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|
// SPDX-License-Identifier: LGPL-2.1-or-later
/*
* This file is part of libnvme.
* Copyright (c) 2021 Code Construct Pty Ltd
*
* Authors: Jeremy Kerr <jk@codeconstruct.com.au>
*/
#include <errno.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <poll.h>
#include <sys/socket.h>
#include <sys/types.h>
#include <sys/uio.h>
#if HAVE_LINUX_MCTP_H
#include <linux/mctp.h>
#endif
#include <ccan/endian/endian.h>
#ifdef CONFIG_DBUS
#include <dbus/dbus.h>
#define MCTP_DBUS_PATH "/xyz/openbmc_project/mctp"
#define MCTP_DBUS_IFACE "xyz.openbmc_project.MCTP"
#define MCTP_DBUS_IFACE_ENDPOINT "xyz.openbmc_project.MCTP.Endpoint"
#endif
#include "private.h"
#include "log.h"
#include "mi.h"
#if !defined(AF_MCTP)
#define AF_MCTP 45
#endif
#if !HAVE_LINUX_MCTP_H
/* As of kernel v5.15, these AF_MCTP-related definitions are provided by
* linux/mctp.h. However, we provide a set here while that header percolates
* through to standard includes.
*
* These were all introduced in the same version as AF_MCTP was defined,
* so we can key off the presence of that.
*/
typedef __u8 mctp_eid_t;
struct mctp_addr {
mctp_eid_t s_addr;
};
struct sockaddr_mctp {
unsigned short int smctp_family;
__u16 __smctp_pad0;
unsigned int smctp_network;
struct mctp_addr smctp_addr;
__u8 smctp_type;
__u8 smctp_tag;
__u8 __smctp_pad1;
};
#define MCTP_NET_ANY 0x0
#define MCTP_ADDR_NULL 0x00
#define MCTP_ADDR_ANY 0xff
#define MCTP_TAG_MASK 0x07
#define MCTP_TAG_OWNER 0x08
#endif /* !AF_MCTP */
#define MCTP_TYPE_NVME 0x04
#define MCTP_TYPE_MIC 0x80
struct nvme_mi_transport_mctp {
int net;
__u8 eid;
int sd;
void *resp_buf;
size_t resp_buf_size;
};
static int ioctl_tag(int sd, unsigned long req, struct mctp_ioc_tag_ctl *ctl)
{
return ioctl(sd, req, ctl);
}
static struct __mi_mctp_socket_ops ops = {
socket,
sendmsg,
recvmsg,
poll,
ioctl_tag,
};
void __nvme_mi_mctp_set_ops(const struct __mi_mctp_socket_ops *newops)
{
ops = *newops;
}
static const struct nvme_mi_transport nvme_mi_transport_mctp;
#ifdef SIOCMCTPALLOCTAG
static __u8 nvme_mi_mctp_tag_alloc(struct nvme_mi_ep *ep)
{
struct nvme_mi_transport_mctp *mctp;
struct mctp_ioc_tag_ctl ctl = { 0 };
static bool logged;
int rc;
mctp = ep->transport_data;
ctl.peer_addr = mctp->eid;
errno = 0;
rc = ops.ioctl_tag(mctp->sd, SIOCMCTPALLOCTAG, &ctl);
if (rc) {
if (!logged) {
/* not necessarily fatal, just means we can't handle
* "more processing required" messages */
nvme_msg(ep->root, LOG_INFO,
"System does not support explicit tag allocation\n");
logged = true;
}
return MCTP_TAG_OWNER;
}
return ctl.tag;
}
static void nvme_mi_mctp_tag_drop(struct nvme_mi_ep *ep, __u8 tag)
{
struct nvme_mi_transport_mctp *mctp;
struct mctp_ioc_tag_ctl ctl = { 0 };
mctp = ep->transport_data;
if (!(tag & MCTP_TAG_PREALLOC))
return;
ctl.peer_addr = mctp->eid;
ctl.tag = tag;
ops.ioctl_tag(mctp->sd, SIOCMCTPDROPTAG, &ctl);
}
#else /* !defined SIOMCTPTAGALLOC */
static __u8 nvme_mi_mctp_tag_alloc(struct nvme_mi_ep *ep)
{
static bool logged;
if (!logged) {
nvme_msg(ep->root, LOG_INFO,
"Build does not support explicit tag allocation\n");
logged = true;
}
return MCTP_TAG_OWNER;
}
static void nvme_mi_mctp_tag_drop(struct nvme_mi_ep *ep, __u8 tag)
{
}
#endif /* !defined SIOMCTPTAGALLOC */
struct nvme_mi_msg_resp_mpr {
struct nvme_mi_msg_hdr hdr;
__u8 status;
__u8 rsvd0;
__u16 mprt;
};
/* Check if this response was a More Processing Required response; if so,
* populate the worst-case expected processing time, given in milliseconds.
