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|
/*
* Intel(R) Matrix Storage Manager hardware and firmware support routines
*
* Copyright (C) 2008 Intel Corporation
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along with
* this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include "mdadm.h"
#include "platform-intel.h"
#include "probe_roms.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <dirent.h>
#include <fcntl.h>
#include <sys/mman.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <limits.h>
#define NVME_SUBSYS_PATH "/sys/devices/virtual/nvme-subsystem/"
static bool imsm_orom_has_raid0(const struct imsm_orom *orom)
{
return imsm_rlc_has_bit(orom, IMSM_OROM_RLC_RAID0);
}
static bool imsm_orom_has_raid1(const struct imsm_orom *orom)
{
return imsm_rlc_has_bit(orom, IMSM_OROM_RLC_RAID1);
}
static bool imsm_orom_has_raid10(const struct imsm_orom *orom)
{
return imsm_rlc_has_bit(orom, IMSM_OROM_RLC_RAID10);
}
static bool imsm_orom_has_raid5(const struct imsm_orom *orom)
{
return imsm_rlc_has_bit(orom, IMSM_OROM_RLC_RAID5);
}
/* IMSM platforms do not define how many disks are allowed for each level,
* but there are some global limitations we need to follow.
*/
static bool imsm_orom_support_raid_disks_count_raid0(const int raid_disks)
{
return true;
}
static bool imsm_orom_support_raid_disks_count_raid1(const int raid_disks)
{
if (raid_disks == 2)
return true;
return false;
}
static bool imsm_orom_support_raid_disks_count_raid5(const int raid_disks)
{
if (raid_disks > 2)
return true;
return false;
}
static bool imsm_orom_support_raid_disks_count_raid10(const int raid_disks)
{
/* raid_disks count must be higher than 4 and even */
if (raid_disks >= 4 && (raid_disks & 1) == 0)
return true;
return false;
}
struct imsm_level_ops imsm_level_ops[] = {
{0, imsm_orom_has_raid0, imsm_orom_support_raid_disks_count_raid0, "raid0"},
{1, imsm_orom_has_raid1, imsm_orom_support_raid_disks_count_raid1, "raid1"},
{5, imsm_orom_has_raid5, imsm_orom_support_raid_disks_count_raid5, "raid5"},
{10, imsm_orom_has_raid10, imsm_orom_support_raid_disks_count_raid10, "raid10"},
{-1, NULL, NULL, NULL}
};
static int devpath_to_ll(const char *dev_path, const char *entry,
unsigned long long *val);
static void free_sys_dev(struct sys_dev **list)
{
while (*list) {
struct sys_dev *next = (*list)->next;
if ((*list)->path)
free((*list)->path);
free(*list);
*list = next;
}
}
/**
* vmd_find_pci_bus() - look for PCI bus created by VMD.
* @vmd_path: path to vmd driver.
* @buf: return buffer, must be PATH_MAX.
*
* Each VMD device represents one domain and each VMD device adds separate PCI bus.
* IMSM must know VMD domains, therefore it needs to determine and follow buses.
*
*/
mdadm_status_t vmd_find_pci_bus(char *vmd_path, char *buf)
{
char tmp[PATH_MAX];
struct dirent *ent;
DIR *vmd_dir;
char *rp_ret;
snprintf(tmp, PATH_MAX, "%s/domain/device", vmd_path);
rp_ret = realpath(tmp, buf);
if (rp_ret)
return MDADM_STATUS_SUCCESS;
if (errno != ENOENT)
return MDADM_STATUS_ERROR;
/*
* If it is done early, there is a chance that kernel is still enumerating VMD device but
* kernel did enough to start enumerating child devices, {vmd_path}/domain/device link may
* not exist yet. We have to look into @vmd_path directory and find it ourselves.
*/
vmd_dir = opendir(vmd_path);
if (!vmd_dir)
return MDADM_STATUS_ERROR;
for (ent = readdir(vmd_dir); ent; ent = readdir(vmd_dir)) {
static const char pci[] = "pci";
/**
* Pci bus must have form pciXXXXX:XX, where X is a digit i.e pci10000:00.
* We do not check digits here, it is sysfs so it should be safe to check
* length and ':' position only.
*/
if (strncmp(ent->d_name, pci, strlen(pci)) != 0)
continue;
if (ent->d_name[8] != ':' || ent->d_name[11] != 0)
continue;
break;
}
if (!ent) {
closedir(vmd_dir);
return MDADM_STATUS_ERROR;
}
snprintf(buf, PATH_MAX, "%s/%s", vmd_path, ent->d_name);
closedir(vmd_dir);
return MDADM_STATUS_SUCCESS;
}
struct sys_dev *find_driver_devices(const char *bus, const char *driver)
{
/* search sysfs for devices driven by 'driver' */
char path[PATH_MAX];
char link[PATH_MAX];
char *c;
DIR *driver_dir;
struct dirent *de;
struct sys_dev *head = NULL;
struct sys_dev *list = NULL;
struct sys_dev *vmd = NULL;
enum sys_dev_type type;
unsigned long long dev_id;
unsigned long long class;
if (strcmp(driver, "isci") == 0)
type = SYS_DEV_SAS;
else if (strcmp(driver, "ahci") == 0) {
vmd = find_driver_devices("pci", "vmd");
type = SYS_DEV_SATA;
} else if (strcmp(driver, "nvme") == 0) {
/* if looking for nvme devs, first look for vmd */
vmd = find_driver_devices("pci", "vmd");
type = SYS_DEV_NVME;
} else if (strcmp(driver, "vmd") == 0)
