linux_dsm_epyc7002/drivers/usb/usbip/usbip_common.c

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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2003-2008 Takahiro Hirofuchi
* Copyright (C) 2015-2016 Samsung Electronics
* Krzysztof Opasiak <k.opasiak@samsung.com>
*/
#include <asm/byteorder.h>
#include <linux/file.h>
#include <linux/fs.h>
#include <linux/kernel.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 15:04:11 +07:00
#include <linux/slab.h>
#include <linux/stat.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <net/sock.h>
#include "usbip_common.h"
#define DRIVER_AUTHOR "Takahiro Hirofuchi <hirofuchi@users.sourceforge.net>"
#define DRIVER_DESC "USB/IP Core"
#ifdef CONFIG_USBIP_DEBUG
unsigned long usbip_debug_flag = 0xffffffff;
#else
unsigned long usbip_debug_flag;
#endif
EXPORT_SYMBOL_GPL(usbip_debug_flag);
module_param(usbip_debug_flag, ulong, S_IRUGO|S_IWUSR);
MODULE_PARM_DESC(usbip_debug_flag, "debug flags (defined in usbip_common.h)");
/* FIXME */
struct device_attribute dev_attr_usbip_debug;
EXPORT_SYMBOL_GPL(dev_attr_usbip_debug);
static ssize_t usbip_debug_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
return sprintf(buf, "%lx\n", usbip_debug_flag);
}
static ssize_t usbip_debug_store(struct device *dev,
struct device_attribute *attr, const char *buf,
size_t count)
{
if (sscanf(buf, "%lx", &usbip_debug_flag) != 1)
return -EINVAL;
return count;
}
DEVICE_ATTR_RW(usbip_debug);
static void usbip_dump_buffer(char *buff, int bufflen)
{
print_hex_dump(KERN_DEBUG, "usbip-core", DUMP_PREFIX_OFFSET, 16, 4,
buff, bufflen, false);
}
static void usbip_dump_pipe(unsigned int p)
{
unsigned char type = usb_pipetype(p);
unsigned char ep = usb_pipeendpoint(p);
unsigned char dev = usb_pipedevice(p);
unsigned char dir = usb_pipein(p);
pr_debug("dev(%d) ep(%d) [%s] ", dev, ep, dir ? "IN" : "OUT");
switch (type) {
case PIPE_ISOCHRONOUS:
pr_debug("ISO\n");
break;
case PIPE_INTERRUPT:
pr_debug("INT\n");
break;
case PIPE_CONTROL:
pr_debug("CTRL\n");
break;
case PIPE_BULK:
pr_debug("BULK\n");
break;
default:
pr_debug("ERR\n");
break;
}
}
static void usbip_dump_usb_device(struct usb_device *udev)
{
struct device *dev = &udev->dev;
int i;
dev_dbg(dev, " devnum(%d) devpath(%s) usb speed(%s)",
udev->devnum, udev->devpath, usb_speed_string(udev->speed));
pr_debug("tt hub ttport %d\n", udev->ttport);
dev_dbg(dev, " ");
for (i = 0; i < 16; i++)
pr_debug(" %2u", i);
pr_debug("\n");
dev_dbg(dev, " toggle0(IN) :");
for (i = 0; i < 16; i++)
pr_debug(" %2u", (udev->toggle[0] & (1 << i)) ? 1 : 0);
pr_debug("\n");
dev_dbg(dev, " toggle1(OUT):");
for (i = 0; i < 16; i++)
pr_debug(" %2u", (udev->toggle[1] & (1 << i)) ? 1 : 0);
pr_debug("\n");
dev_dbg(dev, " epmaxp_in :");
for (i = 0; i < 16; i++) {
if (udev->ep_in[i])
pr_debug(" %2u",
