OpenCloudOS-Kernel/drivers/usb/usbip/stub_rx.c

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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2003-2008 Takahiro Hirofuchi
*/
#include <asm/byteorder.h>
#include <linux/kthread.h>
#include <linux/usb.h>
#include <linux/usb/hcd.h>
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 11:27:41 +08:00
#include <linux/scatterlist.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 16:04:11 +08:00
#include "usbip_common.h"
#include "stub.h"
static int is_clear_halt_cmd(struct urb *urb)
{
struct usb_ctrlrequest *req;
req = (struct usb_ctrlrequest *) urb->setup_packet;
return (req->bRequest == USB_REQ_CLEAR_FEATURE) &&
(req->bRequestType == USB_RECIP_ENDPOINT) &&
(req->wValue == USB_ENDPOINT_HALT);
}
static int is_set_interface_cmd(struct urb *urb)
{
struct usb_ctrlrequest *req;
req = (struct usb_ctrlrequest *) urb->setup_packet;
return (req->bRequest == USB_REQ_SET_INTERFACE) &&
(req->bRequestType == USB_RECIP_INTERFACE);
}
static int is_set_configuration_cmd(struct urb *urb)
{
struct usb_ctrlrequest *req;
req = (struct usb_ctrlrequest *) urb->setup_packet;
return (req->bRequest == USB_REQ_SET_CONFIGURATION) &&
(req->bRequestType == USB_RECIP_DEVICE);
}
static int is_reset_device_cmd(struct urb *urb)
{
struct usb_ctrlrequest *req;
__u16 value;
__u16 index;
req = (struct usb_ctrlrequest *) urb->setup_packet;
value = le16_to_cpu(req->wValue);
index = le16_to_cpu(req->wIndex);
if ((req->bRequest == USB_REQ_SET_FEATURE) &&
(req->bRequestType == USB_RT_PORT) &&
(value == USB_PORT_FEAT_RESET)) {
usbip_dbg_stub_rx("reset_device_cmd, port %u\n", index);
return 1;
} else
return 0;
}
static int tweak_clear_halt_cmd(struct urb *urb)
{
struct usb_ctrlrequest *req;
int target_endp;
int target_dir;
int target_pipe;
int ret;
req = (struct usb_ctrlrequest *) urb->setup_packet;
/*
* The stalled endpoint is specified in the wIndex value. The endpoint
* of the urb is the target of this clear_halt request (i.e., control
* endpoint).
*/
target_endp = le16_to_cpu(req->wIndex) & 0x000f;
/* the stalled endpoint direction is IN or OUT?. USB_DIR_IN is 0x80. */
target_dir = le16_to_cpu(req->wIndex) & 0x0080;
if (target_dir)
target_pipe = usb_rcvctrlpipe(urb->dev, target_endp);
else
target_pipe = usb_sndctrlpipe(urb->dev, target_endp);
ret = usb_clear_halt(urb->dev, target_pipe);
if (ret < 0)
dev_err(&urb->dev->dev,
"usb_clear_halt error: devnum %d endp %d ret %d\n",
urb->dev->devnum, target_endp, ret);
else
dev_info(&urb->dev->dev,
"usb_clear_halt done: devnum %d endp %d\n",
urb->dev->devnum, target_endp);
return ret;
}
static int tweak_set_interface_cmd(struct urb *urb)
{
struct usb_ctrlrequest *req;
__u16 alternate;
__u16 interface;
int ret;
req = (struct usb_ctrlrequest *) urb->setup_packet;
alternate = le16_to_cpu(req->wValue);
interface = le16_to_cpu(req->wIndex);
usbip_dbg_stub_rx("set_interface: inf %u alt %u\n",
interface, alternate);
ret = usb_set_interface(urb->dev, interface, alternate);
if (ret < 0)
dev_err(&urb->dev->dev,
"usb_set_interface error: inf %u alt %u ret %d\n",
interface, alternate, ret);
else
dev_info(&urb->dev->dev,
"usb_set_interface done: inf %u alt %u\n",
interface, alternate);
return ret;
}
static int tweak_set_configuration_cmd(struct urb *urb)
{
struct stub_priv *priv = (struct stub_priv *) urb->context;
struct stub_device *sdev = priv->sdev;
struct usb_ctrlrequest *req;
__u16 config;
int err;
req = (struct usb_ctrlrequest *) urb->setup_packet;
config = le16_to_cpu(req->wValue);
err = usb_set_configuration(sdev->udev, config);
if (err && err != -ENODEV)
dev_err(&sdev->udev->dev, "can't set config #%d, error %d\n",
config, err);
return 0;
}
static int tweak_reset_device_cmd(struct urb *urb)
{
struct stub_priv *priv = (struct stub_priv *) urb->context;
struct stub_device *sdev = priv->sdev;
dev_info(&urb->dev->dev, "usb_queue_reset_device\n");
if (usb_lock_device_for_reset(sdev->udev, NULL) < 0) {
dev_err(&urb->dev->dev, "could not obtain lock to reset device\n");
return 0;
}
usb_reset_device(sdev->udev);
usb_unlock_device(sdev->udev);
return 0;
}
/*
* clear_halt, set_interface, and set_configuration require special tricks.
