cd; + uint32_t pg_sz = sg_get_page_size(); + struct freebsd_dev_channel * fdc_p; + uint8_t * nvme_id_ns = NULL; + uint8_t * free_nvme_id_ns = NULL; + uint8_t inq_dout[256]; + + if (vb > 5) + pr2ws("%s: starting\n", __func__); + + if (0x2 & cdbp[1]) { /* Reject CmdDt=1 */ + mk_sense_invalid_fld(ptp, true, 1, 1, vb); + return 0; + } + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + if (NULL == fdc_p->nvme_id_ctlp) { + res = sntl_cache_identity(ptp, time_secs, vb); + if (SG_LIB_NVME_STATUS == res) { + mk_sense_from_nvme_status(ptp, ptp->nvme_status, vb); + return 0; + } else if (res) /* should be negative errno */ + return res; + } + memset(inq_dout, 0, sizeof(inq_dout)); + alloc_len = sg_get_unaligned_be16(cdbp + 3); + evpd = !!(0x1 & cdbp[1]); + pg_cd = cdbp[2]; + if (evpd) { /* VPD page responses */ + bool cp_id_ctl = false; + + switch (pg_cd) { + case 0: /* Supported VPD pages VPD page */ + /* inq_dout[0] = (PQ=0)<<5 | (PDT=0); prefer pdt=0xd --> SES */ + inq_dout[1] = pg_cd; + n = 11; + sg_put_unaligned_be16(n - 4, inq_dout + 2); + inq_dout[4] = 0x0; + inq_dout[5] = 0x80; + inq_dout[6] = 0x83; + inq_dout[7] = 0x86; + inq_dout[8] = 0x87; + inq_dout[9] = 0x92; + inq_dout[n - 1] = SG_NVME_VPD_NICR; /* last VPD number */ + break; + case 0x80: /* Serial number VPD page */ + /* inq_dout[0] = (PQ=0)<<5 | (PDT=0); prefer pdt=0xd --> SES */ + inq_dout[1] = pg_cd; + n = 24; + sg_put_unaligned_be16(n - 4, inq_dout + 2); + memcpy(inq_dout + 4, fdc_p->nvme_id_ctlp + 4, 20); /* SN */ + break; + case 0x83: /* Device identification VPD page */ + if ((fdc_p->nsid > 0) && (fdc_p->nsid < SG_NVME_BROADCAST_NSID)) { + nvme_id_ns = sg_memalign(pg_sz, pg_sz, &free_nvme_id_ns, + vb > 3); + if (nvme_id_ns) { + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_IDENTIFY; + sg_put_unaligned_le32(fdc_p->nsid, + npc_up + SG_NVME_PT_NSID); + /* CNS=0x0 Identify: namespace */ + sg_put_unaligned_le32(0x0, npc_up + SG_NVME_PT_CDW10); + sg_put_unaligned_le64((sg_uintptr_t)nvme_id_ns, + npc_up + SG_NVME_PT_ADDR); + sg_put_unaligned_le32(pg_sz, + npc_up + SG_NVME_PT_DATA_LEN); + res = nvme_pt_low(ptp, nvme_id_ns, pg_sz, true, true, + &npc, time_secs, vb > 3); + if (res) { + free(free_nvme_id_ns); + free_nvme_id_ns = NULL; + nvme_id_ns = NULL; + } + } + } + n = sg_make_vpd_devid_for_nvme(fdc_p->nvme_id_ctlp, nvme_id_ns, 0, + -1, inq_dout, sizeof(inq_dout)); + if (n > 3) + sg_put_unaligned_be16(n - 4, inq_dout + 2); + if (free_nvme_id_ns) { + free(free_nvme_id_ns); + free_nvme_id_ns = NULL; + nvme_id_ns = NULL; + } + break; + case 0x86: /* Extended INQUIRY (per SFS SPC Discovery 2016) */ + inq_dout[1] = pg_cd; + n = 64; + sg_put_unaligned_be16(n - 4, inq_dout + 2); + inq_dout[5] = 0x1; /* SIMPSUP=1 */ + inq_dout[7] = 0x1; /* LUICLR=1 */ + inq_dout[13] = 0x40; /* max supported sense data length */ + break; + case 0x87: /* Mode page policy (per SFS SPC Discovery 2016) */ + inq_dout[1] = pg_cd; + n = 8; + sg_put_unaligned_be16(n - 4, inq_dout + 2); + inq_dout[4] = 0x3f; /* all mode pages */ + inq_dout[5] = 0xff; /* and their sub-pages */ + inq_dout[6] = 0x80; /* MLUS=1, policy=shared */ + break; + case 0x92: /* SCSI Feature set: only SPC Discovery 2016 */ + inq_dout[1] = pg_cd; + n = 10; + sg_put_unaligned_be16(n - 4, inq_dout + 2); + inq_dout[9] = 0x1; /* SFS SPC Discovery 2016 */ + break; + case SG_NVME_VPD_NICR: /* 0xde */ + inq_dout[1] = pg_cd; + sg_put_unaligned_be16((16 + 4096) - 4, inq_dout + 2); + n = 16 + 4096; + cp_id_ctl = true; + break; + default: /* Point to page_code field in cdb */ + mk_sense_invalid_fld(ptp, true, 2, 7, vb); + return 0; + } + if (alloc_len > 0) { + n = (alloc_len < n) ? alloc_len : n; + n = (n < ptp->dxfer_len) ? n : ptp->dxfer_len; + ptp->resid = ptp->dxfer_len - n; + if (n > 0) { + if (cp_id_ctl) { + memcpy((uint8_t *)ptp->dxferp, inq_dout, + (n < 16 ? n : 16)); + if (n > 16) + memcpy((uint8_t *)ptp->dxferp + 16, + fdc_p->nvme_id_ctlp, n - 16); + } else + memcpy((uint8_t *)ptp->dxferp, inq_dout, n); + } + } + } else { /* Standard INQUIRY response */ + /* pdt=0 --> disk; pdt=0xd --> SES; pdt=3 --> processor (safte) */ + inq_dout[0] = (PDT_MASK & fdc_p->dev_stat.pdt); /* (PQ=0)<<5 */ + /* inq_dout[1] = (RMD=0)<<7 | (LU_CONG=0)<<6; rest reserved */ + inq_dout[2] = 6; /* version: SPC-4 */ + inq_dout[3] = 2; /* NORMACA=0, HISUP=0, response data format: 2 */ + inq_dout[4] = 31; /* so response length is (or could be) 36 bytes */ + inq_dout[6] = fdc_p->dev_stat.enc_serv ? 