le16_to_cpu(udev->ep_in[i]->desc.wMaxPacketSize));
}
pr_debug("\n");
dev_dbg(dev, " epmaxp_out :");
for (i = 0; i < 16; i++) {
if (udev->ep_out[i])
pr_debug(" %2u",
le16_to_cpu(udev->ep_out[i]->desc.wMaxPacketSize));
}
pr_debug("\n");
dev_dbg(dev, "parent %s, bus %s\n", dev_name(&udev->parent->dev),
udev->bus->bus_name);
dev_dbg(dev, "have_langid %d, string_langid %d\n",
udev->have_langid, udev->string_langid);
dev_dbg(dev, "maxchild %d\n", udev->maxchild);
}
static void usbip_dump_request_type(__u8 rt)
{
switch (rt & USB_RECIP_MASK) {
case USB_RECIP_DEVICE:
pr_debug("DEVICE");
break;
case USB_RECIP_INTERFACE:
pr_debug("INTERF");
break;
case USB_RECIP_ENDPOINT:
pr_debug("ENDPOI");
break;
case USB_RECIP_OTHER:
pr_debug("OTHER ");
break;
default:
pr_debug("------");
break;
}
}
static void usbip_dump_usb_ctrlrequest(struct usb_ctrlrequest *cmd)
{
if (!cmd) {
pr_debug(" : null pointer\n");
return;
}
pr_debug(" ");
pr_debug("bRequestType(%02X) bRequest(%02X) wValue(%04X) wIndex(%04X) wLength(%04X) ",
cmd->bRequestType, cmd->bRequest,
cmd->wValue, cmd->wIndex, cmd->wLength);
pr_debug("\n ");
if ((cmd->bRequestType & USB_TYPE_MASK) == USB_TYPE_STANDARD) {
pr_debug("STANDARD ");
switch (cmd->bRequest) {
case USB_REQ_GET_STATUS:
pr_debug("GET_STATUS\n");
break;
case USB_REQ_CLEAR_FEATURE:
pr_debug("CLEAR_FEAT\n");
break;
case USB_REQ_SET_FEATURE:
pr_debug("SET_FEAT\n");
break;
case USB_REQ_SET_ADDRESS:
pr_debug("SET_ADDRRS\n");
break;
case USB_REQ_GET_DESCRIPTOR:
pr_debug("GET_DESCRI\n");
break;
case USB_REQ_SET_DESCRIPTOR:
pr_debug("SET_DESCRI\n");
break;
case USB_REQ_GET_CONFIGURATION:
pr_debug("GET_CONFIG\n");
break;
case USB_REQ_SET_CONFIGURATION:
pr_debug("SET_CONFIG\n");
break;
case USB_REQ_GET_INTERFACE:
pr_debug("GET_INTERF\n");
break;
case USB_REQ_SET_INTERFACE:
pr_debug("SET_INTERF\n");
break;
case USB_REQ_SYNCH_FRAME:
pr_debug("SYNC_FRAME\n");
break;
default:
pr_debug("REQ(%02X)\n", cmd->bRequest);
break;
}
usbip_dump_request_type(cmd->bRequestType);
} else if ((cmd->bRequestType & USB_TYPE_MASK) == USB_TYPE_CLASS) {
pr_debug("CLASS\n");
} else if ((cmd->bRequestType & USB_TYPE_MASK) == USB_TYPE_VENDOR) {
pr_debug("VENDOR\n");
} else if ((cmd->bRequestType & USB_TYPE_MASK) == USB_TYPE_RESERVED) {
pr_debug("RESERVED\n");
}
}
void usbip_dump_urb(struct urb *urb)
{
struct device *dev;
if (!urb) {
pr_debug("urb: null pointer!!\n");
return;
}
if (!urb->dev) {
pr_debug("urb->dev: null pointer!!\n");
return;
}
dev = &urb->dev->dev;
usbip_dump_usb_device(urb->dev);
dev_dbg(dev, " pipe :%08x ", urb->pipe);
usbip_dump_pipe(urb->pipe);
dev_dbg(dev, " status :%d\n", urb->status);
dev_dbg(dev, " transfer_flags :%08X\n", urb->transfer_flags);
dev_dbg(dev, " transfer_buffer_length:%d\n",
urb->transfer_buffer_length);