type = SYS_DEV_VMD;
else
type = SYS_DEV_UNKNOWN;
sprintf(path, "/sys/bus/%s/drivers/%s", bus, driver);
driver_dir = opendir(path);
if (!driver_dir) {
if (vmd)
free_sys_dev(&vmd);
return NULL;
}
for (de = readdir(driver_dir); de; de = readdir(driver_dir)) {
int skip = 0;
char *p;
int n;
/* is 'de' a device? check that the 'subsystem' link exists and
* that its target matches 'bus'
*/
sprintf(path, "/sys/bus/%s/drivers/%s/%s/subsystem",
bus, driver, de->d_name);
n = readlink(path, link, sizeof(link));
if (n < 0 || n >= (int)sizeof(link))
continue;
link[n] = '\0';
c = strrchr(link, '/');
if (!c)
continue;
if (strncmp(bus, c+1, strlen(bus)) != 0)
continue;
sprintf(path, "/sys/bus/%s/drivers/%s/%s",
bus, driver, de->d_name);
/* if searching for nvme - skip vmd connected one */
if (type == SYS_DEV_NVME) {
struct sys_dev *dev;
char *rp = realpath(path, NULL);
for (dev = vmd; dev; dev = dev->next) {
if ((strncmp(dev->path, rp, strlen(dev->path)) == 0))
skip = 1;
}
free(rp);
}
/* change sata type if under a vmd controller */
if (type == SYS_DEV_SATA) {
struct sys_dev *dev;
char *rp = realpath(path, NULL);
for (dev = vmd; dev; dev = dev->next) {
if ((strncmp(dev->path, rp, strlen(dev->path)) == 0))
type = SYS_DEV_SATA_VMD;
}
free(rp);
}
/* if it's not Intel device or mark as VMD connected - skip it. */
if (devpath_to_vendor(path) != 0x8086 || skip == 1)
continue;
if (devpath_to_ll(path, "device", &dev_id) != 0)
continue;
if (devpath_to_ll(path, "class", &class) != 0)
continue;
if (type == SYS_DEV_VMD) {
char vmd_path[PATH_MAX];
sprintf(vmd_path, "/sys/bus/%s/drivers/%s/%s", bus, driver, de->d_name);
if (vmd_find_pci_bus(vmd_path, path)) {
pr_err("Cannot determine VMD bus for %s\n", vmd_path);
continue;
}
}
p = realpath(path, NULL);
if (!p) {
pr_err("Unable to get real path for '%s'\n", path);
continue;
}
/* start / add list entry */
if (!head) {
head = xmalloc(sizeof(*head));
list = head;
} else {
list->next = xmalloc(sizeof(*head));
list = list->next;
}
if (!list) {
free_sys_dev(&head);
break;
}
list->dev_id = (__u16) dev_id;
list->class = (__u32) class;
list->type = type;
list->next = NULL;
list->path = p;
if ((list->pci_id = strrchr(list->path, '/')) != NULL)
list->pci_id++;
}
closedir(driver_dir);
/* nvme vmd needs a list separate from sata vmd */
if (vmd && type == SYS_DEV_NVME) {
if (list)
list->next = vmd;
else
head = vmd;
}
return head;
}
static struct sys_dev *intel_devices=NULL;
static time_t valid_time = 0;
struct sys_dev *device_by_id(__u16 device_id)
{
struct sys_dev *iter;
for (iter = intel_devices; iter != NULL; iter = iter->next)
if (iter->dev_id == device_id)
return iter;
return NULL;
}
struct sys_dev *device_by_id_and_path(__u16 device_id, const char *path)
{
struct sys_dev *iter;
for (iter = intel_devices; iter != NULL; iter = iter->next)
if ((iter->dev_id == device_id) && strstr(iter->path, path))
return iter;
return NULL;
}
static int devpath_to_ll(const char *dev_path, const char *entry, unsigned long long *val)
{
char path[strnlen(dev_path, PATH_MAX) + strnlen(entry, PATH_MAX) + 2];
int fd;
int n;
sprintf(path, "%s/%s", dev_path, entry);
fd = open(path, O_RDONLY);
if (fd < 0)
return -1;
n = sysfs_fd_get_ll(fd, val);
close(fd);
return n;
}
__u16 devpath_to_vendor(const char *dev_path)
{
char path[strlen(dev_path) + strlen("/vendor") + 1];
char vendor[7];
int fd;
__u16 id = 0xffff;
int n;
sprintf(path, "%s/vendor", dev_path);
fd = open(path, O_RDONLY);
if (fd < 0)
return 0xffff;
n = read(fd, vendor, sizeof(vendor));
if (n == sizeof(vendor)) {
vendor[n - 1] = '\0';
id = strtoul(vendor, NULL, 16);
}
close(fd);
return id;
}
/* Description: Read text value of dev_path/entry field
* Parameters:
* dev_path - sysfs path to the device
* entry - entry to be read
* buf - buffer for read value
* len - size of buf
* verbose - error logging level
*/
int devpath_to_char(const char *dev_path, const char *entry, char *buf, int len,
int verbose)
{
char path[PATH_MAX];
snprintf(path, sizeof(path), "%s/%s", dev_path, entry);
if (load_sys(path, buf, len)) {
if (verbose)
pr_err("Cannot read %s, aborting\n", path);
return 1;
}
return 0;
}
struct sys_dev *find_intel_devices(void)
{
struct sys_dev *ahci, *isci, *nvme;
if (valid_time > time(0) - 10)
return intel_devices;
if (intel_devices)
free_sys_dev(&intel_devices);
isci = find_driver_devices("pci", "isci");
/* Searching for AHCI will return list of SATA and SATA VMD controllers */
ahci = find_driver_devices("pci", "ahci");
/* Searching for NVMe will return list of NVMe and VMD controllers */
nvme = find_driver_devices("pci", "nvme");
if (!isci && !ahci) {
ahci = nvme;
} else if (!ahci) {
