linux/drivers/thunderbolt/ctl.c
Mika Westerberg 235d019481 thunderbolt: Add the new USB4 v2 notification types
USB4 v2 spec adds a bunch of new notifications that the connection
manager can use instead of polling. While we do not use these yet we
need to ack the ones routers expect to be acked.

Signed-off-by: Mika Westerberg <mika.westerberg@linux.intel.com>
2023-06-16 09:53:28 +03:00

1145 lines
29 KiB
C

// SPDX-License-Identifier: GPL-2.0
/*
* Thunderbolt driver - control channel and configuration commands
*
* Copyright (c) 2014 Andreas Noever <andreas.noever@gmail.com>
* Copyright (C) 2018, Intel Corporation
*/
#include <linux/crc32.h>
#include <linux/delay.h>
#include <linux/slab.h>
#include <linux/pci.h>
#include <linux/dmapool.h>
#include <linux/workqueue.h>
#include "ctl.h"
#define TB_CTL_RX_PKG_COUNT 10
#define TB_CTL_RETRIES 4
/**
* struct tb_ctl - Thunderbolt control channel
* @nhi: Pointer to the NHI structure
* @tx: Transmit ring
* @rx: Receive ring
* @frame_pool: DMA pool for control messages
* @rx_packets: Received control messages
* @request_queue_lock: Lock protecting @request_queue
* @request_queue: List of outstanding requests
* @running: Is the control channel running at the moment
* @timeout_msec: Default timeout for non-raw control messages
* @callback: Callback called when hotplug message is received
* @callback_data: Data passed to @callback
*/
struct tb_ctl {
struct tb_nhi *nhi;
struct tb_ring *tx;
struct tb_ring *rx;
struct dma_pool *frame_pool;
struct ctl_pkg *rx_packets[TB_CTL_RX_PKG_COUNT];
struct mutex request_queue_lock;
struct list_head request_queue;
bool running;
int timeout_msec;
event_cb callback;
void *callback_data;
};
#define tb_ctl_WARN(ctl, format, arg...) \
dev_WARN(&(ctl)->nhi->pdev->dev, format, ## arg)
#define tb_ctl_err(ctl, format, arg...) \
dev_err(&(ctl)->nhi->pdev->dev, format, ## arg)
#define tb_ctl_warn(ctl, format, arg...) \
dev_warn(&(ctl)->nhi->pdev->dev, format, ## arg)
#define tb_ctl_info(ctl, format, arg...) \
dev_info(&(ctl)->nhi->pdev->dev, format, ## arg)
#define tb_ctl_dbg(ctl, format, arg...) \
dev_dbg(&(ctl)->nhi->pdev->dev, format, ## arg)
static DECLARE_WAIT_QUEUE_HEAD(tb_cfg_request_cancel_queue);
/* Serializes access to request kref_get/put */
static DEFINE_MUTEX(tb_cfg_request_lock);
/**
* tb_cfg_request_alloc() - Allocates a new config request
*
* This is refcounted object so when you are done with this, call
* tb_cfg_request_put() to it.
*/
struct tb_cfg_request *tb_cfg_request_alloc(void)
{
struct tb_cfg_request *req;
req = kzalloc(sizeof(*req), GFP_KERNEL);
if (!req)
return NULL;
kref_init(&req->kref);
return req;
}
/**
* tb_cfg_request_get() - Increase refcount of a request
* @req: Request whose refcount is increased
*/
void tb_cfg_request_get(struct tb_cfg_request *req)
{
mutex_lock(&tb_cfg_request_lock);
kref_get(&req->kref);
mutex_unlock(&tb_cfg_request_lock);
}
static void tb_cfg_request_destroy(struct kref *kref)
{
struct tb_cfg_request *req = container_of(kref, typeof(*req), kref);
kfree(req);
}
/**
* tb_cfg_request_put() - Decrease refcount and possibly release the request
* @req: Request whose refcount is decreased
*
* Call this function when you are done with the request. When refcount
* goes to %0 the object is released.