*/
static void tweak_special_requests(struct urb *urb)
{
if (!urb || !urb->setup_packet)
return;
if (usb_pipetype(urb->pipe) != PIPE_CONTROL)
return;
if (is_clear_halt_cmd(urb))
/* tweak clear_halt */
tweak_clear_halt_cmd(urb);
else if (is_set_interface_cmd(urb))
/* tweak set_interface */
tweak_set_interface_cmd(urb);
else if (is_set_configuration_cmd(urb))
/* tweak set_configuration */
tweak_set_configuration_cmd(urb);
else if (is_reset_device_cmd(urb))
tweak_reset_device_cmd(urb);
else
usbip_dbg_stub_rx("no need to tweak\n");
}
/*
* stub_recv_unlink() unlinks the URB by a call to usb_unlink_urb().
* By unlinking the urb asynchronously, stub_rx can continuously
* process coming urbs. Even if the urb is unlinked, its completion
* handler will be called and stub_tx will send a return pdu.
*
* See also comments about unlinking strategy in vhci_hcd.c.
*/
static int stub_recv_cmd_unlink(struct stub_device *sdev,
struct usbip_header *pdu)
{
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 11:27:41 +08:00
int ret, i;
unsigned long flags;
struct stub_priv *priv;
spin_lock_irqsave(&sdev->priv_lock, flags);
list_for_each_entry(priv, &sdev->priv_init, list) {
if (priv->seqnum != pdu->u.cmd_unlink.seqnum)
continue;
/*
* This matched urb is not completed yet (i.e., be in
* flight in usb hcd hardware/driver). Now we are
* cancelling it. The unlinking flag means that we are
* now not going to return the normal result pdu of a
* submission request, but going to return a result pdu
* of the unlink request.
*/
priv->unlinking = 1;
/*
* In the case that unlinking flag is on, prev->seqnum
* is changed from the seqnum of the cancelling urb to
* the seqnum of the unlink request. This will be used
* to make the result pdu of the unlink request.
*/
priv->seqnum = pdu->base.seqnum;
spin_unlock_irqrestore(&sdev->priv_lock, flags);
/*
* usb_unlink_urb() is now out of spinlocking to avoid
* spinlock recursion since stub_complete() is
* sometimes called in this context but not in the
* interrupt context. If stub_complete() is executed
* before we call usb_unlink_urb(), usb_unlink_urb()
* will return an error value. In this case, stub_tx
* will return the result pdu of this unlink request
* though submission is completed and actual unlinking
* is not executed. OK?
*/
/* In the above case, urb->status is not -ECONNRESET,
* so a driver in a client host will know the failure
* of the unlink request ?
*/
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 11:27:41 +08:00
for (i = priv->completed_urbs; i < priv->num_urbs; i++) {
ret = usb_unlink_urb(priv->urbs[i]);
if (ret != -EINPROGRESS)
dev_err(&priv->urbs[i]->dev->dev,
"failed to unlink %d/%d urb of seqnum %lu, ret %d\n",
i + 1, priv->num_urbs,
priv->seqnum, ret);
}
return 0;
}
usbip_dbg_stub_rx("seqnum %d is not pending\n",
pdu->u.cmd_unlink.seqnum);
/*
* The urb of the unlink target is not found in priv_init queue. It was
* already completed and its results is/was going to be sent by a
* CMD_RET pdu. In this case, usb_unlink_urb() is not needed. We only
* return the completeness of this unlink request to vhci_hcd.