*
* buf is the incoming message data, including type byte, but excluding
* the MIC which has been extracted into the mic argument already.
*/
static bool nvme_mi_mctp_resp_is_mpr(void *buf, size_t len,
__le32 mic, unsigned int *mpr_time)
{
struct nvme_mi_msg_resp_mpr *msg;
__u32 crc;
/* We need at least the minimal header */
if (len < sizeof(*msg))
return false;
msg = (struct nvme_mi_msg_resp_mpr *)buf;
if (msg->status != NVME_MI_RESP_MPR)
return false;
/* Devices may send a MPR response as a full-sized Admin response,
* rather than the minimal MI-only header. Allow this, but only if the
* type indicates admin, and the allocated response header is the
* correct size for an Admin response.
*/
if (!(len == sizeof(*msg) ||
((msg->hdr.nmp >> 3 & 0x0f) == NVME_MI_MT_ADMIN &&
len == sizeof(struct nvme_mi_admin_resp_hdr))))
return false;
/* Verify the MIC from the response. We're dealing with linear
* header data here, and need to preserve the resp pointer & size
* values, so can't use verify_resp_mic here.
*/
crc = ~nvme_mi_crc32_update(0xffffffff, buf, len);
if (le32_to_cpu(mic) != crc)
return false;
if (mpr_time)
*mpr_time = cpu_to_le16(msg->mprt) * 100;
return true;
}
static int nvme_mi_mctp_submit(struct nvme_mi_ep *ep,
struct nvme_mi_req *req,
struct nvme_mi_resp *resp)
{
ssize_t len, resp_len, resp_hdr_len, resp_data_len;
struct nvme_mi_transport_mctp *mctp;
struct iovec req_iov[3], resp_iov[1];
struct msghdr req_msg, resp_msg;
int i, rc, errno_save, timeout;
struct sockaddr_mctp addr;
struct pollfd pollfds[1];
unsigned int mpr_time;
__le32 mic;
__u8 tag;
if (ep->transport != &nvme_mi_transport_mctp) {
errno = EINVAL;
return -1;
}
/* we need enough space for at least a generic (/error) response */
if (resp->hdr_len < sizeof(struct nvme_mi_msg_resp)) {
errno = EINVAL;
return -1;
}
mctp = ep->transport_data;
tag = nvme_mi_mctp_tag_alloc(ep);
memset(&addr, 0, sizeof(addr));
addr.smctp_family = AF_MCTP;
addr.smctp_network = mctp->net;
addr.smctp_addr.s_addr = mctp->eid;
addr.smctp_type = MCTP_TYPE_NVME | MCTP_TYPE_MIC;
addr.smctp_tag = tag;
i = 0;
req_iov[i].iov_base = ((__u8 *)req->hdr) + 1;
req_iov[i].iov_len = req->hdr_len - 1;
i++;
if (req->data_len) {
req_iov[i].iov_base = req->data;
req_iov[i].iov_len = req->data_len;
i++;
}
mic = cpu_to_le32(req->mic);
req_iov[i].iov_base = &mic;
req_iov[i].iov_len = sizeof(mic);
i++;