dev_dbg(dev, " actual_length :%d\n", urb->actual_length);
if (urb->setup_packet && usb_pipetype(urb->pipe) == PIPE_CONTROL)
usbip_dump_usb_ctrlrequest(
(struct usb_ctrlrequest *)urb->setup_packet);
dev_dbg(dev, " start_frame :%d\n", urb->start_frame);
dev_dbg(dev, " number_of_packets :%d\n", urb->number_of_packets);
dev_dbg(dev, " interval :%d\n", urb->interval);
dev_dbg(dev, " error_count :%d\n", urb->error_count);
}
EXPORT_SYMBOL_GPL(usbip_dump_urb);
void usbip_dump_header(struct usbip_header *pdu)
{
pr_debug("BASE: cmd %u seq %u devid %u dir %u ep %u\n",
pdu->base.command,
pdu->base.seqnum,
pdu->base.devid,
pdu->base.direction,
pdu->base.ep);
switch (pdu->base.command) {
case USBIP_CMD_SUBMIT:
pr_debug("USBIP_CMD_SUBMIT: x_flags %u x_len %u sf %u #p %d iv %d\n",
pdu->u.cmd_submit.transfer_flags,
pdu->u.cmd_submit.transfer_buffer_length,
pdu->u.cmd_submit.start_frame,
pdu->u.cmd_submit.number_of_packets,
pdu->u.cmd_submit.interval);
break;
case USBIP_CMD_UNLINK:
pr_debug("USBIP_CMD_UNLINK: seq %u\n",
pdu->u.cmd_unlink.seqnum);
break;
case USBIP_RET_SUBMIT:
pr_debug("USBIP_RET_SUBMIT: st %d al %u sf %d #p %d ec %d\n",
pdu->u.ret_submit.status,
pdu->u.ret_submit.actual_length,
pdu->u.ret_submit.start_frame,
pdu->u.ret_submit.number_of_packets,
pdu->u.ret_submit.error_count);
break;
case USBIP_RET_UNLINK:
pr_debug("USBIP_RET_UNLINK: status %d\n",
pdu->u.ret_unlink.status);
break;
default:
/* NOT REACHED */
pr_err("unknown command\n");
break;
}
}
EXPORT_SYMBOL_GPL(usbip_dump_header);
/* Receive data over TCP/IP. */
int usbip_recv(struct socket *sock, void *buf, int size)
{
int result;
struct kvec iov = {.iov_base = buf, .iov_len = size};
struct msghdr msg = {.msg_flags = MSG_NOSIGNAL};
int total = 0;
if (!sock || !buf || !size)
return -EINVAL;
iov_iter_kvec(&msg.msg_iter, READ, &iov, 1, size);
usbip_dbg_xmit("enter\n");
do {
sock->sk->sk_allocation = GFP_NOIO;
result = sock_recvmsg(sock, &msg, MSG_WAITALL);
if (result <= 0)
goto err;
total += result;
} while (msg_data_left(&msg));
if (usbip_dbg_flag_xmit) {
if (!in_interrupt())
pr_debug("%-10s:", current->comm);
else
pr_debug("interrupt :");
pr_debug("receiving....\n");
usbip_dump_buffer(buf, size);
pr_debug("received, osize %d ret %d size %zd total %d\n",
size, result, msg_data_left(&msg), total);
}
return total;
err:
return result;
}
EXPORT_SYMBOL_GPL(usbip_recv);
/* there may be more cases to tweak the flags. */
static unsigned int tweak_transfer_flags(unsigned int flags)
{
flags &= ~URB_NO_TRANSFER_DMA_MAP;
return flags;
}
static void usbip_pack_cmd_submit(struct usbip_header *pdu, struct urb *urb,
int pack)
{
struct usbip_header_cmd_submit *spdu = &pdu->u.cmd_submit;
/*
* Some members are not still implemented in usbip. I hope this issue
* will be discussed when usbip is ported to other operating systems.
