blob: 4bdb2d45e0bffc2261b5d846edfd570d20a04e01 [file] [log] [blame] [edit]
// 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 CREATE_TRACE_POINTS
#include "trace.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
* @index: Domain number. This will be output with the trace record.
*/
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;
int index;
};
#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;
trace_tb_tx(ctl->index, type, data, len);
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)
{
trace_tb_event(ctl->index, type, pkg->buffer, 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);
trace_tb_rx(pkg->ctl->index, frame->eof, pkg->buffer, frame->size, !req);
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
* @index: Domain number
* @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 index, 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->index = index;
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;
}