// stl includes
#include <exception>
#include <cstring>
// Local Hyperion includes
#include "LedDeviceLightpack.h"
// from USB_ID.h (http://code.google.com/p/light-pack/source/browse/CommonHeaders/USB_ID.h)
#define USB_OLD_VENDOR_ID 0x03EB
#define USB_OLD_PRODUCT_ID 0x204F
#define USB_VENDOR_ID 0x1D50
#define USB_PRODUCT_ID 0x6022
#define LIGHTPACK_INTERFACE 0
// from commands.h (http://code.google.com/p/light-pack/source/browse/CommonHeaders/commands.h)
// Commands to device, sends it in first byte of data[]
enum COMMANDS{
CMD_UPDATE_LEDS = 1,
CMD_OFF_ALL,
CMD_SET_TIMER_OPTIONS,
CMD_SET_PWM_LEVEL_MAX_VALUE, /* deprecated */
CMD_SET_SMOOTH_SLOWDOWN,
CMD_SET_BRIGHTNESS,
CMD_NOP = 0x0F
};
// from commands.h (http://code.google.com/p/light-pack/source/browse/CommonHeaders/commands.h)
enum DATA_VERSION_INDEXES{
INDEX_FW_VER_MAJOR = 1,
INDEX_FW_VER_MINOR
};
LedDeviceLightpack::LedDeviceLightpack(const QJsonObject &deviceConfig)
: LedDevice(deviceConfig)
, _libusbContext(nullptr)
, _device(nullptr)
, _deviceHandle(nullptr)
, _busNumber(-1)
, _addressNumber(-1)
, _firmwareVersion({-1,-1})
, _bitsPerChannel(-1)
, _hwLedCount(-1)
, _isOpen(false)
{
}
LedDeviceLightpack::~LedDeviceLightpack()
{
if (_libusbContext != nullptr)
{
libusb_exit(_libusbContext);
}
}
LedDevice* LedDeviceLightpack::construct(const QJsonObject &deviceConfig)
{
return new LedDeviceLightpack(deviceConfig);
}
bool LedDeviceLightpack::init(const QJsonObject &deviceConfig)
{
bool isInitOK = false;
// Initialise sub-class
if ( LedDevice::init(deviceConfig) )
{
_serialNumber = deviceConfig["serial"].toString("");
int error;
// initialize the USB context
if ( (error = libusb_init(&_libusbContext)) != LIBUSB_SUCCESS )
{
_libusbContext = nullptr;
QString errortext = QString ("Error while initializing USB context(%1):%2").arg(error).arg(libusb_error_name(error));
this->setInError(errortext);
isInitOK = false;
}
else
{
Debug(_log, "USB context initialized");
if ( _log->getMinLevel() == Logger::LogLevel::DEBUG )
{
int logLevel = LIBUSB_LOG_LEVEL_INFO;
#if LIBUSB_API_VERSION >= 0x01000106
libusb_set_option(_libusbContext, LIBUSB_OPTION_LOG_LEVEL, logLevel);
#else
libusb_set_debug(_libusbContext, logLevel);
#endif
}
// retrieve the list of USB devices
libusb_device ** deviceList;
ssize_t deviceCount = libusb_get_device_list(_libusbContext, &deviceList);
bool deviceFound = true;
// iterate the list of devices
for (ssize_t i = 0 ; i < deviceCount; ++i)
{
// try to open and initialize the device
deviceFound = searchDevice(deviceList[i], _serialNumber);
if ( deviceFound )
{
_device = deviceList[i];
// a device was successfully opened. break from list
break;
}
}
// free the device list
libusb_free_device_list(deviceList, 1);
if (!deviceFound)
{
QString errortext;
if (_serialNumber.isEmpty())
{
errortext = QString ("No working Lightpack devices were found");
}
else
{
errortext = QString ("No working Lightpack device found with serial %1").arg( _serialNumber);
}
this->setInError( errortext );
}
else
{
// set the led buffer size (command + 6 bytes per led)
_ledBuffer = std::vector<uint8_t>(1 + _hwLedCount * 6, 0);
_ledBuffer[0] = CMD_UPDATE_LEDS;
isInitOK = true;
}
}
}
return isInitOK;
}
int LedDeviceLightpack::open()
{
int retval = -1;
_isDeviceReady = false;
if ( _device != nullptr)
{
openDevice(_device, &_deviceHandle);
if ( _deviceHandle == nullptr )
{
QString errortext = QString ("Failed to open device with serial [%1]").arg(_serialNumber);
this->setInError(errortext);
retval = -1;
}
else
{
disableSmoothing();
{
// Everything is OK
_isDeviceReady = true;
_isOpen = true;
Info(_log, "Lightpack device successfully opened");
retval = 0;
}
}
}
return retval;
}
int LedDeviceLightpack::close()
{
int retval = 0;
_isDeviceReady = false;
_isOpen = false;
if ( _deviceHandle != nullptr)
{