memset(&req_msg, 0, sizeof(req_msg));
req_msg.msg_name = &addr;
req_msg.msg_namelen = sizeof(addr);
req_msg.msg_iov = req_iov;
req_msg.msg_iovlen = i;
len = ops.sendmsg(mctp->sd, &req_msg, 0);
if (len < 0) {
errno_save = errno;
nvme_msg(ep->root, LOG_ERR,
"Failure sending MCTP message: %m\n");
errno = errno_save;
rc = -1;
goto out;
}
resp_len = resp->hdr_len + resp->data_len + sizeof(mic);
if (resp_len > mctp->resp_buf_size) {
void *tmp = realloc(mctp->resp_buf, resp_len);
if (!tmp) {
errno_save = errno;
nvme_msg(ep->root, LOG_ERR,
"Failure allocating response buffer: %m\n");
errno = errno_save;
rc = -1;
goto out;
}
mctp->resp_buf = tmp;
mctp->resp_buf_size = resp_len;
}
/* offset by one: the MCTP message type is excluded from the buffer */
resp_iov[0].iov_base = mctp->resp_buf + 1;
resp_iov[0].iov_len = resp_len - 1;
memset(&resp_msg, 0, sizeof(resp_msg));
resp_msg.msg_name = &addr;
resp_msg.msg_namelen = sizeof(addr);
resp_msg.msg_iov = resp_iov;
resp_msg.msg_iovlen = 1;
pollfds[0].fd = mctp->sd;
pollfds[0].events = POLLIN;
timeout = ep->timeout ?: -1;
retry:
rc = ops.poll(pollfds, 1, timeout);
if (rc < 0) {
if (errno == EINTR)
goto retry;
errno_save = errno;
nvme_msg(ep->root, LOG_ERR,
"Failed polling on MCTP socket: %m");
errno = errno_save;
goto out;
}
if (rc == 0) {
nvme_msg(ep->root, LOG_DEBUG, "Timeout on MCTP socket");
errno = ETIMEDOUT;
rc = -1;
goto out;
}
rc = -1;
len = ops.recvmsg(mctp->sd, &resp_msg, MSG_DONTWAIT);
if (len < 0) {
errno_save = errno;
nvme_msg(ep->root, LOG_ERR,
"Failure receiving MCTP message: %m\n");
errno = errno_save;
goto out;
}
if (len == 0) {
nvme_msg(ep->root, LOG_WARNING, "No data from MCTP endpoint\n");
errno = EIO;
goto out;
}
/* Re-add the type byte, so we can work on aligned lengths from here */
((uint8_t *)mctp->resp_buf)[0] = MCTP_TYPE_NVME | MCTP_TYPE_MIC;
len += 1;
/* The smallest response data is 8 bytes: generic 4-byte message header
* plus four bytes of error data (excluding MIC). Ensure we have enough.
*/
if (len < 8 + sizeof(mic)) {
nvme_msg(ep->root, LOG_ERR,
"Invalid MCTP response: too short (%zd bytes, needed %zd)\n",
len, 8 + sizeof(mic));
errno = EPROTO;
goto out;
}
/* Start unpacking the linear resp buffer into the split header + data
* + MIC. We check for a MPR response before fully unpacking, as we'll
* need to preserve the resp layout if we need to retry the receive.