ahci = isci;
struct sys_dev *elem = ahci;
while (elem->next)
elem = elem->next;
elem->next = nvme;
} else {
struct sys_dev *elem = ahci;
while (elem->next)
elem = elem->next;
elem->next = isci;
while (elem->next)
elem = elem->next;
elem->next = nvme;
}
intel_devices = ahci;
valid_time = time(0);
return intel_devices;
}
/*
* PCI Expansion ROM Data Structure Format */
struct pciExpDataStructFormat {
__u8 ver[4];
__u16 vendorID;
__u16 deviceID;
__u16 devListOffset;
__u16 pciDataStructLen;
__u8 pciDataStructRev;
} __attribute__ ((packed));
struct orom_entry *orom_entries;
const struct orom_entry *get_orom_entry_by_device_id(__u16 dev_id)
{
struct orom_entry *entry;
struct devid_list *devid;
for (entry = orom_entries; entry; entry = entry->next) {
for (devid = entry->devid_list; devid; devid = devid->next) {
if (devid->devid == dev_id)
return entry;
}
}
return NULL;
}
const struct imsm_orom *get_orom_by_device_id(__u16 dev_id)
{
const struct orom_entry *entry = get_orom_entry_by_device_id(dev_id);
if (entry)
return &entry->orom;
return NULL;
}
static struct orom_entry *add_orom(const struct imsm_orom *orom)
{
struct orom_entry *list;
struct orom_entry *prev = NULL;
for (list = orom_entries; list; prev = list, list = list->next)
;
list = xmalloc(sizeof(struct orom_entry));
list->orom = *orom;
list->devid_list = NULL;
list->next = NULL;
if (prev == NULL)
orom_entries = list;
else
prev->next = list;
return list;
}
static void add_orom_device_id(struct orom_entry *entry, __u16 dev_id)
{
struct devid_list *list;
struct devid_list *prev = NULL;
for (list = entry->devid_list; list; prev = list, list = list->next) {
if (list->devid == dev_id)
return;
}
list = xmalloc(sizeof(struct devid_list));
list->devid = dev_id;
list->next = NULL;
if (prev == NULL)
entry->devid_list = list;
else
prev->next = list;
}
static int scan(const void *start, const void *end, const void *data)
{
int offset;
const struct imsm_orom *imsm_mem = NULL;
int len = (end - start);
struct pciExpDataStructFormat *ptr= (struct pciExpDataStructFormat *)data;
if (data + 0x18 > end) {
dprintf("cannot find pciExpDataStruct \n");
return 0;
}
dprintf("ptr->vendorID: %lx __le16_to_cpu(ptr->deviceID): %lx \n",
(ulong) __le16_to_cpu(ptr->vendorID),
(ulong) __le16_to_cpu(ptr->deviceID));
if (__le16_to_cpu(ptr->vendorID) != 0x8086)
return 0;
if (get_orom_by_device_id(ptr->deviceID))
return 0;
for (offset = 0; offset < len; offset += 4) {
const void *mem = start + offset;
if ((memcmp(mem, IMSM_OROM_SIGNATURE, 4) == 0)) {
imsm_mem = mem;
break;
}
}
if (!imsm_mem)
return 0;
struct orom_entry *orom = add_orom(imsm_mem);
/* only PciDataStructure with revision 3 and above supports devices list. */
if (ptr->pciDataStructRev >= 3 && ptr->devListOffset) {
const __u16 *dev_list = (void *)ptr + ptr->devListOffset;
int i;
for (i = 0; dev_list[i] != 0; i++)
add_orom_device_id(orom, dev_list[i]);
} else {
add_orom_device_id(orom, __le16_to_cpu(ptr->deviceID));
}
return 0;
}
const struct imsm_orom *imsm_platform_test(struct sys_dev *hba)
{
struct imsm_orom orom = {
.signature = IMSM_OROM_SIGNATURE,
.rlc = IMSM_OROM_RLC_RAID0 | IMSM_OROM_RLC_RAID1 |
IMSM_OROM_RLC_RAID10 | IMSM_OROM_RLC_RAID5,
.sss = IMSM_OROM_SSS_4kB | IMSM_OROM_SSS_8kB |
IMSM_OROM_SSS_16kB | IMSM_OROM_SSS_32kB |
IMSM_OROM_SSS_64kB | IMSM_OROM_SSS_128kB |
IMSM_OROM_SSS_256kB | IMSM_OROM_SSS_512kB |
IMSM_OROM_SSS_1MB | IMSM_OROM_SSS_2MB,
.dpa = IMSM_OROM_DISKS_PER_ARRAY,
.tds = IMSM_OROM_TOTAL_DISKS,
.vpa = IMSM_OROM_VOLUMES_PER_ARRAY,
.vphba = IMSM_OROM_VOLUMES_PER_HBA
};
orom.attr = orom.rlc | IMSM_OROM_ATTR_ChecksumVerify;
if (check_env("IMSM_TEST_OROM_NORAID5")) {
orom.rlc = IMSM_OROM_RLC_RAID0 | IMSM_OROM_RLC_RAID1 |
IMSM_OROM_RLC_RAID10;
}
if (check_env("IMSM_TEST_AHCI_EFI_NORAID5") && (hba->type == SYS_DEV_SAS)) {
orom.rlc = IMSM_OROM_RLC_RAID0 | IMSM_OROM_RLC_RAID1 |
IMSM_OROM_RLC_RAID10;
}
if (check_env("IMSM_TEST_SCU_EFI_NORAID5") && (hba->type == SYS_DEV_SATA)) {
orom.rlc = IMSM_OROM_RLC_RAID0 | IMSM_OROM_RLC_RAID1 |
IMSM_OROM_RLC_RAID10;
}
struct orom_entry *ret = add_orom(&orom);
add_orom_device_id(ret, hba->dev_id);
return &ret->orom;
}
static const struct imsm_orom *find_imsm_hba_orom(struct sys_dev *hba)
{
unsigned long align;
if (check_env("IMSM_TEST_OROM"))
return imsm_platform_test(hba);
/* return empty OROM capabilities in EFI test mode */
if (check_env("IMSM_TEST_AHCI_EFI") || check_env("IMSM_TEST_SCU_EFI"))
return NULL;
find_intel_devices();
if (intel_devices == NULL)
return NULL;
/* scan option-rom memory looking for an imsm signature */
if (check_env("IMSM_SAFE_OROM_SCAN"))
align = 2048;
else
align = 512;