*/
if (pack) {
spdu->transfer_flags =
tweak_transfer_flags(urb->transfer_flags);
spdu->transfer_buffer_length = urb->transfer_buffer_length;
spdu->start_frame = urb->start_frame;
spdu->number_of_packets = urb->number_of_packets;
spdu->interval = urb->interval;
} else {
urb->transfer_flags = spdu->transfer_flags;
urb->transfer_buffer_length = spdu->transfer_buffer_length;
urb->start_frame = spdu->start_frame;
urb->number_of_packets = spdu->number_of_packets;
urb->interval = spdu->interval;
}
}
static void usbip_pack_ret_submit(struct usbip_header *pdu, struct urb *urb,
int pack)
{
struct usbip_header_ret_submit *rpdu = &pdu->u.ret_submit;
if (pack) {
rpdu->status = urb->status;
rpdu->actual_length = urb->actual_length;
rpdu->start_frame = urb->start_frame;
rpdu->number_of_packets = urb->number_of_packets;
rpdu->error_count = urb->error_count;
} else {
urb->status = rpdu->status;
urb->actual_length = rpdu->actual_length;
urb->start_frame = rpdu->start_frame;
urb->number_of_packets = rpdu->number_of_packets;
urb->error_count = rpdu->error_count;
}
}
void usbip_pack_pdu(struct usbip_header *pdu, struct urb *urb, int cmd,
int pack)
{
switch (cmd) {
case USBIP_CMD_SUBMIT:
usbip_pack_cmd_submit(pdu, urb, pack);
break;
case USBIP_RET_SUBMIT:
usbip_pack_ret_submit(pdu, urb, pack);
break;
default:
/* NOT REACHED */
pr_err("unknown command\n");
break;
}
}
EXPORT_SYMBOL_GPL(usbip_pack_pdu);
static void correct_endian_basic(struct usbip_header_basic *base, int send)
{
if (send) {
base->command = cpu_to_be32(base->command);
base->seqnum = cpu_to_be32(base->seqnum);
base->devid = cpu_to_be32(base->devid);
base->direction = cpu_to_be32(base->direction);
base->ep = cpu_to_be32(base->ep);
} else {
base->command = be32_to_cpu(base->command);
base->seqnum = be32_to_cpu(base->seqnum);
base->devid = be32_to_cpu(base->devid);
base->direction = be32_to_cpu(base->direction);
base->ep = be32_to_cpu(base->ep);
}
}
static void correct_endian_cmd_submit(struct usbip_header_cmd_submit *pdu,
int send)
{
if (send) {
pdu->transfer_flags = cpu_to_be32(pdu->transfer_flags);
cpu_to_be32s(&pdu->transfer_buffer_length);
cpu_to_be32s(&pdu->start_frame);
cpu_to_be32s(&pdu->number_of_packets);
cpu_to_be32s(&pdu->interval);
} else {
pdu->transfer_flags = be32_to_cpu(pdu->transfer_flags);
be32_to_cpus(&pdu->transfer_buffer_length);
be32_to_cpus(&pdu->start_frame);
be32_to_cpus(&pdu->number_of_packets);
be32_to_cpus(&pdu->interval);
}
}
static void correct_endian_ret_submit(struct usbip_header_ret_submit *pdu,
int send)
{
if (send) {
cpu_to_be32s(&pdu->status);
cpu_to_be32s(&pdu->actual_length);
cpu_to_be32s(&pdu->start_frame);
cpu_to_be32s(&pdu->number_of_packets);
cpu_to_be32s(&pdu->error_count);
} else {
be32_to_cpus(&pdu->status);
be32_to_cpus(&pdu->actual_length);
be32_to_cpus(&pdu->start_frame);
be32_to_cpus(&pdu->number_of_packets);
be32_to_cpus(&pdu->error_count);
}
}
static void correct_endian_cmd_unlink(struct usbip_header_cmd_unlink *pdu,
int send)
{
if (send)
pdu->seqnum = cpu_to_be32(pdu->seqnum);
else
pdu->seqnum = be32_to_cpu(pdu->seqnum);
}
static void correct_endian_ret_unlink(struct usbip_header_ret_unlink *pdu,
int send)
{
if (send)
cpu_to_be32s(&pdu->status);
else
be32_to_cpus(&pdu->status);
}
void usbip_header_correct_endian(struct usbip_header *pdu, int send)
{
__u32 cmd = 0;
if (send)
cmd = pdu->base.command;
correct_endian_basic(&pdu->base, send);
if (!send)
cmd = pdu->base.command;
switch (cmd) {
case USBIP_CMD_SUBMIT:
correct_endian_cmd_submit(&pdu->u.cmd_submit, send);
break;
case USBIP_RET_SUBMIT:
correct_endian_ret_submit(&pdu->u.ret_submit, send);
break;
case USBIP_CMD_UNLINK:
correct_endian_cmd_unlink(&pdu->u.cmd_unlink, send);
break;
case USBIP_RET_UNLINK:
correct_endian_ret_unlink(&pdu->u.ret_unlink, send);
break;
default:
/* NOT REACHED */
pr_err("unknown command\n");
break;
}
}
EXPORT_SYMBOL_GPL(usbip_header_correct_endian);
static void usbip_iso_packet_correct_endian(
struct usbip_iso_packet_descriptor *iso, int send)
{
/* does not need all members. but copy all simply. */
if (send) {
iso->offset = cpu_to_be32(iso->offset);
iso->length = cpu_to_be32(iso->length);
iso->status = cpu_to_be32(iso->status);
iso->actual_length = cpu_to_be32(iso->actual_length);
} else {
iso->offset = be32_to_cpu(iso->offset);
iso->length = be32_to_cpu(iso->length);
iso->status = be32_to_cpu(iso->status);
iso->actual_length = be32_to_cpu(iso->actual_length);
}
}
static void usbip_pack_iso(struct usbip_iso_packet_descriptor *iso,
struct usb_iso_packet_descriptor *uiso, int pack)
{
if (pack) {
iso->offset = uiso->offset;
iso->length = uiso->length;
iso->status = uiso->status;
iso->actual_length = uiso->actual_length;
} else {
uiso->offset = iso->offset;
uiso->length = iso->length;
uiso->status = iso->status;
uiso->actual_length = iso->actual_length;
}
}
/* must free buffer */
struct usbip_iso_packet_descriptor*
usbip_alloc_iso_desc_pdu(struct urb *urb, ssize_t *bufflen)
{
struct usbip_iso_packet_descriptor *iso;
int np = urb->number_of_packets;
ssize_t size = np * sizeof(*iso);
int i;
iso = kzalloc(size, GFP_KERNEL);
if (!iso)
return NULL;
for (i = 0; i < np; i++) {
usbip_pack_iso(&iso[i], &urb->iso_frame_desc[i], 1);
usbip_iso_packet_correct_endian(&iso[i], 1);
}
*bufflen = size;
return iso;
}
EXPORT_SYMBOL_GPL(usbip_alloc_iso_desc_pdu);
/* some members of urb must be substituted before. */
int usbip_recv_iso(struct usbip_device *ud, struct urb *urb)
{
void *buff;
struct usbip_iso_packet_descriptor *iso;
int np = urb->number_of_packets;
int size = np * sizeof(*iso);
int i;
int ret;
int total_length = 0;
if (!usb_pipeisoc(urb->pipe))
return 0;
/* my Bluetooth dongle gets ISO URBs which are np = 0 */
if (np == 0)
return 0;
buff = kzalloc(size, GFP_KERNEL);
if (!buff)
return -ENOMEM;
ret = usbip_recv(ud->tcp_socket, buff, size);
if (ret != size) {
dev_err(&urb->dev->dev, "recv iso_frame_descriptor, %d\n",
ret);
kfree(buff);
if (ud->side == USBIP_STUB || ud->side == USBIP_VUDC)
usbip_event_add(ud, SDEV_EVENT_ERROR_TCP);
else
usbip_event_add(ud, VDEV_EVENT_ERROR_TCP);
return -EPIPE;
}
iso = (struct usbip_iso_packet_descriptor *) buff;
for (i = 0; i < np; i++) {
usbip_iso_packet_correct_endian(&iso[i], 0);
usbip_pack_iso(&iso[i], &urb->iso_frame_desc[i], 0);
total_length += urb->iso_frame_desc[i].actual_length;
}
kfree(buff);
if (total_length != urb->actual_length) {
dev_err(&urb->dev->dev,
"total length of iso packets %d not equal to actual length of buffer %d\n",
total_length, urb->actual_length);
if (ud->side == USBIP_STUB || ud->side == USBIP_VUDC)
usbip_event_add(ud, SDEV_EVENT_ERROR_TCP);
else
usbip_event_add(ud, VDEV_EVENT_ERROR_TCP);
return -EPIPE;
}
return ret;
}
EXPORT_SYMBOL_GPL(usbip_recv_iso);
/*
* This functions restores the padding which was removed for optimizing
* the bandwidth during transfer over tcp/ip
*
* buffer and iso packets need to be stored and be in propeper endian in urb
* before calling this function
*/
void usbip_pad_iso(struct usbip_device *ud, struct urb *urb)
{
int np = urb->number_of_packets;
int i;
int actualoffset = urb->actual_length;
if (!usb_pipeisoc(urb->pipe))
return;
/* if no packets or length of data is 0, then nothing to unpack */
if (np == 0 || urb->actual_length == 0)
return;
/*
* if actual_length is transfer_buffer_length then no padding is
* present.