*/
void tb_cfg_request_put(struct tb_cfg_request *req)
{
mutex_lock(&tb_cfg_request_lock);
kref_put(&req->kref, tb_cfg_request_destroy);
mutex_unlock(&tb_cfg_request_lock);
}
static int tb_cfg_request_enqueue(struct tb_ctl *ctl,
struct tb_cfg_request *req)
{
WARN_ON(test_bit(TB_CFG_REQUEST_ACTIVE, &req->flags));
WARN_ON(req->ctl);
mutex_lock(&ctl->request_queue_lock);
if (!ctl->running) {
mutex_unlock(&ctl->request_queue_lock);
return -ENOTCONN;
}
req->ctl = ctl;
list_add_tail(&req->list, &ctl->request_queue);
set_bit(TB_CFG_REQUEST_ACTIVE, &req->flags);
mutex_unlock(&ctl->request_queue_lock);
return 0;
}
static void tb_cfg_request_dequeue(struct tb_cfg_request *req)
{
struct tb_ctl *ctl = req->ctl;
mutex_lock(&ctl->request_queue_lock);
list_del(&req->list);
clear_bit(TB_CFG_REQUEST_ACTIVE, &req->flags);
if (test_bit(TB_CFG_REQUEST_CANCELED, &req->flags))
wake_up(&tb_cfg_request_cancel_queue);
mutex_unlock(&ctl->request_queue_lock);
}
static bool tb_cfg_request_is_active(struct tb_cfg_request *req)
{
return test_bit(TB_CFG_REQUEST_ACTIVE, &req->flags);
}
static struct tb_cfg_request *
tb_cfg_request_find(struct tb_ctl *ctl, struct ctl_pkg *pkg)
{
struct tb_cfg_request *req = NULL, *iter;
mutex_lock(&pkg->ctl->request_queue_lock);
list_for_each_entry(iter, &pkg->ctl->request_queue, list) {
tb_cfg_request_get(iter);
if (iter->match(iter, pkg)) {
req = iter;
break;
}
tb_cfg_request_put(iter);
}
mutex_unlock(&pkg->ctl->request_queue_lock);
return req;
}
/* utility functions */
static int check_header(const struct ctl_pkg *pkg, u32 len,
enum tb_cfg_pkg_type type, u64 route)
{
struct tb_cfg_header *header = pkg->buffer;
/* check frame, TODO: frame flags */
if (WARN(len != pkg->frame.size,
"wrong framesize (expected %#x, got %#x)\n",
len, pkg->frame.size))
return -EIO;
if (WARN(type != pkg->frame.eof, "wrong eof (expected %#x, got %#x)\n",
type, pkg->frame.eof))
return -EIO;
if (WARN(pkg->frame.sof, "wrong sof (expected 0x0, got %#x)\n",
pkg->frame.sof))
return -EIO;
/* check header */
if (WARN(header->unknown != 1 << 9,
"header->unknown is %#x\n", header->unknown))
return -EIO;
if (WARN(route != tb_cfg_get_route(header),
"wrong route (expected %llx, got %llx)",
route, tb_cfg_get_route(header)))
return -EIO;
return 0;
}
static int check_config_address(struct tb_cfg_address addr,
enum tb_cfg_space space, u32 offset,
u32 length)
{
if (WARN(addr.zero, "addr.zero is %#x\n", addr.zero))
return -EIO;
if (WARN(space != addr.space, "wrong space (expected %x, got %x\n)",
space, addr.space))
return -EIO;
if (WARN(offset != addr.offset, "wrong offset (expected %x, got %x\n)",
offset, addr.offset))
return -EIO;
if (WARN(length != addr.length, "wrong space (expected %x, got %x\n)",
length, addr.length))
return -EIO;
/*
* We cannot check addr->port as it is set to the upstream port of the
* sender.
*/
return 0;
}
static struct tb_cfg_result decode_error(const struct ctl_pkg *response)
{
struct cfg_error_pkg *pkg = response->buffer;
struct tb_cfg_result res = { 0 };
res.response_route = tb_cfg_get_route(&pkg->header);
res.response_port = 0;
res.err = check_header(response, sizeof(*pkg), TB_CFG_PKG_ERROR,
tb_cfg_get_route(&pkg->header));
if (res.err)
return res;
res.err = 1;
res.tb_error = pkg->error;
res.response_port = pkg->port;
return res;
}
static struct tb_cfg_result parse_header(const struct ctl_pkg *pkg, u32 len,
enum tb_cfg_pkg_type type, u64 route)
{
struct tb_cfg_header *header = pkg->buffer;
struct tb_cfg_result res = { 0 };
if (pkg->frame.eof == TB_CFG_PKG_ERROR)
return decode_error(pkg);
res.response_port = 0; /* will be updated later for cfg_read/write */
res.response_route = tb_cfg_get_route(header);
res.err = check_header(pkg, len, type, route);
return res;
}
static void tb_cfg_print_error(struct tb_ctl *ctl,
const struct tb_cfg_result *res)
{
WARN_ON(res->err != 1);
switch (res->tb_error) {
case TB_CFG_ERROR_PORT_NOT_CONNECTED:
/* Port is not connected. This can happen during surprise
* removal. Do not warn. */
return;
case TB_CFG_ERROR_INVALID_CONFIG_SPACE:
/*
* Invalid cfg_space/offset/length combination in
* cfg_read/cfg_write.
