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/*
* Haiku Backend for libusb
* Copyright © 2014 Akshay Jaggi <akshay1994.leo@gmail.com>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#include <unistd.h>
#include <string.h>
#include <stdlib.h>
#include <new>
#include <vector>
#include "haiku_usb.h"
static int _errno_to_libusb(int status)
{
return status;
}
USBTransfer::USBTransfer(struct usbi_transfer *itransfer, USBDevice *device)
{
fUsbiTransfer = itransfer;
fLibusbTransfer = USBI_TRANSFER_TO_LIBUSB_TRANSFER(itransfer);
fUSBDevice = device;
fCancelled = false;
}
USBTransfer::~USBTransfer()
{
}
struct usbi_transfer *
USBTransfer::UsbiTransfer()
{
return fUsbiTransfer;
}
void
USBTransfer::SetCancelled()
{
fCancelled = true;
}
bool
USBTransfer::IsCancelled()
{
return fCancelled;
}
void
USBTransfer::Do(int fRawFD)
{
switch (fLibusbTransfer->type) {
case LIBUSB_TRANSFER_TYPE_CONTROL:
{
struct libusb_control_setup *setup = (struct libusb_control_setup *)fLibusbTransfer->buffer;
usb_raw_command command;
command.control.request_type = setup->bmRequestType;
command.control.request = setup->bRequest;
command.control.value = setup->wValue;
command.control.index = setup->wIndex;
command.control.length = setup->wLength;
command.control.data = fLibusbTransfer->buffer + LIBUSB_CONTROL_SETUP_SIZE;
if (fCancelled)
break;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_CONTROL_TRANSFER, &command, sizeof(command)) ||
command.control.status != B_USB_RAW_STATUS_SUCCESS) {
fUsbiTransfer->transferred = -1;
usbi_err(TRANSFER_CTX(fLibusbTransfer), "failed control transfer");
break;
}
fUsbiTransfer->transferred = command.control.length;
}
break;
case LIBUSB_TRANSFER_TYPE_BULK:
case LIBUSB_TRANSFER_TYPE_INTERRUPT:
{
usb_raw_command command;
command.transfer.interface = fUSBDevice->EndpointToInterface(fLibusbTransfer->endpoint);
command.transfer.endpoint = fUSBDevice->EndpointToIndex(fLibusbTransfer->endpoint);
command.transfer.data = fLibusbTransfer->buffer;
command.transfer.length = fLibusbTransfer->length;
if (fCancelled)
break;
if (fLibusbTransfer->type == LIBUSB_TRANSFER_TYPE_BULK) {
if (ioctl(fRawFD, B_USB_RAW_COMMAND_BULK_TRANSFER, &command, sizeof(command)) ||
command.transfer.status != B_USB_RAW_STATUS_SUCCESS) {
fUsbiTransfer->transferred = -1;
usbi_err(TRANSFER_CTX(fLibusbTransfer), "failed bulk transfer");
break;
}
}
else {
if (ioctl(fRawFD, B_USB_RAW_COMMAND_INTERRUPT_TRANSFER, &command, sizeof(command)) ||
command.transfer.status != B_USB_RAW_STATUS_SUCCESS) {
fUsbiTransfer->transferred = -1;
usbi_err(TRANSFER_CTX(fLibusbTransfer), "failed interrupt transfer");
break;
}
}
fUsbiTransfer->transferred = command.transfer.length;
}
break;
// IsochronousTransfers not tested
case LIBUSB_TRANSFER_TYPE_ISOCHRONOUS:
{
usb_raw_command command;
command.isochronous.interface = fUSBDevice->EndpointToInterface(fLibusbTransfer->endpoint);
command.isochronous.endpoint = fUSBDevice->EndpointToIndex(fLibusbTransfer->endpoint);
command.isochronous.data = fLibusbTransfer->buffer;
command.isochronous.length = fLibusbTransfer->length;
command.isochronous.packet_count = fLibusbTransfer->num_iso_packets;
int i;
usb_iso_packet_descriptor *packetDescriptors = new usb_iso_packet_descriptor[fLibusbTransfer->num_iso_packets];
for (i = 0; i < fLibusbTransfer->num_iso_packets; i++) {
if ((fLibusbTransfer->iso_packet_desc[i]).length > (unsigned int)INT16_MAX) {
fUsbiTransfer->transferred = -1;
usbi_err(TRANSFER_CTX(fLibusbTransfer), "failed isochronous transfer");
break;
}
packetDescriptors[i].request_length = (int16)(fLibusbTransfer->iso_packet_desc[i]).length;
}
if (i < fLibusbTransfer->num_iso_packets)
break; // TODO Handle this error
command.isochronous.packet_descriptors = packetDescriptors;
if (fCancelled)
break;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_ISOCHRONOUS_TRANSFER, &command, sizeof(command)) ||
command.isochronous.status != B_USB_RAW_STATUS_SUCCESS) {
fUsbiTransfer->transferred = -1;
usbi_err(TRANSFER_CTX(fLibusbTransfer), "failed isochronous transfer");
break;
}
for (i = 0; i < fLibusbTransfer->num_iso_packets; i++) {
(fLibusbTransfer->iso_packet_desc[i]).actual_length = packetDescriptors[i].actual_length;
switch (packetDescriptors[i].status) {
case B_OK:
(fLibusbTransfer->iso_packet_desc[i]).status = LIBUSB_TRANSFER_COMPLETED;
break;
default:
(fLibusbTransfer->iso_packet_desc[i]).status = LIBUSB_TRANSFER_ERROR;
break;
}
}
delete[] packetDescriptors;
// Do we put the length of transfer here, for isochronous transfers?