*/
if (urb->actual_length == urb->transfer_buffer_length)
return;
/*
* loop over all packets from last to first (to prevent overwriting
* memory when padding) and move them into the proper place
*/
for (i = np-1; i > 0; i--) {
actualoffset -= urb->iso_frame_desc[i].actual_length;
memmove(urb->transfer_buffer + urb->iso_frame_desc[i].offset,
urb->transfer_buffer + actualoffset,
urb->iso_frame_desc[i].actual_length);
}
}
EXPORT_SYMBOL_GPL(usbip_pad_iso);
/* some members of urb must be substituted before. */
int usbip_recv_xbuff(struct usbip_device *ud, struct urb *urb)
{
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
struct scatterlist *sg;
int ret = 0;
int recv;
int size;
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
int copy;
int i;
if (ud->side == USBIP_STUB || ud->side == USBIP_VUDC) {
/* the direction of urb must be OUT. */
if (usb_pipein(urb->pipe))
return 0;
size = urb->transfer_buffer_length;
} else {
/* the direction of urb must be IN. */
if (usb_pipeout(urb->pipe))
return 0;
size = urb->actual_length;
}
/* no need to recv xbuff */
if (!(size > 0))
return 0;
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
if (size > urb->transfer_buffer_length)
/* should not happen, probably malicious packet */
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
goto error;
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
if (urb->num_sgs) {
copy = size;
for_each_sg(urb->sg, sg, urb->num_sgs, i) {
int recv_size;
if (copy < sg->length)
recv_size = copy;
else
recv_size = sg->length;
recv = usbip_recv(ud->tcp_socket, sg_virt(sg),
recv_size);
if (recv != recv_size)
goto error;
copy -= recv;
ret += recv;
}
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
if (ret != size)
goto error;
} else {
ret = usbip_recv(ud->tcp_socket, urb->transfer_buffer, size);
if (ret != size)
goto error;
}
return ret;
usbip: Implement SG support to vhci-hcd and stub driver There are bugs on vhci with usb 3.0 storage device. In USB, each SG list entry buffer should be divisible by the bulk max packet size. But with native SG support, this problem doesn't matter because the SG buffer is treated as contiguous buffer. But without native SG support, USB storage driver breaks SG list into several URBs and the error occurs because of a buffer size of URB that cannot be divided by the bulk max packet size. The error situation is as follows. When USB Storage driver requests 31.5 KB data and has SG list which has 3584 bytes buffer followed by 7 4096 bytes buffer for some reason. USB Storage driver splits this SG list into several URBs because VHCI doesn't support SG and sends them separately. So the first URB buffer size is 3584 bytes. When receiving data from device, USB 3.0 device sends data packet of 1024 bytes size because the max packet size of BULK pipe is 1024 bytes. So device sends 4096 bytes. But the first URB buffer has only 3584 bytes buffer size. So host controller terminates the transfer even though there is more data to receive. So, vhci needs to support SG transfer to prevent this error. In this patch, vhci supports SG regardless of whether the server's host controller supports SG or not, because stub driver splits SG list into several URBs if the server's host controller doesn't support SG. To support SG, vhci sets URB_DMA_MAP_SG flag in urb->transfer_flags if URB has SG list and this flag will tell stub driver to use SG list. After receiving urb from stub driver, vhci clear URB_DMA_MAP_SG flag to avoid unnecessary DMA unmapping in HCD. vhci sends each SG list entry to stub driver. Then, stub driver sees the total length of the buffer and allocates SG table and pages according to the total buffer length calling sgl_alloc(). After stub driver receives completed URB, it again sends each SG list entry to vhci. If the server's host controller doesn't support SG, stub driver breaks a single SG request into several URBs and submits them to the server's host controller. When all the split URBs are completed, stub driver reassembles the URBs into a single return command and sends it to vhci. Moreover, in the situation where vhci supports SG, but stub driver does not, or vice versa, usbip works normally. Because there is no protocol modification, there is no problem in communication between server and client even if the one has a kernel without SG support. In the case of vhci supports SG and stub