if (probe_roms_init(align) != 0)
return NULL;
probe_roms();
/* ignore return value - True is returned if both adapater roms are found */
scan_adapter_roms(scan);
probe_roms_exit();
return get_orom_by_device_id(hba->dev_id);
}
#define EFI_GUID(a, b, c, d0, d1, d2, d3, d4, d5, d6, d7) \
((struct efi_guid) \
{{ (a) & 0xff, ((a) >> 8) & 0xff, ((a) >> 16) & 0xff, ((a) >> 24) & 0xff, \
(b) & 0xff, ((b) >> 8) & 0xff, \
(c) & 0xff, ((c) >> 8) & 0xff, \
(d0), (d1), (d2), (d3), (d4), (d5), (d6), (d7) }})
#define SYS_EFI_VAR_PATH "/sys/firmware/efi/vars"
#define SYS_EFIVARS_PATH "/sys/firmware/efi/efivars"
#define ACPI_TABLES_PATH "/sys/firmware/acpi/tables/"
#define ACPI_UEFI_TABLE_BASE_NAME "UEFI"
#define ACPI_UEFI_DATA_OFFSET 52
#define SCU_PROP "RstScuV"
#define AHCI_PROP "RstSataV"
#define AHCI_SSATA_PROP "RstsSatV"
#define AHCI_TSATA_PROP "RsttSatV"
#define VROC_VMD_PROP "RstUefiV"
#define RST_VMD_PROP "RstVmdV"
#define PCI_CLASS_RAID_CNTRL 0x010400
/* GUID length in Bytes */
#define GUID_LENGTH 16
/* GUID entry in 'UEFI' for Sata controller. */
#define RST_SATA_V_GUID \
EFI_GUID(0xe4dd92e0, 0xac7d, 0x11df, 0x94, 0xe2, 0x08, 0x00, 0x20, 0x0c, 0x9a, 0x66)
/* GUID entry in 'UEFI' for sSata controller. */
#define RST_SSATA_V_GUID \
EFI_GUID(0xb002be42, 0x901d, 0x4018, 0xb4, 0x1e, 0xd7, 0x04, 0xab, 0x3a, 0x0f, 0x15)
/* GUID entry in 'UEFI' for tSata controller. */
#define RST_TSATA_V_GUID \
EFI_GUID(0x101ce8f1, 0xb873, 0x4362, 0xa9, 0x76, 0xb5, 0x54, 0x31, 0x74, 0x52, 0x7e)
/* GUID entry in 'UEFI' for Intel(R) VROC VMD. */
#define RST_UEFI_V_GUID \
EFI_GUID(0x4bf2da96, 0xde6e, 0x4d8a, 0xa8, 0x8b, 0xb3, 0xd, 0x33, 0xf6, 0xf, 0x3e)
/**
* GUID entry in 'UEFI' for Intel(R) RST VMD.
* Currently is the same like in 'UEFI' for Sata controller.
*/
#define RST_VMD_V_GUID RST_SATA_V_GUID
/* GUID of intel RST vendor EFI var. */
#define INTEL_RST_VENDOR_GUID \
EFI_GUID(0x193dfefa, 0xa445, 0x4302, 0x99, 0xd8, 0xef, 0x3a, 0xad, 0x1a, 0x04, 0xc6)
/*
* Unified Extensible Firmware Interface (UEFI) Specification Release 2.10
* UEFI ACPI DATA TABLE, Table O.1
*/
typedef struct uefi_acpi_table {
char signature[4];
__u32 length;
__u8 revision;
__u8 checksum;
char oemid[6];
/* controller name */
char oem_table_id[8];
__u32 oem_revision;
__u32 creator_id;
__u32 creator_revision;
/* controller GUID */
struct efi_guid identifier;
/* OROM data offeset */
__u16 dataOffset;
} uefi_acpi_table_t;
typedef struct uefi_acpi_table_with_orom {
struct uefi_acpi_table table;
struct imsm_orom orom;
} uefi_acpi_table_with_orom_t;
/* imsm_orom_id - Identifier used to match imsm efi var or acpi table
* @name: name of the UEFI property, it is part of efivar name or ACPI table oem_table_id
* @guid: acpi table guid identifier
*
* vendor guid (second part of evifar name) is not added here because it is cost.
*/
typedef struct imsm_orom_id {
char *name;
struct efi_guid guid;
} imsm_orom_id_t;
static int read_efi_var(void *buffer, ssize_t buf_size,
const char *variable_name, struct efi_guid guid)
{
char path[PATH_MAX];
char buf[GUID_STR_MAX];
int fd;
ssize_t n;
snprintf(path, PATH_MAX, "%s/%s-%s", SYS_EFIVARS_PATH, variable_name, guid_str(buf, guid));
fd = open(path, O_RDONLY);
if (fd < 0)
return 1;
/* read the variable attributes and ignore it */
n = read(fd, buf, sizeof(__u32));
if (n < 0) {
close(fd);
return 1;
}
/* read the variable data */
n = read(fd, buffer, buf_size);
close(fd);
if (n < buf_size)
return 1;
return 0;
}
static int read_efi_variable(void *buffer, ssize_t buf_size,
const char *variable_name, struct efi_guid guid)
{
char path[PATH_MAX];
char buf[GUID_STR_MAX];
int dfd;
ssize_t n, var_data_len;
/* Try to read the variable using the new efivarfs interface first.
* If that fails, fall back to the old sysfs-efivars interface. */
if (!read_efi_var(buffer, buf_size, variable_name, guid))
return 0;
snprintf(path, PATH_MAX, "%s/%s-%s/size", SYS_EFI_VAR_PATH, variable_name, guid_str(buf, guid));
dprintf("EFI VAR: path=%s\n", path);
/* get size of variable data */
dfd = open(path, O_RDONLY);
if (dfd < 0)
return 1;
n = read(dfd, &buf, sizeof(buf));
close(dfd);
if (n < 0)
return 1;
buf[n] = '\0';
errno = 0;
var_data_len = strtoul(buf, NULL, 16);
if ((errno == ERANGE && (var_data_len == LONG_MAX)) ||
(errno != 0 && var_data_len == 0))
return 1;
/* get data */
snprintf(path, PATH_MAX, "%s/%s-%s/data", SYS_EFI_VAR_PATH, variable_name, guid_str(buf, guid));
dprintf("EFI VAR: path=%s\n", path);
dfd = open(path, O_RDONLY);
if (dfd < 0)
return 1;
n = read(dfd, buffer, buf_size);
close(dfd);
if (n != var_data_len || n < buf_size) {
return 1;
}
return 0;
}
/**
* is_efi_guid_equal() - check if EFI guids are equal.