0x40 : 0; + inq_dout[7] = 0x2; /* CMDQUE=1 */ + memcpy(inq_dout + 8, nvme_scsi_vendor_str, 8); /* NVMe not Intel */ + memcpy(inq_dout + 16, fdc_p->nvme_id_ctlp + 24, 16);/* Prod <-- MN */ + memcpy(inq_dout + 32, fdc_p->nvme_id_ctlp + 64, 4); /* Rev <-- FR */ + if (alloc_len > 0) { + n = (alloc_len < inq_resp_len) ? alloc_len : inq_resp_len; + n = (n < ptp->dxfer_len) ? n : ptp->dxfer_len; + if (n > 0) + memcpy((uint8_t *)ptp->dxferp, inq_dout, n); + } + } + return 0; +} + +static int +sntl_rluns(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + int res; + uint16_t sel_report; + uint32_t alloc_len, k, n, num, max_nsid; + struct freebsd_dev_channel * fdc_p; + uint8_t * rl_doutp; + uint8_t * up; + + if (vb > 5) + pr2ws("%s: starting\n", __func__); + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + sel_report = cdbp[2]; + alloc_len = sg_get_unaligned_be32(cdbp + 6); + if (NULL == fdc_p->nvme_id_ctlp) { + res = sntl_cache_identity(ptp, time_secs, vb); + if (SG_LIB_NVME_STATUS == res) { + mk_sense_from_nvme_status(ptp, ptp->nvme_status, vb); + return 0; + } else if (res) + return res; + } + max_nsid = sg_get_unaligned_le32(fdc_p->nvme_id_ctlp + 516); + switch (sel_report) { + case 0: + case 2: + num = max_nsid; + break; + case 1: + case 0x10: + case 0x12: + num = 0; + break; + case 0x11: + num = (1 == fdc_p->nsid) ? max_nsid : 0; + break; + default: + if (vb > 1) + pr2ws("%s: bad select_report value: 0x%x\n", __func__, + sel_report); + mk_sense_invalid_fld(ptp, true, 2, 7, vb); + return 0; + } + rl_doutp = (uint8_t *)calloc(num + 1, 8); + if (NULL == rl_doutp) { + if (vb) + pr2ws("%s: calloc() failed to get memory\n", __func__); + return -ENOMEM; + } + for (k = 0, up = rl_doutp + 8; k < num; ++k, up += 8) + sg_put_unaligned_be16(k, up); + n = num * 8; + sg_put_unaligned_be32(n, rl_doutp); + n+= 8; + if (alloc_len > 0) { + n = (alloc_len < n) ? alloc_len : n; + n = (n < (uint32_t)ptp->dxfer_len) ? n : (uint32_t)ptp->dxfer_len; + ptp->resid = ptp->dxfer_len - (int)n; + if (n > 0) + memcpy((uint8_t *)ptp->dxferp, rl_doutp, n); + } + res = 0; + free(rl_doutp); + return res; +} + +static int +sntl_tur(struct sg_pt_freebsd_scsi * ptp, int time_secs, int vb) +{ + int err; + uint32_t pow_state; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + if (vb > 5) + pr2ws("%s: starting\n", __func__); + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + if (NULL == fdc_p->nvme_id_ctlp) { + int res = sntl_cache_identity(ptp, time_secs, vb); + + if (SG_LIB_NVME_STATUS == res) { + mk_sense_from_nvme_status(ptp, ptp->nvme_status, vb); + return 0; + } else if (res) + return res; + } + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_GET_FEATURE; + sg_put_unaligned_le32(SG_NVME_BROADCAST_NSID, npc_up + SG_NVME_PT_NSID); + /* SEL=0 (current), Feature=2 Power Management */ + sg_put_unaligned_le32(0x2, npc_up + SG_NVME_PT_CDW10); + err = nvme_pt_low(ptp, NULL, 0, true, false, &npc, time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", __func__, + strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + pow_state = (0x1f & ptp->nvme_result); + if (vb > 3) + pr2ws("%s: pow_state=%u\n", __func__, pow_state); +#if 0 /* pow_state bounces around too much on laptop */ + if (pow_state) + mk_sense_asc_ascq(ptp, SPC_SK_NOT_READY, LOW_POWER_COND_ON_ASC, 0, + vb); +#endif + return 0; +} + +static int +sntl_req_sense(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool desc; + int err; + uint32_t pow_state, alloc_len, n; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + uint8_t rs_dout[64]; + + if (vb > 5) + pr2ws("%s: starting\n", __func__); + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + if (NULL == fdc_p->nvme_id_ctlp) { + int res = sntl_cache_identity(ptp, time_secs, vb); + + if (SG_LIB_NVME_STATUS == res) { + mk_sense_from_nvme_status(ptp, ptp->nvme_status, vb); + return 0; + } else if (res) + return res; + } + desc = !!(0x1 & cdbp[1]); + alloc_len = cdbp[4]; + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_GET_FEATURE; + sg_put_unaligned_le32(SG_NVME_BROADCAST_NSID, npc_up + SG_NVME_PT_NSID); + /* SEL=0 (current), Feature=2 Power Management */ + sg_put_unaligned_le32(0x2, npc_up + SG_NVME_PT_CDW10); + err = nvme_pt_low(ptp, NULL, 0, true, false, &npc, time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", __func__, + strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + pow_state = (0x1f & ptp->nvme_result); + if (vb > 3) + pr2ws("%s: pow_state=%u\n", __func__, pow_state); + memset(rs_dout, 0, sizeof(rs_dout)); + if (pow_state) + sg_build_sense_buffer(desc, rs_dout, SPC_SK_NO_SENSE, + LOW_POWER_COND_ON_ASC, 0); + else + sg_build_sense_buffer(desc, rs_dout, SPC_SK_NO_SENSE, + NO_ADDITIONAL_SENSE, 0); + n = desc ? 