*/
tb_ctl_dbg(ctl, "%llx:%x: invalid config space or offset\n",
res->response_route, res->response_port);
return;
case TB_CFG_ERROR_NO_SUCH_PORT:
/*
* - The route contains a non-existent port.
* - The route contains a non-PHY port (e.g. PCIe).
* - The port in cfg_read/cfg_write does not exist.
*/
tb_ctl_WARN(ctl, "CFG_ERROR(%llx:%x): Invalid port\n",
res->response_route, res->response_port);
return;
case TB_CFG_ERROR_LOOP:
tb_ctl_WARN(ctl, "CFG_ERROR(%llx:%x): Route contains a loop\n",
res->response_route, res->response_port);
return;
case TB_CFG_ERROR_LOCK:
tb_ctl_warn(ctl, "%llx:%x: downstream port is locked\n",
res->response_route, res->response_port);
return;
default:
/* 5,6,7,9 and 11 are also valid error codes */
tb_ctl_WARN(ctl, "CFG_ERROR(%llx:%x): Unknown error\n",
res->response_route, res->response_port);
return;
}
}
static __be32 tb_crc(const void *data, size_t len)
{
return cpu_to_be32(~__crc32c_le(~0, data, len));
}
static void tb_ctl_pkg_free(struct ctl_pkg *pkg)
{
if (pkg) {
dma_pool_free(pkg->ctl->frame_pool,
pkg->buffer, pkg->frame.buffer_phy);
kfree(pkg);
}
}
static struct ctl_pkg *tb_ctl_pkg_alloc(struct tb_ctl *ctl)
{
struct ctl_pkg *pkg = kzalloc(sizeof(*pkg), GFP_KERNEL);
if (!pkg)
return NULL;
pkg->ctl = ctl;
pkg->buffer = dma_pool_alloc(ctl->frame_pool, GFP_KERNEL,
&pkg->frame.buffer_phy);
if (!pkg->buffer) {
kfree(pkg);
return NULL;
}
return pkg;
}
/* RX/TX handling */
static void tb_ctl_tx_callback(struct tb_ring *ring, struct ring_frame *frame,
bool canceled)
{
struct ctl_pkg *pkg = container_of(frame, typeof(*pkg), frame);
tb_ctl_pkg_free(pkg);
}
/*
* tb_cfg_tx() - transmit a packet on the control channel
*
* len must be a multiple of four.
*
* Return: Returns 0 on success or an error code on failure.
*/
static int tb_ctl_tx(struct tb_ctl *ctl, const void *data, size_t len,
enum tb_cfg_pkg_type type)
{
int res;
struct ctl_pkg *pkg;
if (len % 4 != 0) { /* required for le->be conversion */
tb_ctl_WARN(ctl, "TX: invalid size: %zu\n", len);
return -EINVAL;
}
if (len > TB_FRAME_SIZE - 4) { /* checksum is 4 bytes */
tb_ctl_WARN(ctl, "TX: packet too large: %zu/%d\n",
len, TB_FRAME_SIZE - 4);
return -EINVAL;
}
pkg = tb_ctl_pkg_alloc(ctl);
if (!pkg)
return -ENOMEM;
pkg->frame.callback = tb_ctl_tx_callback;
pkg->frame.size = len + 4;
pkg->frame.sof = type;
pkg->frame.eof = type;
cpu_to_be32_array(pkg->buffer, data, len / 4);
*(__be32 *) (pkg->buffer + len) = tb_crc(pkg->buffer, len);
res = tb_ring_tx(ctl->tx, &pkg->frame);
if (res) /* ring is stopped */
tb_ctl_pkg_free(pkg);
return res;
}
/*
* tb_ctl_handle_event() - acknowledge a plug event, invoke ctl->callback
*/
static bool tb_ctl_handle_event(struct tb_ctl *ctl, enum tb_cfg_pkg_type type,
struct ctl_pkg *pkg, size_t size)
{
return ctl->callback(ctl->callback_data, type, pkg->buffer, size);
}
static void tb_ctl_rx_submit(struct ctl_pkg *pkg)
{
tb_ring_rx(pkg->ctl->rx, &pkg->frame); /*
* We ignore failures during stop.
* All rx packets are referenced
* from ctl->rx_packets, so we do
* not loose them.