fUsbiTransfer->transferred = command.transfer.length;
}
break;
default:
usbi_err(TRANSFER_CTX(fLibusbTransfer), "Unknown type of transfer");
}
}
bool
USBDeviceHandle::InitCheck()
{
return fInitCheck;
}
status_t
USBDeviceHandle::TransfersThread(void *self)
{
USBDeviceHandle *handle = (USBDeviceHandle *)self;
handle->TransfersWorker();
return B_OK;
}
void
USBDeviceHandle::TransfersWorker()
{
while (true) {
status_t status = acquire_sem(fTransfersSem);
if (status == B_BAD_SEM_ID)
break;
if (status == B_INTERRUPTED)
continue;
fTransfersLock.Lock();
USBTransfer *fPendingTransfer = (USBTransfer *) fTransfers.RemoveItem((int32)0);
fTransfersLock.Unlock();
fPendingTransfer->Do(fRawFD);
usbi_signal_transfer_completion(fPendingTransfer->UsbiTransfer());
}
}
status_t
USBDeviceHandle::SubmitTransfer(struct usbi_transfer *itransfer)
{
USBTransfer *transfer = new USBTransfer(itransfer, fUSBDevice);
*((USBTransfer **)usbi_get_transfer_priv(itransfer)) = transfer;
BAutolock locker(fTransfersLock);
fTransfers.AddItem(transfer);
release_sem(fTransfersSem);
return LIBUSB_SUCCESS;
}
status_t
USBDeviceHandle::CancelTransfer(USBTransfer *transfer)
{
transfer->SetCancelled();
fTransfersLock.Lock();
bool removed = fTransfers.RemoveItem(transfer);
fTransfersLock.Unlock();
if (removed)
usbi_signal_transfer_completion(transfer->UsbiTransfer());
return LIBUSB_SUCCESS;
}
USBDeviceHandle::USBDeviceHandle(USBDevice *dev)
:
fUSBDevice(dev),
fClaimedInterfaces(0),
fTransfersThread(-1),
fInitCheck(false)
{
fRawFD = open(dev->Location(), O_RDWR | O_CLOEXEC);
if (fRawFD < 0) {
usbi_err(NULL,"failed to open device");
return;
}
fTransfersSem = create_sem(0, "Transfers Queue Sem");
fTransfersThread = spawn_thread(TransfersThread, "Transfer Worker", B_NORMAL_PRIORITY, this);
resume_thread(fTransfersThread);
fInitCheck = true;
}
USBDeviceHandle::~USBDeviceHandle()
{
if (fRawFD > 0)
close(fRawFD);
for (int i = 0; i < 32; i++) {
if (fClaimedInterfaces & (1U << i))
ReleaseInterface(i);
}
delete_sem(fTransfersSem);
if (fTransfersThread > 0)
wait_for_thread(fTransfersThread, NULL);
}
int
USBDeviceHandle::ClaimInterface(uint8 inumber)
{
int status = fUSBDevice->ClaimInterface(inumber);
if (status == LIBUSB_SUCCESS)
fClaimedInterfaces |= (1U << inumber);
return status;
}
int
USBDeviceHandle::ReleaseInterface(uint8 inumber)
{
fUSBDevice->ReleaseInterface(inumber);
fClaimedInterfaces &= ~(1U << inumber);
return LIBUSB_SUCCESS;
}
int
USBDeviceHandle::SetConfiguration(uint8 config)
{
int config_index = fUSBDevice->CheckInterfacesFree(config);
if (config_index == LIBUSB_ERROR_BUSY || config_index == LIBUSB_ERROR_NOT_FOUND)
return config_index;
usb_raw_command command;
command.config.config_index = config_index;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_SET_CONFIGURATION, &command, sizeof(command)) ||
command.config.status != B_USB_RAW_STATUS_SUCCESS) {
return _errno_to_libusb(command.config.status);
}
fUSBDevice->SetActiveConfiguration((uint8)config_index);
return LIBUSB_SUCCESS;
}
int
USBDeviceHandle::SetAltSetting(uint8 inumber, uint8 alt)
{
usb_raw_command command;
command.alternate.config_index = fUSBDevice->ActiveConfigurationIndex();
command.alternate.interface_index = inumber;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_ACTIVE_ALT_INTERFACE_INDEX, &command, sizeof(command)) ||
command.alternate.status != B_USB_RAW_STATUS_SUCCESS) {
usbi_err(NULL, "Error retrieving active alternate interface");
return _errno_to_libusb(command.alternate.status);