* @guid: EFI guid.
* @guid1: EFI guid to compare.
*
* Return: %true if guid are equal, %false otherwise.
*/
static inline bool is_efi_guid_equal(struct efi_guid guid, struct efi_guid guid1)
{
if (memcmp(guid.b, guid1.b, GUID_LENGTH) == 0)
return true;
return false;
}
/**
* acpi_any_imsm_orom_id_matching() - match ACPI table with any of given imsm_orom_id.
* @imsm_orom_ids: array of IMSM OROM Identifiers.
* @imsm_orom_ids_number: number of IMSM OROM Identifiers.
* @table: struct with read ACPI UEFI table.
*
* Check if read UEFI table contains requested OROM id.
* EFI GUID and controller name are compared with expected.
*
* Return: %true if length is proper table, %false otherwise.
*/
bool acpi_any_imsm_orom_id_matching(imsm_orom_id_t *imsm_orom_ids, int imsm_orom_ids_number,
struct uefi_acpi_table table)
{
int index;
for (index = 0; index < imsm_orom_ids_number; index++)
if (strncmp(table.oem_table_id, imsm_orom_ids[index].name,
strlen(imsm_orom_ids[index].name)) == 0 &&
is_efi_guid_equal(table.identifier,
imsm_orom_ids[index].guid) == true)
return true;
return false;
}
/**
* read_uefi_acpi_orom_data() - read OROM data from UEFI ACPI table.
* @fd: file descriptor.
* @uefi_table: struct to fill out.
*
* Read OROM from ACPI UEFI table under given file descriptor.
* Table must have the appropriate OROM data, which should be confirmed before call this function.
* In case of success, &orom in structure in &uefi_table will be filled..
*
* Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise.
*/
mdadm_status_t
read_uefi_acpi_orom_data(int fd, uefi_acpi_table_with_orom_t *uefi_table)
{
assert(is_fd_valid(fd));
if (lseek(fd, uefi_table->table.dataOffset, 0) == -1L)
return MDADM_STATUS_ERROR;
if (read(fd, &uefi_table->orom, sizeof(uefi_table->orom)) == -1)
return MDADM_STATUS_ERROR;
return MDADM_STATUS_SUCCESS;
}
/**
* verify_uefi_acpi_table_length() - verify if ACPI UEFI table have correct length with focus at
* OROM.
* @table: struct with UEFI table.
*
* Verify if ACPI UEFI table have correct length with focus at OROM. Make sure that the file is
* correct and contains the appropriate length data based on the length of the OROM.
*
* Return: %true if length is correct, %false otherwise.
*/
bool verify_uefi_acpi_table_length(struct uefi_acpi_table table)
{
if (table.length < ACPI_UEFI_DATA_OFFSET)
return false;
if (table.length - table.dataOffset != sizeof(struct imsm_orom))
return false;
return true;
}
/**
* find_orom_in_acpi_uefi_tables() - find OROM in UEFI ACPI tables based on requested OROM ids.
* @imsm_orom_ids: array of IMSM OROM Identifiers.
* @imsm_orom_ids_number: number of IMSM OROM Identifiers.
* @orom: OROM struct buffer to fill out.
*
* Find OROM in UEFI ACPI tables provided by Intel, based on requested controllers.
* The first one to be matched, will be used.
* If found, the buffer with the OROM structure will be filled.
*
* Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise.
*/
mdadm_status_t
find_orom_in_acpi_uefi_tables(imsm_orom_id_t *imsm_orom_ids, int imsm_orom_ids_number,
struct imsm_orom *orom)
{
mdadm_status_t status = MDADM_STATUS_ERROR;
uefi_acpi_table_with_orom_t uefi_table;
char path[PATH_MAX];
struct dirent *ent;
int fd = -1;
DIR *dir;
dir = opendir(ACPI_TABLES_PATH);
if (!dir)
return MDADM_STATUS_ERROR;
for (ent = readdir(dir); ent; ent = readdir(dir)) {
close_fd(&fd);
/* Check if file is a UEFI table */
if (strncmp(ent->d_name, ACPI_UEFI_TABLE_BASE_NAME,
strlen(ACPI_UEFI_TABLE_BASE_NAME)) != 0)
continue;
snprintf(path, PATH_MAX, "%s/%s", ACPI_TABLES_PATH, ent->d_name);
fd = open(path, O_RDONLY);
if (!is_fd_valid(fd)) {
pr_err("Fail to open ACPI UEFI table file. File: %s, Error: %s\n",
ent->d_name, strerror(errno));
continue;
}
if (read(fd, &uefi_table.table, sizeof(struct uefi_acpi_table)) == -1) {
pr_err("Fail to read IMSM OROM from ACPI UEFI table file. File: %s\n",
ent->d_name);
continue;
}
if (!acpi_any_imsm_orom_id_matching(imsm_orom_ids, imsm_orom_ids_number,
uefi_table.table))
continue;
if (!verify_uefi_acpi_table_length(uefi_table.table))
continue;
if (read_uefi_acpi_orom_data(fd, &uefi_table)) {
pr_err("Fail to read IMSM OROM from ACPI UEFI table file. File: %s\n",
ent->d_name);
continue;
}
memcpy(orom, &uefi_table.orom, sizeof(uefi_table.orom));
status = MDADM_STATUS_SUCCESS;
break;
}
close_fd(&fd);
closedir(dir);
return status;
}
/**
* find_orom_in_efi_variables() - find first IMSM OROM in EFI vars that matches any imsm_orom_id.