driver doesn't, because vhci sends only the total length of the buffer to stub driver as it did before the patch applied, stub driver only needs to allocate the required length of buffers using only kmalloc() regardless of whether vhci supports SG or not. But stub driver has to allocate buffer with kmalloc() as much as the total length of SG buffer which is quite huge when vhci sends SG request, so it has overhead in buffer allocation in this situation. If stub driver needs to send data buffer to vhci because of IN pipe, stub driver also sends only total length of buffer as metadata and then sends real data as vhci does. Then vhci receive data from stub driver and store it to the corresponding buffer of SG list entry. And for the case of stub driver supports SG and vhci doesn't, since the USB storage driver checks that vhci doesn't support SG and sends the request to stub driver by splitting the SG list into multiple URBs, stub driver allocates a buffer for each URB with kmalloc() as it did before this patch. * Test environment Test uses two difference machines and two different kernel version to make mismatch situation between the client and the server where vhci supports SG, but stub driver does not, or vice versa. All tests are conducted in both full SG support that both vhci and stub support SG and half SG support that is the mismatch situation. Test kernel version is 5.3-rc6 with commit "usb: add a HCD_DMA flag instead of guestimating DMA capabilities" to avoid unnecessary DMA mapping and unmapping. - Test kernel version - 5.3-rc6 with SG support - 5.1.20-200.fc29.x86_64 without SG support * SG support test - Test devices - Super-speed storage device - SanDisk Ultra USB 3.0 - High-speed storage device - SMI corporation USB 2.0 flash drive - Test description Test read and write operation of mass storage device that uses the BULK transfer. In test, the client reads and writes files whose size is over 1G and it works normally. * Regression test - Test devices - Super-speed device - Logitech Brio webcam - High-speed device - Logitech C920 HD Pro webcam - Full-speed device - Logitech bluetooth mouse - Britz BR-Orion speaker - Low-speed device - Logitech wired mouse - Test description Moving and click test for mouse. To test the webcam, use gnome-cheese. To test the speaker, play music and video on the client. All works normally. * VUDC compatibility test VUDC also works well with this patch. Tests are done with two USB gadget created by CONFIGFS USB gadget. Both use the BULK pipe. 1. Serial gadget 2. Mass storage gadget - Serial gadget test Serial gadget on the host sends and receives data using cat command on the /dev/ttyGS<N>. The client uses minicom to communicate with the serial gadget. - Mass storage gadget test After connecting the gadget with vhci, use "dd" to test read and write operation on the client side. Read - dd if=/dev/sd<N> iflag=direct of=/dev/null bs=1G count=1 Write - dd if=<my file path> iflag=direct of=/dev/sd<N> bs=1G count=1 Signed-off-by: Suwan Kim <suwan.kim027@gmail.com> Acked-by: Shuah khan <skhan@linuxfoundation.org> Link: https://lore.kernel.org/r/20190828032741.12234-1-suwan.kim027@gmail.com Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2019-08-28 10:27:41 +07:00
error:
dev_err(&urb->dev->dev, "recv xbuf, %d\n", ret);
if (ud->side == USBIP_STUB || ud->side == USBIP_VUDC)
usbip_event_add(ud, SDEV_EVENT_ERROR_TCP);
else
usbip_event_add(ud, VDEV_EVENT_ERROR_TCP);
return -EPIPE;
}
EXPORT_SYMBOL_GPL(usbip_recv_xbuff);
static int __init usbip_core_init(void)
{
usbip: event handler as one thread Dear all, 1. Overview In current USB/IP implementation, event kernel threads are created for each port. The functions of the threads are closing connection and error handling so they don't have not so many events to handle. There's no need to have thread for each port. BEFORE) vhci side - VHCI_NPORTS(8) threads are created. $ ps aux | grep usbip root 10059 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10060 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10061 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10062 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10063 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10064 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10065 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10066 