}
if (command.alternate.alternate_info == (uint32)alt) {
usbi_dbg("Setting alternate interface successful");
return LIBUSB_SUCCESS;
}
command.alternate.alternate_info = alt;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_SET_ALT_INTERFACE, &command, sizeof(command)) ||
command.alternate.status != B_USB_RAW_STATUS_SUCCESS) { //IF IOCTL FAILS DEVICE DISONNECTED PROBABLY
usbi_err(NULL, "Error setting alternate interface");
return _errno_to_libusb(command.alternate.status);
}
usbi_dbg("Setting alternate interface successful");
return LIBUSB_SUCCESS;
}
int
USBDeviceHandle::ClearHalt(uint8 endpoint)
{
usb_raw_command command;
command.control.request_type = USB_REQTYPE_ENDPOINT_OUT;
command.control.request = USB_REQUEST_CLEAR_FEATURE;
command.control.value = USB_FEATURE_ENDPOINT_HALT;
command.control.index = endpoint;
command.control.length = 0;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_CONTROL_TRANSFER, &command, sizeof(command)) ||
command.control.status != B_USB_RAW_STATUS_SUCCESS) {
return _errno_to_libusb(command.control.status);
}
return LIBUSB_SUCCESS;
}
USBDevice::USBDevice(const char *path)
:
fClaimedInterfaces(0),
fConfigurationDescriptors(NULL),
fActiveConfiguration(0), //0?
fPath(NULL),
fEndpointToIndex(NULL),
fEndpointToInterface(NULL),
fInitCheck(false)
{
fPath=strdup(path);
Initialise();
}
USBDevice::~USBDevice()
{
free(fPath);
if (fConfigurationDescriptors) {
for (uint8 i = 0; i < fDeviceDescriptor.num_configurations; i++) {
if (fConfigurationDescriptors[i])
delete fConfigurationDescriptors[i];
}
delete[] fConfigurationDescriptors;
}
if (fEndpointToIndex)
delete[] fEndpointToIndex;
if (fEndpointToInterface)
delete[] fEndpointToInterface;
}
bool
USBDevice::InitCheck()
{
return fInitCheck;
}
const char *
USBDevice::Location() const
{
return fPath;
}
uint8
USBDevice::CountConfigurations() const
{
return fDeviceDescriptor.num_configurations;
}
const usb_device_descriptor *
USBDevice::Descriptor() const
{
return &fDeviceDescriptor;
}
const usb_configuration_descriptor *
USBDevice::ConfigurationDescriptor(uint8 index) const
{
if (index > CountConfigurations())
return NULL;
return (usb_configuration_descriptor *) fConfigurationDescriptors[index];
}
const usb_configuration_descriptor *
USBDevice::ActiveConfiguration() const
{
return (usb_configuration_descriptor *) fConfigurationDescriptors[fActiveConfiguration];
}
uint8
USBDevice::ActiveConfigurationIndex() const
{
return fActiveConfiguration;
}
int USBDevice::ClaimInterface(uint8 interface)
{
if (interface > ActiveConfiguration()->number_interfaces)
return LIBUSB_ERROR_NOT_FOUND;
if (fClaimedInterfaces & (1U << interface))
return LIBUSB_ERROR_BUSY;
fClaimedInterfaces |= (1U << interface);
return LIBUSB_SUCCESS;
}
int USBDevice::ReleaseInterface(uint8 interface)
{
fClaimedInterfaces &= ~(1U << interface);
return LIBUSB_SUCCESS;
}
int
USBDevice::CheckInterfacesFree(uint8 config)
{
if (fConfigToIndex.count(config) == 0)
return LIBUSB_ERROR_NOT_FOUND;
if (fClaimedInterfaces == 0)
return fConfigToIndex[config];
return LIBUSB_ERROR_BUSY;
}
void
USBDevice::SetActiveConfiguration(uint8 config_index)
{
fActiveConfiguration = config_index;
}
uint8
USBDevice::EndpointToIndex(uint8 address) const
{
return fEndpointToIndex[fActiveConfiguration][address];
}
uint8
USBDevice::EndpointToInterface(uint8 address) const
{
return fEndpointToInterface[fActiveConfiguration][address];
}
int
USBDevice::Initialise() //Do we need more error checking, etc? How to report?