* @imsm_orom_ids: array of IMSM OROM Identifiers.
* @imsm_orom_ids_number: number of IMSM OROM Identifiers.
* @orom: OROM struct buffer to fill out.
*
* Find IMSM OROM that matches on of imsm_orom_id in EFI variables. The first match is used.
* If found, the buffer with the OROM structure is filled.
*
* Return: %MDADM_STATUS_SUCCESS on success, %MDADM_STATUS_ERROR otherwise.
*/
mdadm_status_t
find_orom_in_efi_variables(imsm_orom_id_t *imsm_orom_ids, int imsm_orom_ids_number,
struct imsm_orom *orom)
{
int index;
for (index = 0; index < imsm_orom_ids_number; index++)
if (!read_efi_variable(orom, sizeof(struct imsm_orom), imsm_orom_ids[index].name,
INTEL_RST_VENDOR_GUID))
return MDADM_STATUS_SUCCESS;
return MDADM_STATUS_ERROR;
}
/**
* find_imsm_efi_orom() - find OROM for requested controller.
* @orom: buffer for OROM.
* @controller_type: requested controller type.
*
* Based on controller type, function first search in EFI vars then in ACPI UEFI tables.
* For each controller there is defined an array of OROM ids from which we can read OROM,
* the first one to be matched, will be used.
* In case of success, the structure &orom will be filed out.
*
* Return: %MDADM_STATUS_SUCCESS on success.
*/
static mdadm_status_t
find_imsm_efi_orom(struct imsm_orom *orom, enum sys_dev_type controller_type)
{
static imsm_orom_id_t sata_imsm_orrom_ids[] = {
{AHCI_PROP, RST_SATA_V_GUID},
{AHCI_SSATA_PROP, RST_SSATA_V_GUID},
{AHCI_TSATA_PROP, RST_TSATA_V_GUID},
};
static imsm_orom_id_t vmd_imsm_orom_ids[] = {
{VROC_VMD_PROP, RST_UEFI_V_GUID},
{RST_VMD_PROP, RST_VMD_V_GUID},
};
static imsm_orom_id_t *imsm_orom_ids;
int imsm_orom_ids_number;
switch (controller_type) {
case SYS_DEV_SATA:
imsm_orom_ids = sata_imsm_orrom_ids;
imsm_orom_ids_number = ARRAY_SIZE(sata_imsm_orrom_ids);
break;
case SYS_DEV_VMD:
case SYS_DEV_SATA_VMD:
imsm_orom_ids = vmd_imsm_orom_ids;
imsm_orom_ids_number = ARRAY_SIZE(vmd_imsm_orom_ids);
break;
default:
return MDADM_STATUS_UNDEF;
}
if (!find_orom_in_efi_variables(imsm_orom_ids, imsm_orom_ids_number, orom))
return MDADM_STATUS_SUCCESS;
return find_orom_in_acpi_uefi_tables(imsm_orom_ids, imsm_orom_ids_number, orom);
}
const struct imsm_orom *find_imsm_efi(struct sys_dev *hba)
{
struct imsm_orom orom;
struct orom_entry *ret;
if (check_env("IMSM_TEST_AHCI_EFI") || check_env("IMSM_TEST_SCU_EFI"))
return imsm_platform_test(hba);
/* OROM test is set, return that there is no EFI capabilities */
if (check_env("IMSM_TEST_OROM"))
return NULL;
switch (hba->type) {
case SYS_DEV_SAS:
if (!read_efi_variable(&orom, sizeof(orom), SCU_PROP, INTEL_RST_VENDOR_GUID))
break;
return NULL;
case SYS_DEV_SATA:
if (hba->class != PCI_CLASS_RAID_CNTRL)
return NULL;
if (find_imsm_efi_orom(&orom, hba->type))
return NULL;
break;
case SYS_DEV_VMD:
case SYS_DEV_SATA_VMD:
if (find_imsm_efi_orom(&orom, hba->type))
return NULL;
break;
default:
return NULL;
}
ret = add_orom(&orom);
add_orom_device_id(ret, hba->dev_id);
ret->type = hba->type;
return &ret->orom;
}
const struct imsm_orom *find_imsm_nvme(struct sys_dev *hba)
{
static struct orom_entry *nvme_orom;
if (hba->type != SYS_DEV_NVME)
return NULL;
if (!nvme_orom) {
struct imsm_orom nvme_orom_compat = {
.signature = IMSM_NVME_OROM_COMPAT_SIGNATURE,
.rlc = IMSM_OROM_RLC_RAID0 | IMSM_OROM_RLC_RAID1 |
IMSM_OROM_RLC_RAID10 | IMSM_OROM_RLC_RAID5,
.sss = IMSM_OROM_SSS_4kB | IMSM_OROM_SSS_8kB |
IMSM_OROM_SSS_16kB | IMSM_OROM_SSS_32kB |
IMSM_OROM_SSS_64kB | IMSM_OROM_SSS_128kB,
.dpa = IMSM_OROM_DISKS_PER_ARRAY_NVME,
.tds = IMSM_OROM_TOTAL_DISKS_NVME,
.vpa = IMSM_OROM_VOLUMES_PER_ARRAY,
.vphba = IMSM_OROM_TOTAL_DISKS_NVME / 2 * IMSM_OROM_VOLUMES_PER_ARRAY,
.attr = IMSM_OROM_ATTR_2TB | IMSM_OROM_ATTR_2TB_DISK,
.driver_features = IMSM_OROM_CAPABILITIES_EnterpriseSystem |
IMSM_OROM_CAPABILITIES_TPV
};
nvme_orom = add_orom(&nvme_orom_compat);
}
add_orom_device_id(nvme_orom, hba->dev_id);
nvme_orom->type = SYS_DEV_NVME;
return &nvme_orom->orom;
}
#define VMD_REGISTER_OFFSET 0x3FC
#define VMD_REGISTER_SKU_SHIFT 1
#define VMD_REGISTER_SKU_MASK (0x00000007)
#define VMD_REGISTER_SKU_PREMIUM 2
#define MD_REGISTER_VER_MAJOR_SHIFT 4