*/
/* MIC is always at the tail */
memcpy(&mic, mctp->resp_buf + len - sizeof(mic), sizeof(mic));
len -= 4;
/* Check for a More Processing Required response. This is a slight
* layering violation, as we're pre-checking the MIC and inspecting
* header fields. However, we need to do this in the transport in order
* to keep the tag allocated and retry the recvmsg
*/
if (nvme_mi_mctp_resp_is_mpr(mctp->resp_buf, len, mic, &mpr_time)) {
nvme_msg(ep->root, LOG_DEBUG,
"Received More Processing Required, waiting for response\n");
/* if the controller hasn't set MPRT, fall back to our command/
* response timeout, or the largest possible MPRT if none set */
if (!mpr_time)
mpr_time = ep->timeout ?: 0xffff;
/* clamp to the endpoint max */
if (ep->mprt_max && mpr_time > ep->mprt_max)
mpr_time = ep->mprt_max;
timeout = mpr_time;
goto retry;
}
/* we expect resp->hdr_len bytes, but we may have less */
resp_hdr_len = resp->hdr_len;
if (resp_hdr_len > len)
resp_hdr_len = len;
memcpy(resp->hdr, mctp->resp_buf, resp_hdr_len);
resp->hdr_len = resp_hdr_len;
len -= resp_hdr_len;
/* any remaining bytes are the data payload */
resp_data_len = resp->data_len;
if (resp_data_len > len)
resp_data_len = len;
memcpy(resp->data, mctp->resp_buf + resp_hdr_len, resp_data_len);
resp->data_len = resp_data_len;
resp->mic = le32_to_cpu(mic);
rc = 0;
out:
nvme_mi_mctp_tag_drop(ep, tag);
return rc;
}
static void nvme_mi_mctp_close(struct nvme_mi_ep *ep)
{
struct nvme_mi_transport_mctp *mctp;
if (ep->transport != &nvme_mi_transport_mctp)
return;
mctp = ep->transport_data;
close(mctp->sd);
free(mctp->resp_buf);
free(ep->transport_data);
}
static int nvme_mi_mctp_desc_ep(struct nvme_mi_ep *ep, char *buf, size_t len)
{
struct nvme_mi_transport_mctp *mctp;
if (ep->transport != &nvme_mi_transport_mctp) {
errno = EINVAL;
return -1;
}
mctp = ep->transport_data;
snprintf(buf, len, "net %d eid %d", mctp->net, mctp->eid);
return 0;
}
static const struct nvme_mi_transport nvme_mi_transport_mctp = {
.name = "mctp",
.mic_enabled = true,
.submit = nvme_mi_mctp_submit,
.close = nvme_mi_mctp_close,
.desc_ep = nvme_mi_mctp_desc_ep,
};
nvme_mi_ep_t nvme_mi_open_mctp(nvme_root_t root, unsigned int netid, __u8 eid)
{
struct nvme_mi_transport_mctp *mctp;
struct nvme_mi_ep *ep;
int errno_save;
ep = nvme_mi_init_ep(root);
if (!ep)
return NULL;
mctp = malloc(sizeof(*mctp));
if (!mctp) {
errno_save = errno;
goto err_close_ep;
}
memset(mctp, 0, sizeof(*mctp));
mctp->sd = -1;
mctp->resp_buf_size = 4096;
mctp->resp_buf = malloc(mctp->resp_buf_size);
if (!mctp->resp_buf) {
errno_save = errno;
goto err_free_mctp;
}
mctp->net = netid;
mctp->eid = eid;
mctp->sd = ops.socket(AF_MCTP, SOCK_DGRAM, 0);
if (mctp->sd < 0) {
errno_save = errno;
goto err_free_rspbuf;
}
ep->transport = &nvme_mi_transport_mctp;
ep->transport_data = mctp;
/* Assuming an i2c transport at 100kHz, smallest MTU (64+4). Given
* a worst-case clock stretch, and largest-sized packets, we can
* expect up to 1.6s per command/response pair. Allowing for a
* retry or two (handled by lower layers), 5s is a reasonable timeout.