8 : 18; + n = (n < alloc_len) ? n : alloc_len; + n = (n < (uint32_t)ptp->dxfer_len) ? n : (uint32_t)ptp->dxfer_len; + ptp->resid = ptp->dxfer_len - (int)n; + if (n > 0) + memcpy((uint8_t *)ptp->dxferp, rs_dout, n); + return 0; +} + +static int +sntl_mode_ss(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool is_msense = (SCSI_MODE_SENSE10_OPC == cdbp[0]); + int n, len; + uint8_t * bp; + struct freebsd_dev_channel * fdc_p; + struct sg_sntl_result_t sntl_result; + + if (vb > 5) + pr2ws("%s: mse%s\n", __func__, (is_msense ? "nse" : "lect")); + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + if (NULL == fdc_p->nvme_id_ctlp) { + int res = sntl_cache_identity(ptp, time_secs, vb); + + if (SG_LIB_NVME_STATUS == res) { + mk_sense_from_nvme_status(ptp, ptp->nvme_status, vb); + return 0; + } else if (res) + return res; + } + if (is_msense) { /* MODE SENSE(10) */ + len = ptp->dxfer_len; + bp = ptp->dxferp; + n = sntl_resp_mode_sense10(&fdc_p->dev_stat, cdbp, bp, len, + &sntl_result); + ptp->resid = (n >= 0) ? len - n : len; + } else { /* MODE SELECT(10) */ + uint8_t pre_enc_ov = fdc_p->dev_stat.enclosure_override; + + len = ptp->dxfer_len; + bp = ptp->dxferp; + n = sntl_resp_mode_select10(&fdc_p->dev_stat, cdbp, bp, len, + &sntl_result); + if (pre_enc_ov != fdc_p->dev_stat.enclosure_override) + sntl_check_enclosure_override(fdc_p, vb); /* ENC_OV has changed */ + } + if (n < 0) { + int in_bit = (255 == sntl_result.in_bit) ? (int)sntl_result.in_bit : + -1; + if ((SAM_STAT_CHECK_CONDITION == sntl_result.sstatus) && + (SPC_SK_ILLEGAL_REQUEST == sntl_result.sk)) { + if (INVALID_FIELD_IN_CDB == sntl_result.asc) + mk_sense_invalid_fld(ptp, true, sntl_result.in_byte, in_bit, + vb); + else if (INVALID_FIELD_IN_PARAM_LIST == sntl_result.asc) + mk_sense_invalid_fld(ptp, false, sntl_result.in_byte, in_bit, + vb); + else + mk_sense_asc_ascq(ptp, sntl_result.sk, sntl_result.asc, + sntl_result.ascq, vb); + } else if (vb) + pr2ws("%s: error but no sense?? n=%d\n", __func__, n); + } + return 0; +} + +/* This is not really a SNTL. For SCSI SEND DIAGNOSTIC(PF=1) NVMe-MI + * has a special command (SES Send) to tunnel through pages to an + * enclosure. The NVMe enclosure is meant to understand the SES + * (SCSI Enclosure Services) use of diagnostics pages that are + * related to SES. */ +static int +sntl_senddiag(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool pf, self_test; + int err; + uint8_t st_cd, dpg_cd; + uint32_t alloc_len, n, dout_len, dpg_len, nvme_dst; + const uint8_t * dop; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + st_cd = 0x7 & (cdbp[1] >> 5); + pf = !! (0x4 & cdbp[1]); + self_test = !! (0x10 & cdbp[1]); + if (vb > 5) + pr2ws("%s: pf=%d, self_test=%d, st_code=%d\n", __func__, (int)pf, + (int)self_test, (int)st_cd); + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + if (self_test || st_cd) { + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_DEV_SELT_TEST; + /* just this namespace (if there is one) and controller */ + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + switch (st_cd) { + case 0: /* Here if self_test is set, do short self-test */ + case 1: /* Background short */ + case 5: /* Foreground short */ + nvme_dst = 1; + break; + case 2: /* Background extended */ + case 6: /* Foreground extended */ + nvme_dst = 2; + break; + case 4: /* Abort self-test */ + nvme_dst = 0xf; + break; + default: + pr2ws("%s: bad self-test code [0x%x]\n", __func__, st_cd); + mk_sense_invalid_fld(ptp, true, 1, 7, vb); + return 0; + } + sg_put_unaligned_le32(nvme_dst, npc_up + SG_NVME_PT_CDW10); + err = nvme_pt_low(ptp, NULL, 0x0, true, false, &npc, time_secs, vb); + goto do_low; + } + alloc_len = sg_get_unaligned_be16(cdbp + 3); /* parameter list length */ + dout_len = ptp->dxfer_len; + if (pf) { + if (0 == alloc_len) { + mk_sense_invalid_fld(ptp, true, 3, 7, vb); + if (vb) + pr2ws("%s: PF bit set bit param_list_len=0\n", __func__); + return 0; + } + } else { /* PF bit clear */ + if (alloc_len) { + mk_sense_invalid_fld(ptp, true, 3, 7, vb); + if (vb) + pr2ws("%s: param_list_len>0 but PF clear\n", __func__); + return 0; + } else + return 0; /* nothing to do */ + if (dout_len > 0) { + if (vb) + pr2ws("%s: dout given but PF clear\n", __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + } + if (dout_len < 4) { + if (vb) + pr2ws("%s: dout length (%u bytes) too short\n", __func__, + dout_len); + return SCSI_PT_DO_BAD_PARAMS; + } + n = dout_len; + n = (n < alloc_len) ? n : alloc_len; + dop = (const uint8_t *)ptp->dxferp; + if (! sg_is_aligned(dop, 0)) { + if (vb) + pr2ws("%s: dout [0x%" PRIx64 "] not page aligned\n", __func__, + (uint64_t)ptp->dxferp); + return SCSI_PT_DO_BAD_PARAMS; + } + dpg_cd = dop[0]; + dpg_len = sg_get_unaligned_be16(dop + 2) + 4; + /* should we allow for more than one D_PG is dout ?? */ + n = (n < dpg_len) ? n : dpg_len; /* not yet ... */ + + if (vb) + pr2ws("%s: passing through d_pg=0x%x, len=%u to NVME_MI SES send\n", + __func__, dpg_cd, dpg_len); + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_MI_SEND; + sg_put_unaligned_le64((sg_uintptr_t)ptp->dxferp, + npc_up + SG_NVME_PT_ADDR); + /* NVMe 4k page size. Maybe determine this? */ + /* dout_len > 0x1000, is this a problem?? */ + sg_put_unaligned_le32(0x1000, npc_up + SG_NVME_PT_DATA_LEN); + /* NVMe Message Header */ + sg_put_unaligned_le32(0x0804, npc_up + SG_NVME_PT_CDW10); + /* nvme_mi_ses_send; (0x8 -> mi_ses_recv) */ + sg_put_unaligned_le32(0x9, npc_up + SG_NVME_PT_CDW11); + /* data-out length I hope */ + sg_put_unaligned_le32(n, npc_up + SG_NVME_PT_CDW13); + err = nvme_pt_low(ptp, ptp->dxferp, 0x1000, true, false, &npc, time_secs, + vb); +do_low: + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + return 0; +} + +/* This is not really a SNTL. For SCSI RECEIVE DIAGNOSTIC RESULTS(PCV=1) + * NVMe-MI has a special command (SES Receive) to read pages through a + * tunnel from an enclosure. The NVMe enclosure is meant to understand the + * SES (SCSI Enclosure Services) use of diagnostics pages that are + * related to SES. */ +static int +sntl_recvdiag(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool pcv; + int err; + uint8_t dpg_cd; + uint32_t alloc_len, n, din_len; + const uint8_t * dip; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + pcv = !! (0x1 & cdbp[1]); + dpg_cd = cdbp[2]; + alloc_len = sg_get_unaligned_be16(cdbp + 3); /* parameter list length */ + if (vb > 5) + pr2ws("%s: dpg_cd=0x%x, pcv=%d, alloc_len=0x%x\n", __func__, + dpg_cd, (int)pcv, alloc_len); + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + din_len = ptp->dxfer_len; + if (pcv) { + if (0 == alloc_len) { + /* T10 says not an error, hmmm */ + mk_sense_invalid_fld(ptp, true, 3, 7, vb); + if (vb) + pr2ws("%s: PCV bit set bit but alloc_len=0\n", __func__); + return 0; + } + } else { /* PCV bit clear */ + if (alloc_len) { + mk_sense_invalid_fld(ptp, true, 3, 7, vb); + if (vb) + pr2ws("%s: alloc_len>0 but PCV clear\n", __func__); + return 0; + } else + return 0; /* nothing to do */ + if (din_len > 0) { + if (vb) + pr2ws("%s: din given but PCV clear\n", __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + } + n = din_len; + n = (n < alloc_len) ? n : alloc_len; + dip = (const uint8_t *)ptp->dxferp; + if (! sg_is_aligned(dip, 0)) { + if (vb) + pr2ws("%s: din [0x%" PRIx64 "] not page aligned\n", __func__, + (uint64_t)ptp->dxferp); + return SCSI_PT_DO_BAD_PARAMS; + } + + if (vb) + pr2ws("%s: expecting d_pg=0x%x from NVME_MI SES receive\n", __func__, + dpg_cd); + memset(npc_up, 0, sizeof(npc)); + npc_up[SG_NVME_PT_OPCODE] = SG_NVME_AD_MI_RECEIVE; + sg_put_unaligned_le64((sg_uintptr_t)ptp->dxferp, + npc_up + SG_NVME_PT_ADDR); + /* NVMe 4k page size. Maybe determine this? */ + /* dout_len > 0x1000, is this a problem?? */ + sg_put_unaligned_le32(0x1000, npc_up + SG_NVME_PT_DATA_LEN); + /* NVMe Message Header */ + sg_put_unaligned_le32(0x0804, npc_up + SG_NVME_PT_CDW10); + /* nvme_mi_ses_receive */ + sg_put_unaligned_le32(0x8, npc_up + SG_NVME_PT_CDW11); + sg_put_unaligned_le32(dpg_cd, npc_up + SG_NVME_PT_CDW12); + /* data-in length I hope */ + sg_put_unaligned_le32(n, npc_up + SG_NVME_PT_CDW13); + err = nvme_pt_low(ptp, ptp->dxferp, 0x1000, true, true, &npc, time_secs, + vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + ptp->resid = din_len - n; + return 0; +} + +#define F_SA_LOW 0x80 /* cdb byte 1, bits 4 to 0 */ +#define F_SA_HIGH 0x100 /* as used by variable length cdbs */ +#define FF_SA (F_SA_HIGH | F_SA_LOW) +#define F_INV_OP 0x200 + +static int +sntl_rep_opcodes(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool rctd; + uint8_t reporting_opts, req_opcode, supp; + uint16_t req_sa; + uint32_t alloc_len, offset, a_len; + uint32_t pg_sz = sg_get_page_size(); + int len, count, bump; + const struct sg_opcode_info_t *oip; + uint8_t *arr; + uint8_t *free_arr; + + if (vb > 5) + pr2ws("%s: time_secs=%d\n", __func__, time_secs); + rctd = !!(cdbp[2] & 0x80); /* report command timeout desc. */ + reporting_opts = cdbp[2] & 0x7; + req_opcode = cdbp[3]; + req_sa = sg_get_unaligned_be16(cdbp + 4); + alloc_len = sg_get_unaligned_be32(cdbp + 6); + if (alloc_len < 4 || alloc_len > 0xffff) { + mk_sense_invalid_fld(ptp, true, 6, -1, vb); + return 0; + } + a_len = pg_sz - 72; + arr = sg_memalign(pg_sz, pg_sz, &free_arr, vb > 3); + if (NULL == arr) { + if (vb) + pr2ws("%s: calloc() failed to get memory\n", __func__); + return -ENOMEM; + } + switch (reporting_opts) { + case 0: /* all commands */ + count = 0; + bump = rctd ? 20 : 8; + for (offset = 4, oip = sg_get_opcode_translation(); + (oip->flags != 0xffff) && (offset < a_len); ++oip) { + if (F_INV_OP & oip->flags) + continue; + ++count; + arr[offset] = oip->opcode; + sg_put_unaligned_be16(oip->sa, arr + offset + 2); + if (rctd) + arr[offset + 5] |= 0x2; + if (FF_SA & oip->flags) + arr[offset + 5] |= 0x1; + sg_put_unaligned_be16(oip->len_mask[0], arr + offset + 6); + if (rctd) + sg_put_unaligned_be16(0xa, arr + offset + 8); + offset += bump; + } + sg_put_unaligned_be32(count * bump, arr + 0); + break; + case 1: /* one command: opcode only */ + case 2: /* one command: opcode plus service action */ + case 3: /* one command: if sa==0 then opcode only else opcode+sa */ + for (oip = sg_get_opcode_translation(); oip->flags != 0xffff; ++oip) { + if ((req_opcode == oip->opcode) && (req_sa == oip->sa)) + break; + } + if ((0xffff == oip->flags) || (F_INV_OP & oip->flags)) { + supp = 1; + offset = 4; + } else { + if (1 == reporting_opts) { + if (FF_SA & oip->flags) { + mk_sense_invalid_fld(ptp, true, 2, 2, vb); + free(free_arr); + return 0; + } + req_sa = 0; + } else if ((2 == reporting_opts) && 0 == (FF_SA & oip->flags)) { + mk_sense_invalid_fld(ptp, true, 4, -1, vb); + free(free_arr); + return 0; + } + if ((0 == (FF_SA & oip->flags)) && (req_opcode == oip->opcode)) + supp = 3; + else if (0 == (FF_SA & oip->flags)) + supp = 1; + else if (req_sa != oip->sa) + supp = 1; + else + supp = 3; + if (3 == supp) { + uint16_t u = oip->len_mask[0]; + int k; + + sg_put_unaligned_be16(u, arr + 2); + arr[4] = oip->opcode; + for (k = 1; k < u; ++k) + arr[4 + k] = (k < 16) ? + oip->len_mask[k] : 0xff; + offset = 4 + u; + } else + offset = 4; + } + arr[1] = (rctd ? 0x80 : 0) | supp; + if (rctd) { + sg_put_unaligned_be16(0xa, arr + offset); + offset += 12; + } + break; + default: + mk_sense_invalid_fld(ptp, true, 2, 2, vb); + free(free_arr); + return 0; + } + offset = (offset < a_len) ? offset : a_len; + len = (offset < alloc_len) ? offset : alloc_len; + ptp->resid = ptp->dxfer_len - (int)len; + if (len > 0) + memcpy((uint8_t *)ptp->dxferp, arr, len); + free(free_arr); + return 0; +} + +static int +sntl_rep_tmfs(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool repd; + uint32_t alloc_len, len; + uint8_t arr[16]; + + if (vb > 5) + pr2ws("%s: time_secs=%d\n", __func__, time_secs); + memset(arr, 0, sizeof(arr)); + repd = !!(cdbp[2] & 0x80); + alloc_len = sg_get_unaligned_be32(cdbp + 6); + if (alloc_len < 4) { + mk_sense_invalid_fld(ptp, true, 6, -1, vb); + return 0; + } + arr[0] = 0xc8; /* ATS | ATSS | LURS */ + arr[1] = 0x1; /* ITNRS */ + if (repd) { + arr[3] = 0xc; + len = 16; + } else + len = 4; + + len = (len < alloc_len) ? len : alloc_len; + ptp->resid = ptp->dxfer_len - (int)len; + if (len > 0) + memcpy((uint8_t *)ptp->dxferp, arr, len); + return 0; +} + +static int +sntl_rread(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool is_read10 = (SCSI_READ10_OPC == cdbp[0]); + bool have_fua = !!(cdbp[1] & 0x8); + int err; + uint32_t nblks_t10 = 0; /* 'control' in upper 16 bits */ + uint64_t lba; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + if (vb > 5) + pr2ws("%s: fua=%d\n", __func__, (int)have_fua); + fdc_p = get_fdc_p(ptp); + memset(&npc, 0, sizeof(npc)); + npc.cmd.opc = SG_NVME_NVM_READ; + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + if (is_read10) { + lba = sg_get_unaligned_be32(cdbp + 2); + nblks_t10 = sg_get_unaligned_be16(cdbp + 7); + } else { + lba = sg_get_unaligned_be64(cdbp + 2); + nblks_t10 = sg_get_unaligned_be32(cdbp + 10); + if (nblks_t10 > (UINT16_MAX + 1)) { + mk_sense_invalid_fld(ptp, true, 11, -1, vb); + return 0; + } + } + if (0 == nblks_t10) { /* NOP in SCSI */ + if (vb > 4) + pr2ws("%s: nblks_t10 is 0, a NOP in SCSI, can't map to NVMe\n", + __func__); + return 0; + } + --nblks_t10; /* crazy "0's based" counts */ + sg_put_unaligned_le64(lba, npc_up + SG_NVME_PT_CDW10); /* fills W11 too */ + if (have_fua) + nblks_t10 |= SG_NVME_RW_CDW12_FUA; + sg_put_unaligned_le32(nblks_t10, npc_up + SG_NVME_PT_CDW12); + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + + err = nvme_pt_low(ptp, ptp->dxferp, ptp->dxfer_len, false, true, &npc, + time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + ptp->resid = 0; /* hoping */ + return 0; +} + +static int +sntl_write(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool is_write10 = (SCSI_WRITE10_OPC == cdbp[0]); + bool have_fua = !!(cdbp[1] & 0x8); + int err; + uint32_t nblks_t10 = 0; + uint64_t lba; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + if (vb > 5) + pr2ws("%s: fua=%d, time_secs=%d\n", __func__, (int)have_fua, + time_secs); + fdc_p = get_fdc_p(ptp); + memset(&npc, 0, sizeof(npc)); + npc.cmd.opc = SG_NVME_NVM_WRITE; + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + if (is_write10) { + lba = sg_get_unaligned_be32(cdbp + 2); + nblks_t10 = sg_get_unaligned_be16(cdbp + 7); + } else { + lba = sg_get_unaligned_be64(cdbp + 2); + nblks_t10 = sg_get_unaligned_be32(cdbp + 10); + if (nblks_t10 > (UINT16_MAX + 1)) { + mk_sense_invalid_fld(ptp, true, 11, -1, vb); + return 0; + } + } + if (0 == nblks_t10) { /* NOP in SCSI */ + if (vb > 4) + pr2ws("%s: nblks_t10 is 0, a NOP in SCSI, can't map to NVMe\n", + __func__); + return 0; + } + --nblks_t10; + sg_put_unaligned_le64(lba, npc_up + SG_NVME_PT_CDW10); /* fills W11 too */ + if (have_fua) + nblks_t10 |= SG_NVME_RW_CDW12_FUA; + sg_put_unaligned_le32(nblks_t10, npc_up + SG_NVME_PT_CDW12); + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + + err = nvme_pt_low(ptp, ptp->dxferp, ptp->dxfer_len, false, false, &npc, + time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + ptp->resid = 0; + return 0; +} + +static int +sntl_verify(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool is_verify10 = (SCSI_VERIFY10_OPC == cdbp[0]); + uint8_t bytchk = (cdbp[1] >> 1) & 0x3; + int err; + uint32_t nblks_t10 = 0; + uint64_t lba; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + if (vb > 5) + pr2ws("%s: bytchk=%d, time_secs=%d\n", __func__, bytchk, time_secs); + if (bytchk > 1) { + mk_sense_invalid_fld(ptp, true, 1, 2, vb); + return 0; + } + fdc_p = get_fdc_p(ptp); + memset(&npc, 0, sizeof(npc)); + npc.cmd.opc = bytchk ? SG_NVME_NVM_COMPARE : SG_NVME_NVM_VERIFY; + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + if (is_verify10) { + lba = sg_get_unaligned_be32(cdbp + 2); + nblks_t10 = sg_get_unaligned_be16(cdbp + 7); + } else { + lba = sg_get_unaligned_be64(cdbp + 2); + nblks_t10 = sg_get_unaligned_be32(cdbp + 10); + if (nblks_t10 > (UINT16_MAX + 1)) { + mk_sense_invalid_fld(ptp, true, 11, -1, vb); + return 0; + } + } + if (0 == nblks_t10) { /* NOP in SCSI */ + if (vb > 4) + pr2ws("%s: nblks_t10 is 0, a NOP in SCSI, can't map to NVMe\n", + __func__); + return 0; + } + --nblks_t10; + sg_put_unaligned_le64(lba, npc_up + SG_NVME_PT_CDW10); /* fills W11 too */ + sg_put_unaligned_le32(nblks_t10, npc_up + SG_NVME_PT_CDW12); + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + + err = nvme_pt_low(ptp, ptp->dxferp, ptp->dxfer_len, false, false, &npc, + time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + ptp->resid = 0; + return 0; +} + +static int +sntl_write_same(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool is_ws10 = (SCSI_WRITE_SAME10_OPC == cdbp[0]); + bool ndob = is_ws10 ? false : !!(0x1 & cdbp[1]); + int err; + int nblks_t10 = 0; + uint64_t lba; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + if (vb > 5) + pr2ws("%s: ndob=%d, time_secs=%d\n", __func__, (int)ndob, time_secs); + if (! ndob) { + int flbas, index, lbafx, lbads, lbsize; + uint8_t * up; + uint8_t * dp; + + dp = ptp->dxferp; + up = ptp->mchanp->nvme_id_ctlp; + if ((dp == NULL) || (up == NULL)) + return sg_convert_errno(ENOMEM); + flbas = up[26]; /* NVME FLBAS field from Identify */ + index = 128 + (4 * (flbas & 0xf)); + lbafx = sg_get_unaligned_le32(up + index); + lbads = (lbafx >> 16) & 0xff; /* bits 16 to 23 inclusive, pow2 */ + lbsize = 1 << lbads; + if (! sg_all_zeros(dp, lbsize)) { + mk_sense_asc_ascq(ptp, SPC_SK_ILLEGAL_REQUEST, PCIE_ERR_ASC, + PCIE_UNSUPP_REQ_ASCQ, vb); + return 0; + } + /* so given single LB full of zeros, can translate .... */ + } + fdc_p = ptp->mchanp; + memset(&npc, 0, sizeof(npc)); + npc.cmd.opc = SG_NVME_NVM_WRITE_ZEROES; + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + if (is_ws10) { + lba = sg_get_unaligned_be32(cdbp + 2); + nblks_t10 = sg_get_unaligned_be16(cdbp + 7); + } else { + uint32_t num = sg_get_unaligned_be32(cdbp + 10); + + lba = sg_get_unaligned_be64(cdbp + 2); + if (num > (UINT16_MAX + 1)) { + mk_sense_invalid_fld(ptp, true, 11, -1, vb); + return 0; + } else + nblks_t10 = num; + } + if (0 == nblks_t10) { /* NOP in SCSI */ + if (vb > 4) + pr2ws("%s: nblks_t10 is 0, a NOP in SCSI, can't map to NVMe\n", + __func__); + return 0; + } + --nblks_t10; + sg_put_unaligned_le64(lba, npc_up + SG_NVME_PT_CDW10); /* fills W11 too */ + sg_put_unaligned_le32(nblks_t10, npc_up + SG_NVME_PT_CDW12); + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + + err = nvme_pt_low(ptp, ptp->dxferp, ptp->dxfer_len, false, false, &npc, + time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + ptp->resid = 0; + return 0; +} + +static int +sntl_sync_cache(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool immed = !!(0x2 & cdbp[1]); + int err; + struct nvme_pt_command npc; + uint8_t * npc_up = (uint8_t *)&npc; + struct freebsd_dev_channel * fdc_p; + + if (vb > 5) + pr2ws("%s: immed=%d, time_secs=%d\n", __func__, (int)immed, + time_secs); + fdc_p = ptp->mchanp; + memset(&npc, 0, sizeof(npc)); + npc.cmd.opc = SG_NVME_NVM_FLUSH; + sg_put_unaligned_le32(fdc_p->nsid, npc_up + SG_NVME_PT_NSID); + if (vb > 4) + pr2ws("%s: immed bit, lba and num_lbs fields ignored\n", __func__); + err = nvme_pt_low(ptp, ptp->dxferp, ptp->dxfer_len, false, false, &npc, + time_secs, vb); + if (err) { + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } else { + ptp->nvme_status = err; + mk_sense_from_nvme_status(ptp, err, vb); + return 0; + } + } + ptp->resid = 0; + return 0; +} + +static int +sntl_start_stop(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool immed = !!