#define MD_REGISTER_VER_MAJOR_MASK (0x0000000F)
#define MD_REGISTER_VER_MINOR_SHIFT 8
#define MD_REGISTER_VER_MINOR_MASK (0x0000000F)
/*
* read_vmd_register() - Reads VMD register and writes contents to buff ptr
* @buff: buffer for vmd register data, should be the size of uint32_t
*
* Return: 0 on success, 1 on error
*/
int read_vmd_register(uint32_t *buff, struct sys_dev *hba)
{
int fd;
char vmd_pci_config_path[PATH_MAX];
if (!vmd_domain_to_controller(hba, vmd_pci_config_path))
return 1;
strncat(vmd_pci_config_path, "/config", PATH_MAX - strnlen(vmd_pci_config_path, PATH_MAX));
fd = open(vmd_pci_config_path, O_RDONLY);
if (fd < 0)
return 1;
if (pread(fd, buff, sizeof(uint32_t), VMD_REGISTER_OFFSET) != sizeof(uint32_t)) {
close(fd);
return 1;
}
close(fd);
return 0;
}
/*
* add_vmd_orom() - Adds VMD orom cap to orom list, writes orom_entry ptr into vmd_orom
* @vmd_orom: pointer to orom entry pointer
*
* Return: 0 on success, 1 on error
*/
int add_vmd_orom(struct orom_entry **vmd_orom, struct sys_dev *hba)
{
uint8_t sku;
uint32_t vmd_register_data;
struct imsm_orom vmd_orom_cap = {
.signature = IMSM_VMD_OROM_COMPAT_SIGNATURE,
.sss = IMSM_OROM_SSS_4kB | IMSM_OROM_SSS_8kB |
IMSM_OROM_SSS_16kB | IMSM_OROM_SSS_32kB |
IMSM_OROM_SSS_64kB | IMSM_OROM_SSS_128kB,
.dpa = IMSM_OROM_DISKS_PER_ARRAY_NVME,
.tds = IMSM_OROM_TOTAL_DISKS_VMD,
.vpa = IMSM_OROM_VOLUMES_PER_ARRAY,
.vphba = IMSM_OROM_VOLUMES_PER_HBA_VMD,
.attr = IMSM_OROM_ATTR_2TB | IMSM_OROM_ATTR_2TB_DISK,
.driver_features = IMSM_OROM_CAPABILITIES_EnterpriseSystem |
IMSM_OROM_CAPABILITIES_TPV
};
if (read_vmd_register(&vmd_register_data, hba) != 0)
return 1;
sku = (uint8_t)((vmd_register_data >> VMD_REGISTER_SKU_SHIFT) &
VMD_REGISTER_SKU_MASK);
if (sku == VMD_REGISTER_SKU_PREMIUM)
vmd_orom_cap.rlc = IMSM_OROM_RLC_RAID0 | IMSM_OROM_RLC_RAID1 |
IMSM_OROM_RLC_RAID10 | IMSM_OROM_RLC_RAID5;
else
vmd_orom_cap.rlc = IMSM_OROM_RLC_RAID_CNG;
vmd_orom_cap.major_ver = (uint8_t)
((vmd_register_data >> MD_REGISTER_VER_MAJOR_SHIFT) &
MD_REGISTER_VER_MAJOR_MASK);
vmd_orom_cap.minor_ver = (uint8_t)
((vmd_register_data >> MD_REGISTER_VER_MINOR_SHIFT) &
MD_REGISTER_VER_MINOR_MASK);
*vmd_orom = add_orom(&vmd_orom_cap);
return 0;
}
const struct imsm_orom *find_imsm_vmd(struct sys_dev *hba)
{
static struct orom_entry *vmd_orom;
if (hba->type != SYS_DEV_VMD)
return NULL;
if (!vmd_orom && add_vmd_orom(&vmd_orom, hba) != 0)
return NULL;
add_orom_device_id(vmd_orom, hba->dev_id);
vmd_orom->type = SYS_DEV_VMD;
return &vmd_orom->orom;
}
const struct imsm_orom *find_imsm_capability(struct sys_dev *hba)
{
const struct imsm_orom *cap = get_orom_by_device_id(hba->dev_id);
if (cap)
return cap;
if (hba->type == SYS_DEV_NVME)
return find_imsm_nvme(hba);
cap = find_imsm_efi(hba);
if (cap)
return cap;
if (hba->type == SYS_DEV_VMD) {
cap = find_imsm_vmd(hba);
if (cap)
return cap;
}
cap = find_imsm_hba_orom(hba);
if (cap)
return cap;
return NULL;
}
/* Check whether the nvme device is represented by nvme subsytem,
* if yes virtual path should be changed to hardware device path,
* to allow IMSM capabilities detection.
* Returns:
* hardware path to device - if the device is represented via
* nvme virtual subsytem
* NULL - if the device is not represented via nvme virtual subsytem
*/
char *get_nvme_multipath_dev_hw_path(const char *dev_path)
{
DIR *dir;
struct dirent *ent;
char *rp = NULL;
if (strncmp(dev_path, NVME_SUBSYS_PATH, strlen(NVME_SUBSYS_PATH)) != 0)
return NULL;
dir = opendir(dev_path);
if (!dir)
return NULL;
for (ent = readdir(dir); ent; ent = readdir(dir)) {
char buf[PATH_MAX];
/* Check if dir is a controller, ignore namespaces*/
if (!(strncmp(ent->d_name, "nvme", 4) == 0) ||
(strrchr(ent->d_name, 'n') != &ent->d_name[0]))
continue;
snprintf(buf, PATH_MAX, "%s/%s", dev_path, ent->d_name);
rp = realpath(buf, NULL);
break;
}
closedir(dir);
return rp;
}
/* Description: Return part or whole realpath for the dev
* Parameters:
* dev - the device to be quered
* dev_level - level of "/device" entries. It allows to caller to access
* virtual or physical devices which are on "path" to quered
* one.