*/
ep->timeout = 5000;
nvme_mi_ep_probe(ep);
return ep;
err_free_rspbuf:
free(mctp->resp_buf);
err_free_mctp:
free(mctp);
err_close_ep:
/* the ep->transport is not set yet, so this will not call back
* into nvme_mi_mctp_close() */
nvme_mi_close(ep);
errno = errno_save;
return NULL;
}
#ifdef CONFIG_DBUS
static int nvme_mi_mctp_add(nvme_root_t root, unsigned int netid, __u8 eid)
{
nvme_mi_ep_t ep = NULL;
/* ensure we don't already have an endpoint with the same net/eid. if
* we do, just skip, no need to re-add. */
list_for_each(&root->endpoints, ep, root_entry) {
if (ep->transport != &nvme_mi_transport_mctp) {
continue;
}
const struct nvme_mi_transport_mctp *t = ep->transport_data;
if (t->eid == eid && t->net == netid)
return 0;
}
ep = nvme_mi_open_mctp(root, netid, eid);
if (!ep)
return -1;
return 0;
}
static bool dbus_object_is_type(DBusMessageIter *obj, int type)
{
return dbus_message_iter_get_arg_type(obj) == type;
}
static bool dbus_object_is_dict(DBusMessageIter *obj)
{
return dbus_object_is_type(obj, DBUS_TYPE_ARRAY) &&
dbus_message_iter_get_element_type(obj) == DBUS_TYPE_DICT_ENTRY;
}
static int read_variant_basic(DBusMessageIter *var, int type, void *val)
{
if (!dbus_object_is_type(var, type))
return -1;
dbus_message_iter_get_basic(var, val);
return 0;
}
static bool has_message_type(DBusMessageIter *prop, uint8_t type)
{
DBusMessageIter inner;
uint8_t *types;
int i, n;
if (!dbus_object_is_type(prop, DBUS_TYPE_ARRAY) ||
dbus_message_iter_get_element_type(prop) != DBUS_TYPE_BYTE)
return false;
dbus_message_iter_recurse(prop, &inner);
dbus_message_iter_get_fixed_array(&inner, &types, &n);
for (i = 0; i < n; i++) {
if (types[i] == type)
return true;
}
return false;
}
static int handle_mctp_endpoint(nvme_root_t root, const char* objpath,
DBusMessageIter *props)
{
bool have_eid = false, have_net = false, have_nvmemi = false;
mctp_eid_t eid;
int net;
int rc;
/* for each property */
for (;;) {
DBusMessageIter prop, val;
const char *propname;
dbus_message_iter_recurse(props, &prop);
if (!dbus_object_is_type(&prop, DBUS_TYPE_STRING)) {
nvme_msg(root, LOG_ERR,
"error unmashalling object (propname)\n");
return -1;
}
dbus_message_iter_get_basic(&prop, &propname);
dbus_message_iter_next(&prop);
if (!dbus_object_is_type(&prop, DBUS_TYPE_VARIANT)) {
nvme_msg(root, LOG_ERR,
"error unmashalling object (propval)\n");
return -1;
}
dbus_message_iter_recurse(&prop, &val);
if (!strcmp(propname, "EID")) {
rc = read_variant_basic(&val, DBUS_TYPE_BYTE, &eid);
have_eid = true;
} else if (!strcmp(propname, "NetworkId")) {
rc = read_variant_basic(&val, DBUS_TYPE_INT32, &net);
have_net = true;
} else if (!strcmp(propname, "SupportedMessageTypes")) {
have_nvmemi = has_message_type(&val, MCTP_TYPE_NVME);
}
if (rc)
return rc;
if (!dbus_message_iter_next(props))
break;
}
if (have_nvmemi) {
if (!(have_eid && have_net)) {
nvme_msg(root, LOG_ERR,
"Missing property for %s\n", objpath);
errno = ENOENT;
return -1;
}
rc = nvme_mi_mctp_add(root, net, eid);
if (rc < 0) {
int errno_save = errno;
nvme_msg(root, LOG_ERR,
"Error adding net %d eid %d: %m\n", net, eid);
errno = errno_save;