*/
}
static int tb_async_error(const struct ctl_pkg *pkg)
{
const struct cfg_error_pkg *error = pkg->buffer;
if (pkg->frame.eof != TB_CFG_PKG_ERROR)
return false;
switch (error->error) {
case TB_CFG_ERROR_LINK_ERROR:
case TB_CFG_ERROR_HEC_ERROR_DETECTED:
case TB_CFG_ERROR_FLOW_CONTROL_ERROR:
case TB_CFG_ERROR_DP_BW:
case TB_CFG_ERROR_ROP_CMPLT:
case TB_CFG_ERROR_POP_CMPLT:
case TB_CFG_ERROR_PCIE_WAKE:
case TB_CFG_ERROR_DP_CON_CHANGE:
case TB_CFG_ERROR_DPTX_DISCOVERY:
case TB_CFG_ERROR_LINK_RECOVERY:
case TB_CFG_ERROR_ASYM_LINK:
return true;
default:
return false;
}
}
static void tb_ctl_rx_callback(struct tb_ring *ring, struct ring_frame *frame,
bool canceled)
{
struct ctl_pkg *pkg = container_of(frame, typeof(*pkg), frame);
struct tb_cfg_request *req;
__be32 crc32;
if (canceled)
return; /*
* ring is stopped, packet is referenced from
* ctl->rx_packets.
*/
if (frame->size < 4 || frame->size % 4 != 0) {
tb_ctl_err(pkg->ctl, "RX: invalid size %#x, dropping packet\n",
frame->size);
goto rx;
}
frame->size -= 4; /* remove checksum */
crc32 = tb_crc(pkg->buffer, frame->size);
be32_to_cpu_array(pkg->buffer, pkg->buffer, frame->size / 4);
switch (frame->eof) {
case TB_CFG_PKG_READ:
case TB_CFG_PKG_WRITE:
case TB_CFG_PKG_ERROR:
case TB_CFG_PKG_OVERRIDE:
case TB_CFG_PKG_RESET:
if (*(__be32 *)(pkg->buffer + frame->size) != crc32) {
tb_ctl_err(pkg->ctl,
"RX: checksum mismatch, dropping packet\n");
goto rx;
}
if (tb_async_error(pkg)) {
tb_ctl_handle_event(pkg->ctl, frame->eof,
pkg, frame->size);
goto rx;
}
break;
case TB_CFG_PKG_EVENT:
case TB_CFG_PKG_XDOMAIN_RESP:
case TB_CFG_PKG_XDOMAIN_REQ:
if (*(__be32 *)(pkg->buffer + frame->size) != crc32) {
tb_ctl_err(pkg->ctl,
"RX: checksum mismatch, dropping packet\n");
goto rx;
}
fallthrough;
case TB_CFG_PKG_ICM_EVENT:
if (tb_ctl_handle_event(pkg->ctl, frame->eof, pkg, frame->size))
goto rx;
break;
default:
break;
}
/*
* The received packet will be processed only if there is an
* active request and that the packet is what is expected. This
* prevents packets such as replies coming after timeout has
* triggered from messing with the active requests.
*/
req = tb_cfg_request_find(pkg->ctl, pkg);
if (req) {
if (req->copy(req, pkg))
schedule_work(&req->work);
tb_cfg_request_put(req);
}
rx:
tb_ctl_rx_submit(pkg);
}
static void tb_cfg_request_work(struct work_struct *work)
{
struct tb_cfg_request *req = container_of(work, typeof(*req), work);
if (!test_bit(TB_CFG_REQUEST_CANCELED, &req->flags))
req->callback(req->callback_data);
tb_cfg_request_dequeue(req);
tb_cfg_request_put(req);
}
/**
* tb_cfg_request() - Start control request not waiting for it to complete
* @ctl: Control channel to use
* @req: Request to start
* @callback: Callback called when the request is completed
* @callback_data: Data to be passed to @callback
*
* This queues @req on the given control channel without waiting for it
* to complete. When the request completes @callback is called.
*/
int tb_cfg_request(struct tb_ctl *ctl, struct tb_cfg_request *req,
void (*callback)(void *), void *callback_data)
{
int ret;
req->flags = 0;
req->callback = callback;
req->callback_data = callback_data;
INIT_WORK(&req->work, tb_cfg_request_work);
INIT_LIST_HEAD(&req->list);
tb_cfg_request_get(req);
ret = tb_cfg_request_enqueue(ctl, req);
if (ret)
goto err_put;
ret = tb_ctl_tx(ctl, req->request, req->request_size,
req->request_type);
if (ret)
goto err_dequeue;
if (!req->response)
schedule_work(&req->work);
return 0;
err_dequeue:
tb_cfg_request_dequeue(req);
err_put:
tb_cfg_request_put(req);
return ret;
}
/**
* tb_cfg_request_cancel() - Cancel a control request
* @req: Request to cancel
* @err: Error to assign to the request
*
* This function can be used to cancel ongoing request. It will wait
* until the request is not active anymore.