{
int fRawFD = open(fPath, O_RDWR | O_CLOEXEC);
if (fRawFD < 0)
return B_ERROR;
usb_raw_command command;
command.device.descriptor = &fDeviceDescriptor;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_DEVICE_DESCRIPTOR, &command, sizeof(command)) ||
command.device.status != B_USB_RAW_STATUS_SUCCESS) {
close(fRawFD);
return B_ERROR;
}
fConfigurationDescriptors = new(std::nothrow) unsigned char *[fDeviceDescriptor.num_configurations];
fEndpointToIndex = new(std::nothrow) map<uint8,uint8> [fDeviceDescriptor.num_configurations];
fEndpointToInterface = new(std::nothrow) map<uint8,uint8> [fDeviceDescriptor.num_configurations];
for (uint8 i = 0; i < fDeviceDescriptor.num_configurations; i++) {
usb_configuration_descriptor tmp_config;
command.config.descriptor = &tmp_config;
command.config.config_index = i;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_CONFIGURATION_DESCRIPTOR, &command, sizeof(command)) ||
command.config.status != B_USB_RAW_STATUS_SUCCESS) {
usbi_err(NULL, "failed retrieving configuration descriptor");
close(fRawFD);
return B_ERROR;
}
fConfigToIndex[tmp_config.configuration_value] = i;
fConfigurationDescriptors[i] = new(std::nothrow) unsigned char[tmp_config.total_length];
command.config_etc.descriptor = (usb_configuration_descriptor*)fConfigurationDescriptors[i];
command.config_etc.length = tmp_config.total_length;
command.config_etc.config_index = i;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_CONFIGURATION_DESCRIPTOR_ETC, &command, sizeof(command)) ||
command.config_etc.status != B_USB_RAW_STATUS_SUCCESS) {
usbi_err(NULL, "failed retrieving full configuration descriptor");
close(fRawFD);
return B_ERROR;
}
for (uint8 j = 0; j < tmp_config.number_interfaces; j++) {
command.alternate.config_index = i;
command.alternate.interface_index = j;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_ALT_INTERFACE_COUNT, &command, sizeof(command)) ||
command.config.status != B_USB_RAW_STATUS_SUCCESS) {
usbi_err(NULL, "failed retrieving number of alternate interfaces");
close(fRawFD);
return B_ERROR;
}
uint8 num_alternate = (uint8)command.alternate.alternate_info;
for (uint8 k = 0; k < num_alternate; k++) {
usb_interface_descriptor tmp_interface;
command.interface_etc.config_index = i;
command.interface_etc.interface_index = j;
command.interface_etc.alternate_index = k;
command.interface_etc.descriptor = &tmp_interface;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_INTERFACE_DESCRIPTOR_ETC, &command, sizeof(command)) ||
command.config.status != B_USB_RAW_STATUS_SUCCESS) {
usbi_err(NULL, "failed retrieving interface descriptor");
close(fRawFD);
return B_ERROR;
}
for (uint8 l = 0; l < tmp_interface.num_endpoints; l++) {
usb_endpoint_descriptor tmp_endpoint;
command.endpoint_etc.config_index = i;
command.endpoint_etc.interface_index = j;
command.endpoint_etc.alternate_index = k;
command.endpoint_etc.endpoint_index = l;
command.endpoint_etc.descriptor = &tmp_endpoint;
if (ioctl(fRawFD, B_USB_RAW_COMMAND_GET_ENDPOINT_DESCRIPTOR_ETC, &command, sizeof(command)) ||
command.config.status != B_USB_RAW_STATUS_SUCCESS) {
usbi_err(NULL, "failed retrieving endpoint descriptor");
close(fRawFD);
return B_ERROR;
}
fEndpointToIndex[i][tmp_endpoint.endpoint_address] = l;
fEndpointToInterface[i][tmp_endpoint.endpoint_address] = j;
}
}
}
}
close(fRawFD);
fInitCheck = true;
return B_OK;
}