(0x1 & cdbp[1]); + + if (vb > 5) + pr2ws("%s: immed=%d, time_secs=%d, ignore\n", __func__, (int)immed, + time_secs); + if (ptp) { } /* suppress warning */ + return 0; +} + +/* Note that the "Returned logical block address" (RLBA) field in the SCSI + * READ CAPACITY (10+16) command's response provides the address of the _last_ + * LBA (counting origin 0) which will be one less that the "size" in the + * NVMe Identify command response's NSZE field. One problem is that in + * some situations NSZE can be zero: temporarily set RLBA field to 0 + * (implying a 1 LB logical units size) pending further research. The LBLIB + * is the "Logical Block Length In Bytes" field in the RCAP response. */ +static int +sntl_readcap(struct sg_pt_freebsd_scsi * ptp, const uint8_t * cdbp, + int time_secs, int vb) +{ + bool is_rcap10 = (SCSI_READ_CAPACITY10_OPC == cdbp[0]); + int res, n, len, alloc_len, dps; + uint8_t flbas, index, lbads; /* NVMe: 2**LBADS --> Logical Block size */ + uint32_t lbafx; /* NVME: LBAF0...LBAF15, each 16 bytes */ + uint32_t pg_sz = sg_get_page_size(); + uint64_t nsze; + uint8_t * bp; + uint8_t * up; + uint8_t * free_up = NULL; + struct freebsd_dev_channel * fdc_p; + uint8_t resp[32]; + + if (vb > 5) + pr2ws("%s: RCAP%d\n", __func__, (is_rcap10 ? 10 : 16)); + fdc_p = ptp->mchanp; + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: get_fdc_p() failed, no file descriptor ?\n", __func__); + return -EINVAL; + } + up = sg_memalign(pg_sz, pg_sz, &free_up, false); + if (NULL == up) { + if (vb) + pr2ws("%s: sg_memalign() failed to get memory\n", __func__); + return sg_convert_errno(ENOMEM); + } + res = sntl_do_identify(ptp, 0x0 /* CNS */, fdc_p->nsid, pg_sz, up, + time_secs, vb); + if (res < 0) { + res = sg_convert_errno(-res); + goto fini; + } + memset(resp, 0, sizeof(resp)); + nsze = sg_get_unaligned_le64(up + 0); + flbas = up[26]; /* NVME FLBAS field from Identify, want LBAF[flbas] */ + index = 128 + (4 * (flbas & 0xf)); + lbafx = sg_get_unaligned_le32(up + index); + lbads = (lbafx >> 16) & 0xff; /* bits 16 to 23 inclusive, pow2 */ + if (is_rcap10) { + alloc_len = 8; /* implicit, not in cdb */ + if (nsze > 0xffffffff) + sg_put_unaligned_be32(0xffffffff, resp + 0); + else if (0 == nsze) /* no good answer here */ + sg_put_unaligned_be32(0, resp + 0); /* SCSI RLBA field */ + else + sg_put_unaligned_be32((uint32_t)(nsze - 1), resp + 0); + sg_put_unaligned_be32(1 << lbads, resp + 4); /* SCSI LBLIB field */ + } else { + alloc_len = sg_get_unaligned_be32(cdbp + 10); + dps = up[29]; + if (0x7 & dps) { + resp[12] = 0x1; + n = (0x7 & dps) - 1; + if (n > 0) + resp[12] |= (n + n); + } + if (0 == nsze) /* no good answer here */ + sg_put_unaligned_be64(0, resp + 0); + else + sg_put_unaligned_be64(nsze - 1, resp + 0); + sg_put_unaligned_be32(1 << lbads, resp + 8); /* SCSI LBLIB field */ + } + len = ptp->dxfer_len; + bp = ptp->dxferp; + n = 32; + n = (n < alloc_len) ? n : alloc_len; + n = (n < len) ? n : len; + ptp->resid = len - n; + if (n > 0) + memcpy(bp, resp, n); +fini: + if (free_up) + free(free_up); + return res; +} + +/* Executes NVMe Admin command (or at least forwards it to lower layers). + * Depending on the device, this could be NVME(via CAM) or NVME(non-CAM). + * is_admin will be overridden if the SNTL functions are called. + * Returns 0 for success, negative numbers are negated 'errno' values from + * OS system calls. Positive return values are errors from this package. */ +static int +sg_do_nvme_pt(struct sg_pt_freebsd_scsi * ptp, int fd, bool is_admin, + int time_secs, int vb) +{ + bool scsi_cdb, in_xfer; + int n, err, len, io_len; + uint16_t sct_sc, sa; + uint8_t * dxferp; + uint8_t * npc_up; + struct freebsd_dev_channel * fdc_p; + const uint8_t * cdbp; + struct nvme_pt_command npc; + + npc_up = (uint8_t *)&npc; + if (vb > 6) + pr2ws("%s: fd=%d, is_admin=%d\n", __func__, fd, (int)is_admin); + if (! ptp->cdb) { + if (vb) + pr2ws("%s: No NVMe command given (set_scsi_pt_cdb())\n", + __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + fdc_p = ptp->mchanp; + if (fd < 0) { + if (NULL == fdc_p) { + if (vb) + pr2ws("%s: no device handle in object or fd ?\n", __func__); + return -EINVAL; + } + /* no fd, but have fdc_p so that is okay */ + } else { + int han = fd - FREEBSD_FDOFFSET; + + if ((han < 0) || (han >= FREEBSD_MAXDEV)) { + if (vb) + pr2ws("%s: argument 'fd' is bad\n", __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + if (NULL == devicetable[han]) { + if (vb) + pr2ws("%s: argument 'fd' is bad (2)\n", __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + if (fdc_p && (fdc_p != devicetable[han])) { + if (vb) + pr2ws("%s: different device handle in object and fd ?