*/
void tb_cfg_request_cancel(struct tb_cfg_request *req, int err)
{
set_bit(TB_CFG_REQUEST_CANCELED, &req->flags);
schedule_work(&req->work);
wait_event(tb_cfg_request_cancel_queue, !tb_cfg_request_is_active(req));
req->result.err = err;
}
static void tb_cfg_request_complete(void *data)
{
complete(data);
}
/**
* tb_cfg_request_sync() - Start control request and wait until it completes
* @ctl: Control channel to use
* @req: Request to start
* @timeout_msec: Timeout how long to wait @req to complete
*
* Starts a control request and waits until it completes. If timeout
* triggers the request is canceled before function returns. Note the
* caller needs to make sure only one message for given switch is active
* at a time.
*/
struct tb_cfg_result tb_cfg_request_sync(struct tb_ctl *ctl,
struct tb_cfg_request *req,
int timeout_msec)
{
unsigned long timeout = msecs_to_jiffies(timeout_msec);
struct tb_cfg_result res = { 0 };
DECLARE_COMPLETION_ONSTACK(done);
int ret;
ret = tb_cfg_request(ctl, req, tb_cfg_request_complete, &done);
if (ret) {
res.err = ret;
return res;
}
if (!wait_for_completion_timeout(&done, timeout))
tb_cfg_request_cancel(req, -ETIMEDOUT);
flush_work(&req->work);
return req->result;
}
/* public interface, alloc/start/stop/free */
/**
* tb_ctl_alloc() - allocate a control channel
* @nhi: Pointer to NHI
* @timeout_msec: Default timeout used with non-raw control messages
* @cb: Callback called for plug events
* @cb_data: Data passed to @cb
*
* cb will be invoked once for every hot plug event.
*
* Return: Returns a pointer on success or NULL on failure.
*/
struct tb_ctl *tb_ctl_alloc(struct tb_nhi *nhi, int timeout_msec, event_cb cb,
void *cb_data)
{
int i;
struct tb_ctl *ctl = kzalloc(sizeof(*ctl), GFP_KERNEL);
if (!ctl)
return NULL;
ctl->nhi = nhi;
ctl->timeout_msec = timeout_msec;
ctl->callback = cb;
ctl->callback_data = cb_data;
mutex_init(&ctl->request_queue_lock);
INIT_LIST_HEAD(&ctl->request_queue);
ctl->frame_pool = dma_pool_create("thunderbolt_ctl", &nhi->pdev->dev,
TB_FRAME_SIZE, 4, 0);
if (!ctl->frame_pool)
goto err;
ctl->tx = tb_ring_alloc_tx(nhi, 0, 10, RING_FLAG_NO_SUSPEND);
if (!ctl->tx)
goto err;
ctl->rx = tb_ring_alloc_rx(nhi, 0, 10, RING_FLAG_NO_SUSPEND, 0, 0xffff,
0xffff, NULL, NULL);
if (!ctl->rx)
goto err;
for (i = 0; i < TB_CTL_RX_PKG_COUNT; i++) {
ctl->rx_packets[i] = tb_ctl_pkg_alloc(ctl);
if (!ctl->rx_packets[i])
goto err;
ctl->rx_packets[i]->frame.callback = tb_ctl_rx_callback;
}
tb_ctl_dbg(ctl, "control channel created\n");
return ctl;
err:
tb_ctl_free(ctl);
return NULL;
}
/**
* tb_ctl_free() - free a control channel
* @ctl: Control channel to free
*
* Must be called after tb_ctl_stop.
*
* Must NOT be called from ctl->callback.