}
} else {
/* Ignore other endpoints */
rc = 0;
}
return rc;
}
/* obj is an array of (object path, interfaces) dict entries - ie., dbus type
* a{oa{sa{sv}}}
*/
static int handle_mctp_obj(nvme_root_t root, DBusMessageIter *obj)
{
const char *objpath = NULL;
DBusMessageIter intfs;
if (!dbus_object_is_type(obj, DBUS_TYPE_OBJECT_PATH)) {
nvme_msg(root, LOG_ERR, "error unmashalling object (path)\n");
return -1;
}
dbus_message_iter_get_basic(obj, &objpath);
dbus_message_iter_next(obj);
if (!dbus_object_is_dict(obj)) {
nvme_msg(root, LOG_ERR, "error unmashalling object (intfs)\n");
return -1;
}
dbus_message_iter_recurse(obj, &intfs);
/* for each interface */
for (;;) {
DBusMessageIter props, intf;
const char *intfname;
dbus_message_iter_recurse(&intfs, &intf);
if (!dbus_object_is_type(&intf, DBUS_TYPE_STRING)) {
nvme_msg(root, LOG_ERR,
"error unmashalling object (intf)\n");
return -1;
}
dbus_message_iter_get_basic(&intf, &intfname);
if (strcmp(intfname, MCTP_DBUS_IFACE_ENDPOINT)) {
if (!dbus_message_iter_next(&intfs))
break;
continue;
}
dbus_message_iter_next(&intf);
if (!dbus_object_is_dict(&intf)) {
nvme_msg(root, LOG_ERR,
"error unmarshalling object (props)\n");
return -1;
}
dbus_message_iter_recurse(&intf, &props);
return handle_mctp_endpoint(root, objpath, &props);
}
return 0;
}
nvme_root_t nvme_mi_scan_mctp(void)
{
DBusMessage *msg, *resp = NULL;
DBusConnection *bus = NULL;
DBusMessageIter args, objs;
int errno_save, rc = -1;
nvme_root_t root;
dbus_bool_t drc;
DBusError berr;
root = nvme_mi_create_root(NULL, DEFAULT_LOGLEVEL);
if (!root) {
errno = ENOMEM;
return NULL;
}
dbus_error_init(&berr);
bus = dbus_bus_get(DBUS_BUS_SYSTEM, &berr);
if (!bus) {
nvme_msg(root, LOG_ERR, "Failed connecting to D-Bus: %s (%s)\n",
berr.message, berr.name);
goto out;
}
msg = dbus_message_new_method_call(MCTP_DBUS_IFACE,
MCTP_DBUS_PATH,
"org.freedesktop.DBus.ObjectManager",
"GetManagedObjects");
if (!msg) {
nvme_msg(root, LOG_ERR, "Failed creating call message\n");
goto out;
}
resp = dbus_connection_send_with_reply_and_block(bus, msg,
DBUS_TIMEOUT_USE_DEFAULT,
&berr);
dbus_message_unref(msg);
if (!resp) {
nvme_msg(root, LOG_ERR, "Failed querying MCTP D-Bus: %s (%s)\n",
berr.message, berr.name);
goto out;
}
/* argument container */
drc = dbus_message_iter_init(resp, &args);
if (!drc) {
nvme_msg(root, LOG_ERR, "can't read dbus reply args\n");
goto out;
}
if (!dbus_object_is_dict(&args)) {
nvme_msg(root, LOG_ERR, "error unmashalling args\n");
goto out;
}
/* objects container */
dbus_message_iter_recurse(&args, &objs);
rc = 0;
for (;;) {
DBusMessageIter ent;
dbus_message_iter_recurse(&objs, &ent);
rc = handle_mctp_obj(root, &ent);
if (rc)
break;
if (!dbus_message_iter_next(&objs))
break;
}
out:
errno_save = errno;
if (resp)
dbus_message_unref(resp);
if (bus)
dbus_connection_unref(bus);
dbus_error_free(&berr);
if (rc < 0) {
if (root) {
nvme_mi_free_root(root);
}
errno = errno_save;
root = NULL;
}
return root;
}
#else /* CONFIG_DBUS */
nvme_root_t nvme_mi_scan_mctp(void)
{
return NULL;
}
#endif /* CONFIG_DBUS */
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