*/
stub_enqueue_ret_unlink(sdev, pdu->base.seqnum, 0);
spin_unlock_irqrestore(&sdev->priv_lock, flags);
return 0;
}
static int valid_request(struct stub_device *sdev, struct usbip_header *pdu)
{
struct usbip_device *ud = &sdev->ud;
int valid = 0;
if (pdu->base.devid == sdev->devid) {
spin_lock_irq(&ud->lock);
if (ud->status == SDEV_ST_USED) {
/* A request is valid. */
valid = 1;
}
spin_unlock_irq(&ud->lock);
}
return valid;
}
static struct stub_priv *stub_priv_alloc(struct stub_device *sdev,
struct usbip_header *pdu)
{
struct stub_priv *priv;
struct usbip_device *ud = &sdev->ud;
unsigned long flags;
spin_lock_irqsave(&sdev->priv_lock, flags);
priv = kmem_cache_zalloc(stub_priv_cache, GFP_ATOMIC);
if (!priv) {
dev_err(&sdev->udev->dev, "alloc stub_priv\n");
spin_unlock_irqrestore(&sdev->priv_lock, flags);
usbip_event_add(ud, SDEV_EVENT_ERROR_MALLOC);
return NULL;
}
priv->seqnum = pdu->base.seqnum;
priv->sdev = sdev;
/*
* After a stub_priv is linked to a list_head,
* our error handler can free allocated data.
*/
list_add_tail(&priv->list, &sdev->priv_init);
spin_unlock_irqrestore(&sdev->priv_lock, flags);
return priv;
}
static int get_pipe(struct stub_device *sdev, struct usbip_header *pdu)
{
staging: usbip: stub: update refcounts for devices and interfaces The stub driver expects to access the usb interface and usb device structures even if the device has been disconnected in the meantime. This change gets a reference to them in the stub probe function using usb_get_intf()/usb_get_dev() and drops them in the disconnect function. This fixes an oops observed with a Logic Controls Line display (0fa8:a030) which disconnects itself when it is reset: [ 1348.562274] BUG: unable to handle kernel paging request at 5f7433e5 [ 1348.562327] IP: [<c0393b02>] usb_lock_device_for_reset+0x22/0xd0 [ 1348.562374] *pde = 00000000 [ 1348.562397] Oops: 0000 [#1] [ 1348.562418] last sysfs file: /sys/devices/pci0000:00/0000:00:10.2/usb4/4-1/bConfigurationValue [ 1348.562454] Modules linked in: usbip vhci_hcd usbip_common_mod fbcon tileblit font bitblit softcursor serio_raw uvesafb pcspkr via_rng snd_via82xx gameport snd_ac97_codec ac97_bus snd_pcm_oss snd_mixer_oss snd_pcm snd_page_alloc snd_mpu401_uart snd_rawmidi snd_seq_oss snd_seq_midi_event snd_seq snd_timer snd_seq_device snd usbhid hid via_rhine soundcore mii igel_flash aufs pata_via [ 1348.562649] [ 1348.562670] Pid: 2855, comm: usbip_eh Not tainted (2.6.32 #23.37-ud-r113) M300C [ 1348.562704] EIP: 0060:[<c0393b02>] EFLAGS: 00010216 CPU: 0 [ 1348.562734] EIP is at usb_lock_device_for_reset+0x22/0xd0 [ 1348.562762] EAX: 5f7433cd EBX: 5f7433cd ECX: de293a5c EDX: dd326a00 [ 1348.562793] ESI: 5f7433cd EDI: 000400f6 EBP: cf43ff48 ESP: cf43ff38 [ 1348.562824] DS: 007b ES: 007b FS: 0000 GS: 00e0 SS: 0068 [ 1348.562854] Process usbip_eh (pid: 2855, ti=cf43e000 task=d2c7f230 task.ti=cf43e000) [ 1348.562884] Stack: [ 1348.562900] d6ec9960 de2939cc 5f7433cd 5f743431 cf43ff70 df8fd32f de2939cc d2c7f230 [ 1348.562940] <0> cf43ff70 00000282 00000282 de2939cc d2c7f230 d2c7f230 cf43ffa8 df84416d [ 1348.562987] <0> cf43ff88 d2c7f230 de293a24 d2c7f230 00000000 d2c7f230 c014e760 cf43ff94 [ 1348.563042] Call Trace: [ 1348.563073] [<df8fd32f>] ? stub_device_reset+0x3f/0x110 [usbip] [ 1348.563114] [<df84416d>] ? event_handler_loop+0xcd/0xe8 [usbip_common_mod] [ 