closeDevice(_deviceHandle);
_deviceHandle = nullptr;
}
return retval;
}
bool LedDeviceLightpack::searchDevice(libusb_device * device, const QString & requestedSerialNumber)
{
bool lightPackFound = false;
libusb_device_descriptor deviceDescriptor;
int error = libusb_get_device_descriptor(device, &deviceDescriptor);
if (error != LIBUSB_SUCCESS)
{
Error(_log, "Error while retrieving device descriptor(%d): %s", error, libusb_error_name(error));
return false;
}
if ((deviceDescriptor.idVendor == USB_VENDOR_ID && deviceDescriptor.idProduct == USB_PRODUCT_ID) ||
(deviceDescriptor.idVendor == USB_OLD_VENDOR_ID && deviceDescriptor.idProduct == USB_OLD_PRODUCT_ID))
{
Info(_log, "Found a Lightpack device. Retrieving more information...");
Debug(_log, "vendorIdentifier : %s", QSTRING_CSTR(QString("0x%1").arg(static_cast<ushort>(deviceDescriptor.idVendor),0,16)));
Debug(_log, "productIdentifier: %s", QSTRING_CSTR(QString("0x%1").arg(static_cast<ushort>(deviceDescriptor.idProduct),0,16)));
Debug(_log, "release_number : %s", QSTRING_CSTR(QString("0x%1").arg(static_cast<ushort>(deviceDescriptor.bcdDevice),0,16)));
Debug(_log, "manufacturer : %s", QSTRING_CSTR(getProperty(device, deviceDescriptor.iManufacturer)));
// get the hardware address
int busNumber = libusb_get_bus_number(device);
int addressNumber = libusb_get_device_address(device);
// get the serial number
QString serialNumber = LedDeviceLightpack::getProperty(device, deviceDescriptor.iSerialNumber);
Debug(_log,"Lightpack device found: bus=%d address=%d serial=%s", busNumber, addressNumber, QSTRING_CSTR(serialNumber));
// check if this is the device we are looking for
if (requestedSerialNumber.isEmpty() || requestedSerialNumber == serialNumber)
{
libusb_device_handle * deviceHandle;
if ( openDevice(device, &deviceHandle ) == 0 )
{
_serialNumber = serialNumber;
_busNumber = busNumber;
_addressNumber = addressNumber;
// get the firmware version
uint8_t buffer[256];
error = libusb_control_transfer(
deviceHandle,
static_cast<uint8_t>( LIBUSB_ENDPOINT_IN | LIBUSB_REQUEST_TYPE_CLASS | LIBUSB_RECIPIENT_INTERFACE),
0x01,
0x0100,
0,
buffer, sizeof(buffer), 1000);
if (error < 3)
{
Error(_log, "Unable to retrieve firmware version number from Lightpack device(%d): %s", error, libusb_error_name(error));
}
else
{
_firmwareVersion.majorVersion = buffer[INDEX_FW_VER_MAJOR];
_firmwareVersion.minorVersion = buffer[INDEX_FW_VER_MINOR];
}
#if 0
// FOR TESTING PURPOSE: FORCE MAJOR VERSION TO 6
_firmwareVersion.majorVersion = 6;
#endif
// determine the number of LEDs
if (_firmwareVersion.majorVersion == 4)
{
_hwLedCount = 8;
}
else
{
_hwLedCount = 10;
}
// determine the bits per channel
if (_firmwareVersion.majorVersion == 6)
{
// maybe also or version 7? The firmware suggest this is only for 6... (2013-11-13)
_bitsPerChannel = 12;
}
else
{
_bitsPerChannel = 8;
}
closeDevice(deviceHandle);
Debug(_log, "Lightpack device found: bus=%d address=%d serial=%s version=%d.%d.", _busNumber, _addressNumber, QSTRING_CSTR(_serialNumber), _firmwareVersion.majorVersion, _firmwareVersion.minorVersion );
lightPackFound = true;
}
else
{
Warning(_log, "Unable to open Lightpack device. Searching for other device");
}
}
}
return lightPackFound;
}
int LedDeviceLightpack::write(const std::vector<ColorRgb> &ledValues)
{
return write(ledValues.data(), static_cast<int>(ledValues.size()));
}
int LedDeviceLightpack::write(const ColorRgb * ledValues, int size)
{
int count = qMin(_hwLedCount, static_cast<int>( size ));
for (int i = 0; i < count ; ++i)
{
const ColorRgb & color = ledValues[i];
// copy the most significant bits of the RGB values to the first three bytes
// offset 1 to accommodate for the command byte
_ledBuffer[6*i+1] = color.red;
_ledBuffer[6*i+2] = color.green;
_ledBuffer[6*i+3] = color.blue;
// leave the next three bytes on zero...