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] BEFORE) stub side - threads will be created every bind operation. $ ps aux | grep usbip root 8368 0.0 0.0 0 0 ? S 17:56 0:00 [usbip_eh] root 8399 0.0 0.0 0 0 ? S 17:56 0:00 [usbip_eh] This patch put event threads of stub and vhci driver as one workqueue. AFTER) only one event threads in each vhci and stub side. $ ps aux | grep usbip root 10457 0.0 0.0 0 0 ? S< 17:47 0:00 [usbip_event] 2. Modification to usbip_event.c BEFORE) kernel threads are created in usbip_start_eh(). AFTER) one workqueue is created in new usbip_init_eh(). Event handler which was main loop of kernel thread is modified to workqueue handler. Events themselves are stored in struct usbip_device - same as before. usbip_devices which have event are listed in event_list. The handler picks an element from the list and wakeup usbip_device. The wakeup method is same as before. usbip_in_eh() substitutes statement which checks whether functions are called from eh_ops or not. In this function, the worker context is used for the checking. The context will be set in a variable in the beginning of first event handling. usbip_in_eh() is used in event handler so it works well. 3. Modifications to programs using usbip_event.c Initialization and termination of workqueue are added to init and exit routine of usbip_core respectively. A. version info v2) # Merged 1/2 event handler itself and 2/2 user programs because of auto build fail at 1/2 casued unmodified user programs in 1/2. Signed-off-by: Nobuo Iwata <nobuo.iwata@fujixerox.co.jp> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2016-03-24 08:50:59 +07:00
int ret;
ret = usbip_init_eh();
if (ret)
return ret;
return 0;
}
static void __exit usbip_core_exit(void)
{
usbip: event handler as one thread Dear all, 1. Overview In current USB/IP implementation, event kernel threads are created for each port. The functions of the threads are closing connection and error handling so they don't have not so many events to handle. There's no need to have thread for each port. BEFORE) vhci side - VHCI_NPORTS(8) threads are created. $ ps aux | grep usbip root 10059 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10060 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10061 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10062 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10063 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10064 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10065 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] root 10066 0.0 0.0 0 0 ? S 17:06 0:00 [usbip_eh] BEFORE) stub side - threads will be created every bind operation. $ ps aux | grep usbip root 8368 0.0 0.0 0 0 ? S 17:56 0:00 [usbip_eh] root 8399 0.0 0.0 0 0 ? S 17:56 0:00 [usbip_eh] This patch put event threads of stub and vhci driver as one workqueue. AFTER) only one event threads in each vhci and stub side. $ ps aux | grep usbip root 10457 0.0 0.0 0 0 ? S< 17:47 0:00 [usbip_event] 2. Modification to usbip_event.c BEFORE) kernel threads are created in usbip_start_eh(). AFTER) one workqueue is created in new usbip_init_eh(). Event handler which was main loop of kernel thread is modified to workqueue handler. Events themselves are stored in struct usbip_device - same as before. usbip_devices which have event are listed in event_list. The handler picks an element from the list and wakeup usbip_device. The wakeup method is same as before. usbip_in_eh() substitutes statement which checks whether functions are called from eh_ops or not. In this function, the worker context is used for the checking. The context will be set in a variable in the beginning of first event handling. usbip_in_eh() is used in event handler so it works well. 3. Modifications to programs using usbip_event.c Initialization and termination of workqueue are added to init and exit routine of usbip_core respectively. A. version info v2) # Merged 1/2 event handler itself and 2/2 user programs because of auto build fail at 1/2 casued unmodified user programs in 1/2. Signed-off-by: Nobuo Iwata <nobuo.iwata@fujixerox.co.jp> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2016-03-24 08:50:59 +07:00
usbip_finish_eh();
return;
}
module_init(usbip_core_init);
module_exit(usbip_core_exit);
MODULE_AUTHOR(DRIVER_AUTHOR);
MODULE_DESCRIPTION(DRIVER_DESC);
MODULE_LICENSE("GPL");