1348.563156] [<c014e760>] ? autoremove_wake_function+0x0/0x50 [ 1348.563193] [<df843d80>] ? usbip_thread+0x0/0x60 [usbip_common_mod] [ 1348.563230] [<df843dd1>] ? usbip_thread+0x51/0x60 [usbip_common_mod] [ 1348.563265] [<c014e374>] ? kthread+0x74/0x80 [ 1348.563294] [<c014e300>] ? kthread+0x0/0x80 [ 1348.563326] [<c0103c47>] ? kernel_thread_helper+0x7/0x10 [ 1348.563351] Code: 00 e8 73 4d 00 00 5d c3 90 55 89 e5 83 ec 10 89 5d f4 89 75 f8 89 7d fc 0f 1f 44 00 00 8b 3d c0 2e 67 c0 81 c7 fa 00 00 00 89 c3 <8b> 40 18 89 d6 85 c0 75 15 b8 ed ff ff ff 8b 5d f4 8b 75 f8 8b [ 1348.563528] EIP: [<c0393b02>] usb_lock_device_for_reset+0x22/0xd0 SS:ESP 0068:cf43ff38 [ 1348.563570] CR2: 000000005f7433e5 [ 1348.563593] ---[ end trace 9c3f1e3a2e5299d9 ]--- Signed-off-by: Max Vozeler <max@vozeler.com> Tested-by: Mark Wehby <MWehby@luxotticaRetail.com> Tested-by: Steven Harms <sharms@luxotticaRetail.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-01-12 21:01:59 +08:00
struct usb_device *udev = sdev->udev;
struct usb_host_endpoint *ep;
struct usb_endpoint_descriptor *epd = NULL;
int epnum = pdu->base.ep;
int dir = pdu->base.direction;
if (epnum < 0 || epnum > 15)
goto err_ret;
if (dir == USBIP_DIR_IN)
ep = udev->ep_in[epnum & 0x7f];
else
ep = udev->ep_out[epnum & 0x7f];
if (!ep)
goto err_ret;
epd = &ep->desc;
if (usb_endpoint_xfer_control(epd)) {
if (dir == USBIP_DIR_OUT)
return usb_sndctrlpipe(udev, epnum);
else
return usb_rcvctrlpipe(udev, epnum);
}
if (usb_endpoint_xfer_bulk(epd)) {
if (dir == USBIP_DIR_OUT)
return usb_sndbulkpipe(udev, epnum);
else
return usb_rcvbulkpipe(udev, epnum);
}
if (usb_endpoint_xfer_int(epd)) {
if (dir == USBIP_DIR_OUT)
return usb_sndintpipe(udev, epnum);
else
return usb_rcvintpipe(udev, epnum);
}
if (usb_endpoint_xfer_isoc(epd)) {
/* validate number of packets */
if (pdu->u.cmd_submit.number_of_packets < 0 ||
pdu->u.cmd_submit.number_of_packets >
USBIP_MAX_ISO_PACKETS) {
dev_err(&sdev->udev->dev,
"CMD_SUBMIT: isoc invalid num packets %d\n",
pdu->u.cmd_submit.number_of_packets);
return -1;
}
if (dir == USBIP_DIR_OUT)
return usb_sndisocpipe(udev, epnum);
else
return usb_rcvisocpipe(udev, epnum);
}
err_ret:
/* NOT REACHED */
dev_err(&sdev->udev->dev, "CMD_SUBMIT: invalid epnum %d\n", epnum);
return -1;
}
static void masking_bogus_flags(struct urb *urb)
{
int xfertype;
struct usb_device *dev;
struct usb_host_endpoint *ep;
int is_out;
unsigned int allowed;
if (!urb || urb->hcpriv || !urb->complete)
return;
dev = urb->dev;
if ((!dev) || (dev->state < USB_STATE_UNAUTHENTICATED))
return;
ep = (usb_pipein(urb->pipe) ? dev->ep_in : dev->ep_out)
[usb_pipeendpoint(urb->pipe)];
if (!ep)
return;
xfertype = usb_endpoint_type(&ep->desc);
if (xfertype == USB_ENDPOINT_XFER_CONTROL) {
struct usb_ctrlrequest *setup =
(struct usb_ctrlrequest *) urb->setup_packet;
if (!setup)
return;
is_out = !(setup->bRequestType & USB_DIR_IN) ||
!setup->wLength;
} else {
is_out = usb_endpoint_dir_out(&ep->desc);
}
/* enforce simple/standard policy */
allowed = (URB_NO_TRANSFER_DMA_MAP | URB_NO_INTERRUPT |
URB_DIR_MASK | URB_FREE_BUFFER);
switch (xfertype) {
case USB_ENDPOINT_XFER_BULK:
if (is_out)
allowed |= URB_ZERO_PACKET;
fallthrough;
default: /* all non-iso endpoints */
if (!is_out)
allowed |= URB_SHORT_NOT_OK;
break;
case USB_ENDPOINT_XFER_ISOC:
allowed |= URB_ISO_ASAP;
break;
}