// 12-bit values having zeros in the lowest 4 bits which is almost correct, but it saves extra
// switches to determine what to do and some bit shuffling
}
int error = writeBytes(_ledBuffer.data(), _ledBuffer.size());
return error >= 0 ? 0 : error;
}
bool LedDeviceLightpack::powerOff()
{
bool rc = false;
unsigned char buf[1] = {CMD_OFF_ALL};
rc = writeBytes(buf, sizeof(buf)) == sizeof(buf);
return rc;
}
const QString &LedDeviceLightpack::getSerialNumber() const
{
return _serialNumber;
}
int LedDeviceLightpack::writeBytes(uint8_t *data, int size)
{
int rc = 0;
int error = libusb_control_transfer(_deviceHandle,
static_cast<uint8_t>( LIBUSB_ENDPOINT_OUT | LIBUSB_REQUEST_TYPE_CLASS | LIBUSB_RECIPIENT_INTERFACE ),
0x09,
(2 << 8),
0x00,
data, size, 1000);
if (error != size)
{
rc = -1;
Error(_log, "Unable to write %d bytes to Lightpack device(%d): %s", size, error, libusb_error_name(error));
}
return rc;
}
int LedDeviceLightpack::disableSmoothing()
{
unsigned char buf[2] = {CMD_SET_SMOOTH_SLOWDOWN, 0};
int rc = 0;
if ( writeBytes(buf, sizeof(buf)) == sizeof(buf) )
{
rc = 1;
}
return rc;
}
int LedDeviceLightpack::openDevice(libusb_device *device, libusb_device_handle ** deviceHandle)
{
int rc = 0;
libusb_device_handle * handle = nullptr;
int error = libusb_open(device, &handle);
if (error != LIBUSB_SUCCESS)
{
Error(_log, "unable to open device(%d): %s", error, libusb_error_name(error));
rc = -1;
}
else
{
// detach kernel driver if it is active
if (libusb_kernel_driver_active(handle, LIGHTPACK_INTERFACE) == 1)
{
error = libusb_detach_kernel_driver(handle, LIGHTPACK_INTERFACE);
if (error != LIBUSB_SUCCESS)
{
Error(_log, "unable to detach kernel driver(%d): %s", error, libusb_error_name(error));
libusb_close(handle);
rc = -1;
}
}
error = libusb_claim_interface(handle, LIGHTPACK_INTERFACE);
if (error != LIBUSB_SUCCESS)
{
Error(_log, "unable to claim interface(%d): %s", error, libusb_error_name(error));
libusb_attach_kernel_driver(handle, LIGHTPACK_INTERFACE);
libusb_close(handle);
rc = -1;
}
}
*deviceHandle = handle;
return rc;
}
int LedDeviceLightpack::closeDevice(libusb_device_handle * deviceHandle)
{
int rc = 0;
int error = libusb_release_interface(deviceHandle, LIGHTPACK_INTERFACE);
if (error != LIBUSB_SUCCESS)
{
Debug(_log, "Error while releasing interface (%d): %s", error, libusb_error_name(error));
rc = -1;
}
error = libusb_attach_kernel_driver(deviceHandle, LIGHTPACK_INTERFACE);
if (error != LIBUSB_SUCCESS)
{
Debug(_log, "Error while attaching kernel driver (%d): %s", error, libusb_error_name(error));
rc = -1;
}
libusb_close(deviceHandle);
return rc;
}
QString LedDeviceLightpack::getProperty(libusb_device * device, int stringDescriptorIndex)
{
QString value;
if ( stringDescriptorIndex != 0 )
{
libusb_device_handle * handle = nullptr;
if ( libusb_open(device, &handle) == LIBUSB_SUCCESS )
{
char buffer[256];
int error = libusb_get_string_descriptor_ascii(handle, stringDescriptorIndex, reinterpret_cast<unsigned char *>(buffer), sizeof(buffer));
if (error > 0)
{
value = QString(QByteArray(buffer, error));
}
libusb_close(handle);
}
}
return value;
}