*/
void tb_ctl_free(struct tb_ctl *ctl)
{
int i;
if (!ctl)
return;
if (ctl->rx)
tb_ring_free(ctl->rx);
if (ctl->tx)
tb_ring_free(ctl->tx);
/* free RX packets */
for (i = 0; i < TB_CTL_RX_PKG_COUNT; i++)
tb_ctl_pkg_free(ctl->rx_packets[i]);
dma_pool_destroy(ctl->frame_pool);
kfree(ctl);
}
/**
* tb_ctl_start() - start/resume the control channel
* @ctl: Control channel to start
*/
void tb_ctl_start(struct tb_ctl *ctl)
{
int i;
tb_ctl_dbg(ctl, "control channel starting...\n");
tb_ring_start(ctl->tx); /* is used to ack hotplug packets, start first */
tb_ring_start(ctl->rx);
for (i = 0; i < TB_CTL_RX_PKG_COUNT; i++)
tb_ctl_rx_submit(ctl->rx_packets[i]);
ctl->running = true;
}
/**
* tb_ctl_stop() - pause the control channel
* @ctl: Control channel to stop
*
* All invocations of ctl->callback will have finished after this method
* returns.
*
* Must NOT be called from ctl->callback.
*/
void tb_ctl_stop(struct tb_ctl *ctl)
{
mutex_lock(&ctl->request_queue_lock);
ctl->running = false;
mutex_unlock(&ctl->request_queue_lock);
tb_ring_stop(ctl->rx);
tb_ring_stop(ctl->tx);
if (!list_empty(&ctl->request_queue))
tb_ctl_WARN(ctl, "dangling request in request_queue\n");
INIT_LIST_HEAD(&ctl->request_queue);
tb_ctl_dbg(ctl, "control channel stopped\n");
}
/* public interface, commands */
/**
* tb_cfg_ack_notification() - Ack notification
* @ctl: Control channel to use
* @route: Router that originated the event
* @error: Pointer to the notification package
*
* Call this as response for non-plug notification to ack it. Returns
* %0 on success or an error code on failure.
*/
int tb_cfg_ack_notification(struct tb_ctl *ctl, u64 route,
const struct cfg_error_pkg *error)
{
struct cfg_ack_pkg pkg = {
.header = tb_cfg_make_header(route),
};
const char *name;
switch (error->error) {
case TB_CFG_ERROR_LINK_ERROR:
name = "link error";
break;
case TB_CFG_ERROR_HEC_ERROR_DETECTED:
name = "HEC error";
break;
case TB_CFG_ERROR_FLOW_CONTROL_ERROR:
name = "flow control error";
break;
case TB_CFG_ERROR_DP_BW:
name = "DP_BW";
break;
case TB_CFG_ERROR_ROP_CMPLT:
name = "router operation completion";
break;
case TB_CFG_ERROR_POP_CMPLT:
name = "port operation completion";
break;
case TB_CFG_ERROR_PCIE_WAKE:
name = "PCIe wake";
break;
case TB_CFG_ERROR_DP_CON_CHANGE:
name = "DP connector change";
break;
case TB_CFG_ERROR_DPTX_DISCOVERY:
name = "DPTX discovery";
break;
case TB_CFG_ERROR_LINK_RECOVERY:
name = "link recovery";
break;
case TB_CFG_ERROR_ASYM_LINK:
name = "asymmetric link";
break;
default:
name = "unknown";
break;
}
tb_ctl_dbg(ctl, "acking %s (%#x) notification on %llx\n", name,
error->error, route);
return tb_ctl_tx(ctl, &pkg, sizeof(pkg), TB_CFG_PKG_NOTIFY_ACK);
}
/**
* tb_cfg_ack_plug() - Ack hot plug/unplug event
* @ctl: Control channel to use
* @route: Router that originated the event
* @port: Port where the hot plug/unplug happened
* @unplug: Ack hot plug or unplug
*
* Call this as response for hot plug/unplug event to ack it.
* Returns %0 on success or an error code on failure.