urb->transfer_flags &= allowed;
}
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 11:27:41 +08:00
static int stub_recv_xbuff(struct usbip_device *ud, struct stub_priv *priv)
{
int ret;
int i;
for (i = 0; i < priv->num_urbs; i++) {
ret = usbip_recv_xbuff(ud, priv->urbs[i]);
if (ret < 0)
break;
}
return ret;
}
static void stub_recv_cmd_submit(struct stub_device *sdev,
struct usbip_header *pdu)
{
struct stub_priv *priv;
struct usbip_device *ud = &sdev->ud;
staging: usbip: stub: update refcounts for devices and interfaces The stub driver expects to access the usb interface and usb device structures even if the device has been disconnected in the meantime. This change gets a reference to them in the stub probe function using usb_get_intf()/usb_get_dev() and drops them in the disconnect function. This fixes an oops observed with a Logic Controls Line display (0fa8:a030) which disconnects itself when it is reset: [ 1348.562274] BUG: unable to handle kernel paging request at 5f7433e5 [ 1348.562327] IP: [<c0393b02>] usb_lock_device_for_reset+0x22/0xd0 [ 1348.562374] *pde = 00000000 [ 1348.562397] Oops: 0000 [#1] [ 1348.562418] last sysfs file: /sys/devices/pci0000:00/0000:00:10.2/usb4/4-1/bConfigurationValue [ 1348.562454] Modules linked in: usbip vhci_hcd usbip_common_mod fbcon tileblit font bitblit softcursor serio_raw uvesafb pcspkr via_rng snd_via82xx gameport snd_ac97_codec ac97_bus snd_pcm_oss snd_mixer_oss snd_pcm snd_page_alloc snd_mpu401_uart snd_rawmidi snd_seq_oss snd_seq_midi_event snd_seq snd_timer snd_seq_device snd usbhid hid via_rhine soundcore mii igel_flash aufs pata_via [ 1348.562649] [ 1348.562670] Pid: 2855, comm: usbip_eh Not tainted (2.6.32 #23.37-ud-r113) M300C [ 1348.562704] EIP: 0060:[<c0393b02>] EFLAGS: 00010216 CPU: 0 [ 1348.562734] EIP is at usb_lock_device_for_reset+0x22/0xd0 [ 1348.562762] EAX: 5f7433cd EBX: 5f7433cd ECX: de293a5c EDX: dd326a00 [ 1348.562793] ESI: 5f7433cd EDI: 000400f6 EBP: cf43ff48 ESP: cf43ff38 [ 1348.562824] DS: 007b ES: 007b FS: 0000 GS: 00e0 SS: 0068 [ 1348.562854] Process usbip_eh (pid: 2855, ti=cf43e000 task=d2c7f230 task.ti=cf43e000) [ 1348.562884] Stack: [ 1348.562900] d6ec9960 de2939cc 5f7433cd 5f743431 cf43ff70 df8fd32f de2939cc d2c7f230 [ 1348.562940] <0> cf43ff70 00000282 00000282 de2939cc d2c7f230 d2c7f230 cf43ffa8 df84416d [ 1348.562987] <0> cf43ff88 d2c7f230 de293a24 d2c7f230 00000000 d2c7f230 c014e760 cf43ff94 [ 1348.563042] Call Trace: [ 1348.563073] [<df8fd32f>] ? stub_device_reset+0x3f/0x110 [usbip] [ 1348.563114] [<df84416d>] ? event_handler_loop+0xcd/0xe8 [usbip_common_mod] [ 1348.563156] [<c014e760>] ? autoremove_wake_function+0x0/0x50 [ 1348.563193] [<df843d80>] ? usbip_thread+0x0/0x60 [usbip_common_mod] [ 1348.563230] [<df843dd1>] ? usbip_thread+0x51/0x60 [usbip_common_mod] [ 1348.563265] [<c014e374>] ? kthread+0x74/0x80 [ 1348.563294] [<c014e300>] ? kthread+0x0/0x80 [ 1348.563326] [<c0103c47>] ? kernel_thread_helper+0x7/0x10 [ 1348.563351] Code: 00 e8 73 4d 00 00 5d c3 90 55 89 e5 83 ec 10 89 5d f4 89 75 f8 89 7d fc 0f 1f 44 00 00 8b 3d c0 2e 67 c0 81 c7 fa 00 00 00 89 c3 <8b> 40 18 89 d6 85 c0 75 15 b8 ed ff ff ff 8b 5d f4 8b 75 f8 8b [ 1348.563528] EIP: [<c0393b02>] usb_lock_device_for_reset+0x22/0xd0 SS:ESP 0068:cf43ff38 [ 1348.563570] CR2: 000000005f7433e5 [ 1348.563593] ---[ end trace 9c3f1e3a2e5299d9 ]--- Signed-off-by: Max Vozeler <max@vozeler.com> Tested-by: Mark Wehby <MWehby@luxotticaRetail.com> Tested-by: Steven Harms <sharms@luxotticaRetail.com> Signed-off-by: Greg Kroah-Hartman <gregkh@suse.de>
