hyperion.ng/libsrc/hyperion/Hyperion.cpp
T. van der Zwan 4031a33f04 Added simple test for image2led map.
Added test executable for creating png from frame grabber.
Added test-device for exporting color values of leds to text file.
Updated configuration to match new color transform.
Finished first version of the Hyperion structure (IT WORKS [1% CPU]!)
2013-08-15 19:11:02 +00:00

159 lines
4.2 KiB
C++

// Syslog include
#include <syslog.h>
#include <QDateTime>
// JsonSchema include
#include <utils/jsonschema/JsonFactory.h>
// hyperion include
#include <hyperion/Hyperion.h>
#include <hyperion/LedDevice.h>
#include <hyperion/ImageProcessorFactory.h>
#include "LedDeviceWs2801.h"
#include "LedDeviceTest.h"
#include "ColorTransform.h"
using namespace hyperion;
LedDevice* constructDevice(const Json::Value& deviceConfig)
{
std::cout << "Device configuration: " << deviceConfig << std::endl;
LedDevice* device = nullptr;
if (deviceConfig["type"].asString() == "ws2801")
{
const std::string name = "WS-2801";
const std::string output = deviceConfig["output"].asString();
const unsigned interval = deviceConfig["interval"].asInt();
const unsigned rate = deviceConfig["rate"].asInt();
LedDeviceWs2801* deviceWs2801 = new LedDeviceWs2801(name, output, interval, rate);
deviceWs2801->open();
device = deviceWs2801;
}
else if (deviceConfig["type"].asString() == "test")
{
device = new LedDeviceTest();
}
else
{
// Unknown / Unimplemented device
}
return device;
}
ColorTransform* createColorTransform(const Json::Value& colorConfig)
{
const double threshold = colorConfig["threshold"].asDouble();
const double gamma = colorConfig["gamma"].asDouble();
const double blacklevel = colorConfig["blacklevel"].asDouble();
const double whitelevel = colorConfig["whitelevel"].asDouble();
ColorTransform* transform = new ColorTransform(threshold, gamma, blacklevel, whitelevel);
return transform;
}
LedString Hyperion::createLedString(const Json::Value& ledsConfig)
{
LedString ledString;
for (const Json::Value& ledConfig : ledsConfig)
{
Led led;
led.index = ledConfig["index"].asInt();
const Json::Value& hscanConfig = ledConfig["hscan"];
const Json::Value& vscanConfig = ledConfig["vscan"];
led.minX_frac = std::max(0.0, std::min(100.0, hscanConfig["minimum"].asDouble()))/100.0;
led.maxX_frac = std::max(0.0, std::min(100.0, hscanConfig["maximum"].asDouble()))/100.0;
led.minY_frac = 1.0 - std::max(0.0, std::min(100.0, vscanConfig["maximum"].asDouble()))/100.0;
led.maxY_frac = 1.0 - std::max(0.0, std::min(100.0, vscanConfig["minimum"].asDouble()))/100.0;
ledString.leds().push_back(led);
}
return ledString;
}
Hyperion::Hyperion(const Json::Value &jsonConfig) :
mLedString(createLedString(jsonConfig["leds"])),
mRedTransform( createColorTransform(jsonConfig["color"]["red"])),
mGreenTransform(createColorTransform(jsonConfig["color"]["green"])),
mBlueTransform( createColorTransform(jsonConfig["color"]["blue"])),
mDevice(constructDevice(jsonConfig["device"])),
_timer()
{
ImageProcessorFactory::getInstance().init(mLedString);
_timer.setSingleShot(true);
QObject::connect(&_timer, SIGNAL(timeout()), this, SLOT(update()));
}
Hyperion::~Hyperion()
{
// Delete the Led-String
delete mDevice;
// Delete the color-transform
delete mBlueTransform;
delete mGreenTransform;
delete mRedTransform;
}
unsigned Hyperion::getLedCount() const
{
return mLedString.leds().size();
}
void Hyperion::setValue(int priority, std::vector<RgbColor>& ledColors, const int timeout_ms)
{
// Apply the transform to each led and color-channel
for (RgbColor& color : ledColors)
{
color.red = mRedTransform->transform(color.red);
color.green = mGreenTransform->transform(color.green);
color.blue = mBlueTransform->transform(color.blue);
}
if (timeout_ms > 0)
{
const uint64_t timeoutTime = QDateTime::currentMSecsSinceEpoch() + timeout_ms;
mMuxer.setInput(priority, ledColors, timeoutTime);
}
else
{
mMuxer.setInput(priority, ledColors);
}
if (priority == mMuxer.getCurrentPriority())
{
update();
}
}
void Hyperion::update()
{
// Update the muxer, cleaning obsolete priorities
mMuxer.setCurrentTime(QDateTime::currentMSecsSinceEpoch());
// Obtain the current priority channel
int priority = mMuxer.getCurrentPriority();
const PriorityMuxer::InputInfo & priorityInfo = mMuxer.getInputInfo(priority);
// Write the data to the device
mDevice->write(priorityInfo.ledColors);
// Start the timeout-timer
if (priorityInfo.timeoutTime_ms == -1)
{
_timer.stop();
}
else
{
int timeout_ms = std::max(0, int(priorityInfo.timeoutTime_ms - QDateTime::currentMSecsSinceEpoch()));
_timer.start(timeout_ms);
}
}