\n", + __func__); + return SCSI_PT_DO_BAD_PARAMS; + } + if (NULL == fdc_p) { + ptp->dev_han = fd; + fdc_p = devicetable[han]; + } + } + + ptp->is_nvme_dev = fdc_p->is_nvme_dev; + n = ptp->cdb_len; + cdbp = (const uint8_t *)ptp->cdb; + if (vb > 3) + pr2ws("%s: opcode=0x%x, fd=%d\n", __func__, cdbp[0], fd); + scsi_cdb = sg_is_scsi_cdb(cdbp, n); + /* nvme_our_sntl is false when NVMe command (64 byte) has been given */ + ptp->nvme_our_sntl = scsi_cdb; + if (scsi_cdb) { + switch (cdbp[0]) { + case SCSI_INQUIRY_OPC: + return sntl_inq(ptp, cdbp, time_secs, vb); + case SCSI_REPORT_LUNS_OPC: + return sntl_rluns(ptp, cdbp, time_secs, vb); + case SCSI_TEST_UNIT_READY_OPC: + return sntl_tur(ptp, time_secs, vb); + case SCSI_REQUEST_SENSE_OPC: + return sntl_req_sense(ptp, cdbp, time_secs, vb); + case SCSI_READ10_OPC: + case SCSI_READ16_OPC: + return sntl_rread(ptp, cdbp, time_secs, vb); + case SCSI_WRITE10_OPC: + case SCSI_WRITE16_OPC: + return sntl_write(ptp, cdbp, time_secs, vb); + case SCSI_START_STOP_OPC: + return sntl_start_stop(ptp, cdbp, time_secs, vb); + case SCSI_SEND_DIAGNOSTIC_OPC: + return sntl_senddiag(ptp, cdbp, time_secs, vb); + case SCSI_RECEIVE_DIAGNOSTIC_OPC: + return sntl_recvdiag(ptp, cdbp, time_secs, vb); + case SCSI_MODE_SENSE10_OPC: + case SCSI_MODE_SELECT10_OPC: + return sntl_mode_ss(ptp, cdbp, time_secs, vb); + case SCSI_READ_CAPACITY10_OPC: + return sntl_readcap(ptp, cdbp, time_secs, vb); + case SCSI_VERIFY10_OPC: + case SCSI_VERIFY16_OPC: + return sntl_verify(ptp, cdbp, time_secs, vb); + case SCSI_WRITE_SAME10_OPC: + case SCSI_WRITE_SAME16_OPC: + return sntl_write_same(ptp, cdbp, time_secs, vb); + case SCSI_SYNC_CACHE10_OPC: + case SCSI_SYNC_CACHE16_OPC: + return sntl_sync_cache(ptp, cdbp, time_secs, vb); + case SCSI_SERVICE_ACT_IN_OPC: + if (SCSI_READ_CAPACITY16_SA == (cdbp[1] & SCSI_SA_MSK)) + return sntl_readcap(ptp, cdbp, time_secs, vb); + goto fini; + case SCSI_MAINT_IN_OPC: + sa = SCSI_SA_MSK & cdbp[1]; /* service action */ + if (SCSI_REP_SUP_OPCS_OPC == sa) + return sntl_rep_opcodes(ptp, cdbp, time_secs, vb); + else if (SCSI_REP_SUP_TMFS_OPC == sa) + return sntl_rep_tmfs(ptp, cdbp, time_secs, vb); + /* fall through */ + default: +fini: + if (vb > 2) { + char b[64]; + + sg_get_command_name(cdbp, -1, sizeof(b), b); + pr2ws("%s: no translation to NVMe for SCSI %s command\n", + __func__, b); + } + mk_sense_asc_ascq(ptp, SPC_SK_ILLEGAL_REQUEST, INVALID_OPCODE, + 0, vb); + return 0; + } + } + + /* NVMe command given to pass-through */ + if (vb > 4) + pr2ws("%s: NVMe pass-through command, admin=%d\n", __func__, + is_admin); + len = (int)sizeof(npc.cmd); + n = (n < len) ? n : len; + if (n < 64) { + if (vb) + pr2ws("%s: command length of %d bytes is too short\n", __func__, + n); + return SCSI_PT_DO_BAD_PARAMS; + } + memcpy(npc_up, (const uint8_t *)ptp->cdb, n); + if (n < len) /* zero out rest of 'npc' */ + memset(npc_up + n, 0, len - n); + in_xfer = false; + io_len = 0; + dxferp = NULL; + if (ptp->dxfer_ilen > 0) { + in_xfer = true; + io_len = ptp->dxfer_ilen; + dxferp = ptp->dxferip; + sg_put_unaligned_le32(ptp->dxfer_ilen, npc_up + SG_NVME_PT_DATA_LEN); + sg_put_unaligned_le64((sg_uintptr_t)ptp->dxferip, + npc_up + SG_NVME_PT_ADDR); + } else if (ptp->dxfer_olen > 0) { + in_xfer = false; + io_len = ptp->dxfer_olen; + dxferp = ptp->dxferop; + sg_put_unaligned_le32(ptp->dxfer_olen, npc_up + SG_NVME_PT_DATA_LEN); + sg_put_unaligned_le64((sg_uintptr_t)ptp->dxferop, + npc_up + SG_NVME_PT_ADDR); + } + err = nvme_pt_low(ptp, dxferp, io_len, is_admin, in_xfer, &npc, time_secs, + vb); + if (err < 0) { + if (vb > 1) + pr2ws("%s: nvme_pt_low() failed: %s (errno=%d)\n", + __func__, strerror(-err), -err); + return err; + } + sct_sc = err; /* ((SCT << 8) | SC) which may be 0 */ + ptp->nvme_status = sct_sc; + if (ptp->sense && (ptp->sense_len > 0)) { + uint32_t k = sizeof(ptp->cq_dw0_3); + + if ((int)k < ptp->sense_len) + ptp->sense_resid = ptp->sense_len - (int)k; + else { + k = ptp->sense_len; + ptp->sense_resid = 0; + } + memcpy(ptp->sense, ptp->cq_dw0_3, k); + } + if (in_xfer) + ptp->resid = 0; /* Just hoping ... */ + return sct_sc ? SG_LIB_NVME_STATUS : 0; +} + +#endif /* (HAVE_NVME && (! IGNORE_NVME)) */ + + +#if (HAVE_NVME && (! IGNORE_NVME)) + +/* Requires pass-through file to be open and associated with vp */ +int +do_nvm_pt(struct sg_pt_base * vp, int submq, int timeout_secs, int vb) +{ + struct sg_pt_freebsd_scsi * ptp = &vp->impl; + struct freebsd_dev_channel *fdc_p; + + if (vb && (submq != 0)) + pr2ws("%s: warning, uses submit queue 0\n", __func__); + fdc_p = ptp->mchanp; + if (NULL == fdc_p) { + fdc_p = get_fdc_p(ptp); + if (NULL == fdc_p) { + if (vb > 2) + pr2ws("%s: no open file associated with pt object\n", + __func__); + return -EINVAL; + } + ptp->mchanp = fdc_p; + } + return sg_do_nvme_pt(ptp, -1, false, timeout_secs, vb); +} + +#else /* (HAVE_NVME && (! IGNORE_NVME)) */ + +int +do_nvm_pt(struct sg_pt_base * vp, int submq, int timeout_secs, int vb) +{ + if (vb) { + pr2ws("%s: not supported, ", __func__); +#ifdef HAVE_NVME + pr2ws("HAVE_NVME, "); +#else + pr2ws("don't HAVE_NVME, "); +#endif + +#ifdef IGNORE_NVME + pr2ws("IGNORE_NVME"); +#else + pr2ws("don't IGNORE_NVME"); +#endif + } + if (vp) { } + if (submq) { } + if (timeout_secs) { } + return SCSI_PT_DO_NOT_SUPPORTED; +} + +#endif /* (HAVE_NVME && (! IGNORE_NVME)) */ |