2011-01-12 21:01:59 +08:00
struct usb_device *udev = sdev->udev;
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 11:27:41 +08:00
struct scatterlist *sgl = NULL, *sg;
void *buffer = NULL;
unsigned long long buf_len;
int nents;
int num_urbs = 1;
int pipe = get_pipe(sdev, pdu);
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 11:27:41 +08:00
int use_sg = pdu->u.cmd_submit.transfer_flags & URB_DMA_MAP_SG;
int support_sg = 1;
int np = 0;
int ret, i;
if (pipe == -1)
return;
/*
* Smatch reported the error case where use_sg is true and buf_len is 0.
* In this case, It adds SDEV_EVENT_ERROR_MALLOC and stub_priv will be
* released by stub event handler and connection will be shut down.
*/
priv = stub_priv_alloc(sdev, pdu);
if (!priv)
return;
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 11:27:41 +08:00
buf_len = (unsigned long long)pdu->u.cmd_submit.transfer_buffer_length;
if (use_sg && !buf_len) {
dev_err(&udev->dev, "sg buffer with zero length\n");
goto err_malloc;
}
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 11:27:41 +08:00
/* allocate urb transfer buffer, if needed */
if (buf_len) {
if (use_sg) {
sgl = sgl_alloc(buf_len, GFP_KERNEL, &nents);
if (!sgl)
goto err_malloc;
/* Check if the server's HCD supports SG */
if (!udev->bus->sg_tablesize) {
/*
* If the server's HCD doesn't support SG, break
* a single SG request into several URBs and map
* each SG list entry to corresponding URB
* buffer. The previously allocated SG list is
* stored in priv->sgl (If the server's HCD
* support SG, SG list is stored only in
* urb->sg) and it is used as an indicator that
* the server split single SG request into
* several URBs. Later, priv->sgl is used by
* stub_complete() and stub_send_ret_submit() to
* reassemble the divied URBs.
*/
support_sg = 0;
num_urbs = nents;
priv->completed_urbs = 0;
pdu->u.cmd_submit.transfer_flags &=
~URB_DMA_MAP_SG;
}
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 11:27:41 +08:00
} else {
buffer = kzalloc(buf_len, GFP_KERNEL);
if (!buffer)
goto err_malloc;
}
}
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 11:27:41 +08:00
/* allocate urb array */
priv->num_urbs = num_urbs;
priv->urbs = kmalloc_array(num_urbs, sizeof(*priv->urbs), GFP_KERNEL);
if (!priv->urbs)
goto err_urbs;
/* setup a urb */
if (support_sg) {
if (usb_pipeisoc(pipe))
np = pdu->u.cmd_submit.number_of_packets;
priv->urbs[0] = usb_alloc_urb(np, GFP_KERNEL);
if (!priv->urbs[0])
goto err_urb;
if (buf_len) {
if (use_sg) {
priv->urbs[0]->sg = sgl;
priv->urbs[0]->num_sgs = nents;
priv->urbs[0]->transfer_buffer = NULL;
} else {
priv->urbs[0]->transfer_buffer = buffer;
}
}
/* copy urb setup packet */
priv->urbs[0]->setup_packet = kmemdup(&pdu->u.cmd_submit.setup,
8, GFP_KERNEL);
if (!priv->urbs[0]->setup_packet) {
usbip_event_add(ud, SDEV_EVENT_ERROR_MALLOC);
return;
}
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 11:27:41 +08:00
usbip_pack_pdu(pdu, priv->urbs[0], USBIP_CMD_SUBMIT, 0);
} else {
for_each_sg(sgl, sg, nents, i) {
priv->urbs[i] = usb_alloc_urb(0, GFP_KERNEL);
/* The URBs which is previously allocated will be freed
* in stub_device_cleanup_urbs() if error occurs.
