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sys-con/ControllerUSB/source/Controllers/Dualshock3Controller.cpp

237 lines
7.1 KiB
C++

#include "Controllers/Dualshock3Controller.h"
#include <cmath>
static ControllerConfig _dualshock3ControllerConfig{};
Dualshock3Controller::Dualshock3Controller(std::unique_ptr<IUSBDevice> &&interface)
: IController(std::move(interface))
{
}
Dualshock3Controller::~Dualshock3Controller()
{
Exit();
}
Result Dualshock3Controller::Initialize()
{
Result rc;
rc = OpenInterfaces();
if (R_FAILED(rc))
return rc;
SetLED(DS3LED_1);
return rc;
}
void Dualshock3Controller::Exit()
{
CloseInterfaces();
}
Result Dualshock3Controller::OpenInterfaces()
{
Result rc;
rc = m_device->Open();
if (R_FAILED(rc))
return rc;
//Open each interface, send it a setup packet and get the endpoints if it succeeds
std::vector<std::unique_ptr<IUSBInterface>> &interfaces = m_device->GetInterfaces();
for (auto &&interface : interfaces)
{
rc = interface->Open();
if (R_FAILED(rc))
return rc;
if (interface->GetDescriptor()->bNumEndpoints < 2)
continue;
//Send an initial control packet
constexpr uint8_t initBytes[] = {0x42, 0x0C, 0x00, 0x00};
rc = SendCommand(interface.get(), Ds3FeatureStartDevice, initBytes, sizeof(initBytes));
if (R_FAILED(rc))
return 60;
m_interface = interface.get();
if (!m_inPipe)
{
for (int i = 0; i != 15; ++i)
{
IUSBEndpoint *inEndpoint = interface->GetEndpoint(IUSBEndpoint::USB_ENDPOINT_IN, i);
if (inEndpoint)
{
rc = inEndpoint->Open();
if (R_FAILED(rc))
return 61;
m_inPipe = inEndpoint;
break;
}
}
}
if (!m_outPipe)
{
for (int i = 0; i != 15; ++i)
{
IUSBEndpoint *outEndpoint = interface->GetEndpoint(IUSBEndpoint::USB_ENDPOINT_OUT, i);
if (outEndpoint)
{
rc = outEndpoint->Open();
if (R_FAILED(rc))
return 62;
m_outPipe = outEndpoint;
break;
}
}
}
}
if (!m_inPipe || !m_outPipe)
return 69;
return rc;
}
void Dualshock3Controller::CloseInterfaces()
{
//m_device->Reset();
m_device->Close();
}
Result Dualshock3Controller::GetInput()
{
uint8_t input_bytes[49];
Result rc = m_inPipe->Read(input_bytes, sizeof(input_bytes));
if (R_FAILED(rc))
return rc;
if (input_bytes[0] == Ds3InputPacket_Button)
{
m_buttonData = *reinterpret_cast<Dualshock3ButtonData *>(input_bytes);
}
return rc;
}
float Dualshock3Controller::NormalizeTrigger(uint8_t value)
{
uint8_t deadzone = (UINT8_MAX * _dualshock3ControllerConfig.triggerDeadzonePercent) / 100;
//If the given value is below the trigger zone, save the calc and return 0, otherwise adjust the value to the deadzone
return value < deadzone
? 0
: static_cast<float>(value - deadzone) / (UINT8_MAX - deadzone);
}
void Dualshock3Controller::NormalizeAxis(uint8_t x,
uint8_t y,
uint8_t deadzonePercent,
float *x_out,
float *y_out)
{
float x_val = x - 127.0f;
float y_val = 127.0f - y;
// Determine how far the stick is pushed.
//This will never exceed 32767 because if the stick is
//horizontally maxed in one direction, vertically it must be neutral(0) and vice versa
float real_magnitude = std::sqrt(x_val * x_val + y_val * y_val);
float real_deadzone = (127 * deadzonePercent) / 100;
// Check if the controller is outside a circular dead zone.
if (real_magnitude > real_deadzone)
{
// Clip the magnitude at its expected maximum value.
float magnitude = std::min(127.0f, real_magnitude);
// Adjust magnitude relative to the end of the dead zone.
magnitude -= real_deadzone;
// Normalize the magnitude with respect to its expected range giving a
// magnitude value of 0.0 to 1.0
//ratio = (currentValue / maxValue) / realValue
float ratio = (magnitude / (127 - real_deadzone)) / real_magnitude;
*x_out = x_val * ratio;
*y_out = y_val * ratio;
}
else
{
// If the controller is in the deadzone zero out the magnitude.
*x_out = *y_out = 0.0f;
}
}
//Pass by value should hopefully be optimized away by RVO
NormalizedButtonData Dualshock3Controller::GetNormalizedButtonData()
{
NormalizedButtonData normalData;
normalData.triggers[0] = NormalizeTrigger(m_buttonData.trigger_left_pressure);
normalData.triggers[1] = NormalizeTrigger(m_buttonData.trigger_right_pressure);
NormalizeAxis(m_buttonData.stick_left_x, m_buttonData.stick_left_y, _dualshock3ControllerConfig.leftStickDeadzonePercent,
&normalData.sticks[0].axis_x, &normalData.sticks[0].axis_y);
NormalizeAxis(m_buttonData.stick_right_x, m_buttonData.stick_right_y, _dualshock3ControllerConfig.rightStickDeadzonePercent,
&normalData.sticks[1].axis_x, &normalData.sticks[1].axis_y);
bool buttons[NUM_CONTROLLERBUTTONS] = {
m_buttonData.triangle,
m_buttonData.circle,
m_buttonData.cross,
m_buttonData.square,
m_buttonData.stick_left_click,
m_buttonData.stick_right_click,
m_buttonData.bumper_left,
m_buttonData.bumper_right,
normalData.triggers[0] > 0,
normalData.triggers[1] > 0,
m_buttonData.back,
m_buttonData.start,
m_buttonData.dpad_up,
m_buttonData.dpad_right,
m_buttonData.dpad_down,
m_buttonData.dpad_left,
false,
m_buttonData.guide,
};
for (int i = 0; i != NUM_CONTROLLERBUTTONS; ++i)
{
ControllerButton button = _dualshock3ControllerConfig.buttons[i];
normalData.buttons[(button != NOT_SET ? button : i)] = buttons[i];
}
return normalData;
}
Result Dualshock3Controller::SetRumble(uint8_t strong_magnitude, uint8_t weak_magnitude)
{
//Not implemented yet
return 9;
}
Result Dualshock3Controller::SendCommand(IUSBInterface *interface, Dualshock3FeatureValue feature, const void *buffer, uint16_t size)
{
return interface->ControlTransfer(0x21, 0x09, static_cast<uint16_t>(feature), 0, size, buffer);
}
Result Dualshock3Controller::SetLED(Dualshock3LEDValue value)
{
const uint8_t ledPacket[]{
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
static_cast<uint8_t>(value << 1),
LED_PERMANENT,
LED_PERMANENT,
LED_PERMANENT,
LED_PERMANENT};
return SendCommand(m_interface, Ds3FeatureUnknown1, ledPacket, sizeof(ledPacket));
}
void Dualshock3Controller::LoadConfig(const ControllerConfig *config)
{
_dualshock3ControllerConfig = *config;
}
ControllerConfig *Dualshock3Controller::GetConfig()
{
return &_dualshock3ControllerConfig;
}