*/
int tb_cfg_ack_plug(struct tb_ctl *ctl, u64 route, u32 port, bool unplug)
{
struct cfg_error_pkg pkg = {
.header = tb_cfg_make_header(route),
.port = port,
.error = TB_CFG_ERROR_ACK_PLUG_EVENT,
.pg = unplug ? TB_CFG_ERROR_PG_HOT_UNPLUG
: TB_CFG_ERROR_PG_HOT_PLUG,
};
tb_ctl_dbg(ctl, "acking hot %splug event on %llx:%u\n",
unplug ? "un" : "", route, port);
return tb_ctl_tx(ctl, &pkg, sizeof(pkg), TB_CFG_PKG_ERROR);
}
static bool tb_cfg_match(const struct tb_cfg_request *req,
const struct ctl_pkg *pkg)
{
u64 route = tb_cfg_get_route(pkg->buffer) & ~BIT_ULL(63);
if (pkg->frame.eof == TB_CFG_PKG_ERROR)
return true;
if (pkg->frame.eof != req->response_type)
return false;
if (route != tb_cfg_get_route(req->request))
return false;
if (pkg->frame.size != req->response_size)
return false;
if (pkg->frame.eof == TB_CFG_PKG_READ ||
pkg->frame.eof == TB_CFG_PKG_WRITE) {
const struct cfg_read_pkg *req_hdr = req->request;
const struct cfg_read_pkg *res_hdr = pkg->buffer;
if (req_hdr->addr.seq != res_hdr->addr.seq)
return false;
}
return true;
}
static bool tb_cfg_copy(struct tb_cfg_request *req, const struct ctl_pkg *pkg)
{
struct tb_cfg_result res;
/* Now make sure it is in expected format */
res = parse_header(pkg, req->response_size, req->response_type,
tb_cfg_get_route(req->request));
if (!res.err)
memcpy(req->response, pkg->buffer, req->response_size);
req->result = res;
/* Always complete when first response is received */
return true;
}
/**
* tb_cfg_reset() - send a reset packet and wait for a response
* @ctl: Control channel pointer
* @route: Router string for the router to send reset
*
* If the switch at route is incorrectly configured then we will not receive a
* reply (even though the switch will reset). The caller should check for
* -ETIMEDOUT and attempt to reconfigure the switch.
*/
struct tb_cfg_result tb_cfg_reset(struct tb_ctl *ctl, u64 route)
{
struct cfg_reset_pkg request = { .header = tb_cfg_make_header(route) };
struct tb_cfg_result res = { 0 };
struct tb_cfg_header reply;
struct tb_cfg_request *req;
req = tb_cfg_request_alloc();
if (!req) {
res.err = -ENOMEM;
return res;
}
req->match = tb_cfg_match;
req->copy = tb_cfg_copy;
req->request = &request;
req->request_size = sizeof(request);
req->request_type = TB_CFG_PKG_RESET;
req->response = &reply;
req->response_size = sizeof(reply);
req->response_type = TB_CFG_PKG_RESET;
res = tb_cfg_request_sync(ctl, req, ctl->timeout_msec);
tb_cfg_request_put(req);
return res;
}
/**
* tb_cfg_read_raw() - read from config space into buffer
* @ctl: Pointer to the control channel
* @buffer: Buffer where the data is read
* @route: Route string of the router
* @port: Port number when reading from %TB_CFG_PORT, %0 otherwise
* @space: Config space selector
* @offset: Dword word offset of the register to start reading
* @length: Number of dwords to read
* @timeout_msec: Timeout in ms how long to wait for the response
*
* Reads from router config space without translating the possible error.
*/
struct tb_cfg_result tb_cfg_read_raw(struct tb_ctl *ctl, void *buffer,
u64 route, u32 port, enum tb_cfg_space space,
u32 offset, u32 length, int timeout_msec)
{
struct tb_cfg_result res = { 0 };
struct cfg_read_pkg request = {
.header = tb_cfg_make_header(route),
.addr = {
.port = port,
.space = space,
.offset = offset,
.length = length,
},
};
struct cfg_write_pkg reply;
int retries = 0;
while (retries < TB_CTL_RETRIES) {
struct tb_cfg_request *req;
req = tb_cfg_request_alloc();
if (!req) {
res.err = -ENOMEM;
return res;
}
request.addr.seq = retries++;
req->match = tb_cfg_match;
req->copy = tb_cfg_copy;
req->request = &request;
req->request_size = sizeof(request);
req->request_type = TB_CFG_PKG_READ;
req->response = &reply;
req->response_size = 12 + 4 * length;
req->response_type = TB_CFG_PKG_READ;
res = tb_cfg_request_sync(ctl, req, timeout_msec);
tb_cfg_request_put(req);
if (res.err != -ETIMEDOUT)
break;
/* Wait a bit (arbitrary time) until we send a retry */
usleep_range(10, 100);
}
if (res.err)
return res;
res.response_port = reply.addr.port;
res.err = check_config_address(reply.addr, space, offset, length);
if (!res.err)
memcpy(buffer, &reply.data, 4 * length);
return res;
}
/**
* tb_cfg_write_raw() - write from buffer into config space
* @ctl: Pointer to the control channel
* @buffer: Data to write
* @route: Route string of the router
* @port: Port number when writing to %TB_CFG_PORT, %0 otherwise
* @space: Config space selector
* @offset: Dword word offset of the register to start writing
* @length: Number of dwords to write
* @timeout_msec: Timeout in ms how long to wait for the response
*
* Writes to router config space without translating the possible error.