* buf - optional, must be PATH_MAX size. If set, then will be used.
*/
char *devt_to_devpath(dev_t dev, int dev_level, char *buf)
{
char device[PATH_MAX];
char *hw_path;
int i;
unsigned long device_free_len = sizeof(device) - 1;
char dev_str[] = "/device";
unsigned long dev_str_len = strlen(dev_str);
snprintf(device, sizeof(device), "/sys/dev/block/%d:%d", major(dev),
minor(dev));
/* If caller wants block device, return path to it even if it is exposed
* via virtual layer.
*/
if (dev_level == 0)
return realpath(device, buf);
device_free_len -= strlen(device);
for (i = 0; i < dev_level; i++) {
if (device_free_len < dev_str_len)
return NULL;
strncat(device, dev_str, device_free_len);
/* Resolve nvme-subsystem abstraction if needed
*/
device_free_len -= dev_str_len;
if (i == 0) {
char rp[PATH_MAX];
if (!realpath(device, rp))
return NULL;
hw_path = get_nvme_multipath_dev_hw_path(rp);
if (hw_path) {
strcpy(device, hw_path);
device_free_len = sizeof(device) -
strlen(device) - 1;
free(hw_path);
}
}
}
return realpath(device, buf);
}
char *diskfd_to_devpath(int fd, int dev_level, char *buf)
{
/* return the device path for a disk, return NULL on error or fd
* refers to a partition
*/
struct stat st;
if (fstat(fd, &st) != 0)
return NULL;
if (!S_ISBLK(st.st_mode))
return NULL;
return devt_to_devpath(st.st_rdev, dev_level, buf);
}
/**
* is_path_attached_to_hba() - Check if disk is attached to hba
*
* @disk_path: Path to disk.
* @hba_path: Path to hba.
*
* Returns: true if disk is attached to hba, false otherwise.
*/
bool is_path_attached_to_hba(const char *disk_path, const char *hba_path)
{
if (!disk_path || !hba_path)
return false;
if (strncmp(disk_path, hba_path, strlen(hba_path)) == 0)
return true;
return false;
}
int devt_attached_to_hba(dev_t dev, const char *hba_path)
{
char *disk_path = devt_to_devpath(dev, 1, NULL);
int rc = is_path_attached_to_hba(disk_path, hba_path);
if (disk_path)
free(disk_path);
return rc;
}
int disk_attached_to_hba(int fd, const char *hba_path)
{
char *disk_path = diskfd_to_devpath(fd, 1, NULL);
int rc = is_path_attached_to_hba(disk_path, hba_path);
if (disk_path)
free(disk_path);
return rc;
}
char *vmd_domain_to_controller(struct sys_dev *hba, char *buf)
{
struct dirent *ent;
DIR *dir;
char path[PATH_MAX];
if (!hba)
return NULL;
if (hba->type != SYS_DEV_VMD)
return NULL;
dir = opendir("/sys/bus/pci/drivers/vmd");
if (!dir)
return NULL;
for (ent = readdir(dir); ent; ent = readdir(dir)) {
sprintf(path, "/sys/bus/pci/drivers/vmd/%s/domain/device",
ent->d_name);
if (!realpath(path, buf))
continue;
if (strncmp(buf, hba->path, strlen(buf)) == 0) {
sprintf(path, "/sys/bus/pci/drivers/vmd/%s", ent->d_name);
closedir(dir);
return realpath(path, buf);
}
}
closedir(dir);
return NULL;
}
/* Scan over all controller's namespaces and compare nsid value to verify if
* current one is supported. The routine doesn't check IMSM capabilities for
* namespace. Only one nvme namespace is supported by IMSM.
* Paramteres:
* fd - open descriptor to the nvme namespace
* verbose - error logging level
* Returns:
* 1 - if namespace is supported
* 0 - otherwise
*/
int imsm_is_nvme_namespace_supported(int fd, int verbose)
{
DIR *dir = NULL;
struct dirent *ent;
char cntrl_path[PATH_MAX];
char ns_path[PATH_MAX];
unsigned long long lowest_nsid = ULLONG_MAX;
unsigned long long this_nsid;
int rv = 0;
if (!diskfd_to_devpath(fd, 1, cntrl_path) ||
!diskfd_to_devpath(fd, 0, ns_path)) {
if (verbose)
pr_err("Cannot get device paths\n");
goto abort;
}
if (devpath_to_ll(ns_path, "nsid", &this_nsid)) {
if (verbose)
pr_err("Cannot read nsid value for %s",
basename(ns_path));
goto abort;
}
dir = opendir(cntrl_path);
if (!dir)
goto abort;
/* The lowest nvme namespace is supported */
for (ent = readdir(dir); ent; ent = readdir(dir)) {
unsigned long long curr_nsid;
char curr_ns_path[PATH_MAX + 256];
if (!strstr(ent->d_name, "nvme"))
continue;
snprintf(curr_ns_path, sizeof(curr_ns_path), "%s/%s",
cntrl_path, ent->d_name);
if (devpath_to_ll(curr_ns_path, "nsid", &curr_nsid))
goto abort;
if (lowest_nsid > curr_nsid)
lowest_nsid = curr_nsid;
}
if (this_nsid == lowest_nsid)
rv = 1;
else if (verbose)
pr_err("IMSM is supported on the lowest NVMe namespace\n");
abort:
if (dir)
closedir(dir);
return rv;
}
/* Verify if multipath is supported by NVMe controller
* Returns:
* 0 - not supported
* 1 - supported
*/
int is_multipath_nvme(int disk_fd)
{
char ns_path[PATH_MAX];
if (!diskfd_to_devpath(disk_fd, 0, ns_path))
return 0;
if (strncmp(ns_path, NVME_SUBSYS_PATH, strlen(NVME_SUBSYS_PATH)) == 0)
return 1;
return 0;
}
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