*/
if (!priv->urbs[i])
goto err_urb;
usbip_pack_pdu(pdu, priv->urbs[i], USBIP_CMD_SUBMIT, 0);
priv->urbs[i]->transfer_buffer = sg_virt(sg);
priv->urbs[i]->transfer_buffer_length = sg->length;
}
priv->sgl = sgl;
}
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 11:27:41 +08:00
for (i = 0; i < num_urbs; i++) {
/* set other members from the base header of pdu */
priv->urbs[i]->context = (void *) priv;
priv->urbs[i]->dev = udev;
priv->urbs[i]->pipe = pipe;
priv->urbs[i]->complete = stub_complete;
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 11:27:41 +08:00
/* no need to submit an intercepted request, but harmless? */
tweak_special_requests(priv->urbs[i]);
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 11:27:41 +08:00
masking_bogus_flags(priv->urbs[i]);
}
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 11:27:41 +08:00
if (stub_recv_xbuff(ud, priv) < 0)
return;
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 11:27:41 +08:00
if (usbip_recv_iso(ud, priv->urbs[0]) < 0)
return;
/* urb is now ready to submit */
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 11:27:41 +08:00
for (i = 0; i < priv->num_urbs; i++) {
ret = usb_submit_urb(priv->urbs[i], GFP_KERNEL);
if (ret == 0)
usbip_dbg_stub_rx("submit urb ok, seqnum %u\n",
pdu->base.seqnum);
else {
dev_err(&udev->dev, "submit_urb error, %d\n", ret);
usbip_dump_header(pdu);
usbip_dump_urb(priv->urbs[i]);
/*
* Pessimistic.
* This connection will be discarded.
*/
usbip_event_add(ud, SDEV_EVENT_ERROR_SUBMIT);
break;
}
}
usbip_dbg_stub_rx("Leave\n");
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 11:27:41 +08:00
return;
err_urb:
kfree(priv->urbs);
err_urbs:
kfree(buffer);
sgl_free(sgl);
err_malloc:
usbip_event_add(ud, SDEV_EVENT_ERROR_MALLOC);
}
/* recv a pdu */
static void stub_rx_pdu(struct usbip_device *ud)
{
int ret;
struct usbip_header pdu;
struct stub_device *sdev = container_of(ud, struct stub_device, ud);
struct device *dev = &sdev->udev->dev;
usbip_dbg_stub_rx("Enter\n");
memset(&pdu, 0, sizeof(pdu));
/* receive a pdu header */
ret = usbip_recv(ud->tcp_socket, &pdu, sizeof(pdu));
if (ret != sizeof(pdu)) {
dev_err(dev, "recv a header, %d\n", ret);
usbip_event_add(ud, SDEV_EVENT_ERROR_TCP);
return;
}
usbip_header_correct_endian(&pdu, 0);
if (usbip_dbg_flag_stub_rx)
usbip_dump_header(&pdu);
if (!valid_request(sdev, &pdu)) {
dev_err(dev, "recv invalid request\n");
usbip_event_add(ud, SDEV_EVENT_ERROR_TCP);
return;
}
switch (pdu.base.command) {
case USBIP_CMD_UNLINK:
stub_recv_cmd_unlink(sdev, &pdu);
break;
case USBIP_CMD_SUBMIT:
stub_recv_cmd_submit(sdev, &pdu);
break;
default:
/* NOTREACHED */
dev_err(dev, "unknown pdu\n");
usbip_event_add(ud, SDEV_EVENT_ERROR_TCP);
break;
}
}
int stub_rx_loop(void *data)
{
struct usbip_device *ud = data;
while (!kthread_should_stop()) {
if (usbip_event_happened(ud))
break;
stub_rx_pdu(ud);
}
return 0;
}