*/
struct tb_cfg_result tb_cfg_write_raw(struct tb_ctl *ctl, const void *buffer,
u64 route, u32 port, enum tb_cfg_space space,
u32 offset, u32 length, int timeout_msec)
{
struct tb_cfg_result res = { 0 };
struct cfg_write_pkg request = {
.header = tb_cfg_make_header(route),
.addr = {
.port = port,
.space = space,
.offset = offset,
.length = length,
},
};
struct cfg_read_pkg reply;
int retries = 0;
memcpy(&request.data, buffer, length * 4);
while (retries < TB_CTL_RETRIES) {
struct tb_cfg_request *req;
req = tb_cfg_request_alloc();
if (!req) {
res.err = -ENOMEM;
return res;
}
request.addr.seq = retries++;
req->match = tb_cfg_match;
req->copy = tb_cfg_copy;
req->request = &request;
req->request_size = 12 + 4 * length;
req->request_type = TB_CFG_PKG_WRITE;
req->response = &reply;
req->response_size = sizeof(reply);
req->response_type = TB_CFG_PKG_WRITE;
res = tb_cfg_request_sync(ctl, req, timeout_msec);
tb_cfg_request_put(req);
if (res.err != -ETIMEDOUT)
break;
/* Wait a bit (arbitrary time) until we send a retry */
usleep_range(10, 100);
}
if (res.err)
return res;
res.response_port = reply.addr.port;
res.err = check_config_address(reply.addr, space, offset, length);
return res;
}
static int tb_cfg_get_error(struct tb_ctl *ctl, enum tb_cfg_space space,
const struct tb_cfg_result *res)
{
/*
* For unimplemented ports access to port config space may return
* TB_CFG_ERROR_INVALID_CONFIG_SPACE (alternatively their type is
* set to TB_TYPE_INACTIVE). In the former case return -ENODEV so
* that the caller can mark the port as disabled.
*/
if (space == TB_CFG_PORT &&
res->tb_error == TB_CFG_ERROR_INVALID_CONFIG_SPACE)
return -ENODEV;
tb_cfg_print_error(ctl, res);
if (res->tb_error == TB_CFG_ERROR_LOCK)
return -EACCES;
if (res->tb_error == TB_CFG_ERROR_PORT_NOT_CONNECTED)
return -ENOTCONN;
return -EIO;
}
int tb_cfg_read(struct tb_ctl *ctl, void *buffer, u64 route, u32 port,
enum tb_cfg_space space, u32 offset, u32 length)
{
struct tb_cfg_result res = tb_cfg_read_raw(ctl, buffer, route, port,
space, offset, length, ctl->timeout_msec);
switch (res.err) {
case 0:
/* Success */
break;
case 1:
/* Thunderbolt error, tb_error holds the actual number */
return tb_cfg_get_error(ctl, space, &res);
case -ETIMEDOUT:
tb_ctl_warn(ctl, "%llx: timeout reading config space %u from %#x\n",
route, space, offset);
break;
default:
WARN(1, "tb_cfg_read: %d\n", res.err);
break;
}
return res.err;
}
int tb_cfg_write(struct tb_ctl *ctl, const void *buffer, u64 route, u32 port,
enum tb_cfg_space space, u32 offset, u32 length)
{
struct tb_cfg_result res = tb_cfg_write_raw(ctl, buffer, route, port,
space, offset, length, ctl->timeout_msec);
switch (res.err) {
case 0:
/* Success */
break;
case 1:
/* Thunderbolt error, tb_error holds the actual number */
return tb_cfg_get_error(ctl, space, &res);
case -ETIMEDOUT:
tb_ctl_warn(ctl, "%llx: timeout writing config space %u to %#x\n",
route, space, offset);
break;
default:
WARN(1, "tb_cfg_write: %d\n", res.err);
break;
}
return res.err;
}
/**
* tb_cfg_get_upstream_port() - get upstream port number of switch at route
* @ctl: Pointer to the control channel
* @route: Route string of the router
*
* Reads the first dword from the switches TB_CFG_SWITCH config area and
* returns the port number from which the reply originated.
*
* Return: Returns the upstream port number on success or an error code on
* failure.
*/
int tb_cfg_get_upstream_port(struct tb_ctl *ctl, u64 route)
{
u32 dummy;
struct tb_cfg_result res = tb_cfg_read_raw(ctl, &dummy, route, 0,
TB_CFG_SWITCH, 0, 1,
ctl->timeout_msec);
if (res.err == 1)
return -EIO;
if (res.err)
return res.err;
return res.response_port;
}