public void Raise_ValueGenerated_Event_And_Check_Value_Interval()
{
// Arrange
const int intervalBoundary = -112;
int? result = null;
var generator = new Generator();
var resetEvent = new ManualResetEventSlim(false);
void ValueGeneratedHandler(object sender, int value)
{
result = value;
resetEvent.Set();
(sender as Generator)?.Stop();
}
generator.ValueGenerated += ValueGeneratedHandler;
// Act
generator.Start(intervalBoundary, intervalBoundary, 1, 1);
// Assert
Assert.AreEqual(resetEvent.Wait(TimeSpan.FromMilliseconds(500)), true);
Assert.AreEqual(intervalBoundary, result);
generator.ValueGenerated -= ValueGeneratedHandler;
}
public override void Render(PostProcessRenderContext context)
{
var cmd = context.command;
cmd.BeginSample("Pix2Pix");
var sheet = context.propertySheets.Get(_shader);
var props = sheet.properties;
props.SetVector(ShaderIDs.EdgeParams, new Vector3(
settings.edgeThreshold,
settings.edgeIntensity,
settings.edgeOpacity
));
// Edge detection pass
cmd.BlitFullscreenTriangle(context.source, _sourceRT, sheet, 0);
// Pix2Pix generator pass
GpuBackend.UseCommandBuffer(cmd);
_generator.Start(_sourceRT);
_generator.Step();
while (_generator.Running)
{
_generator.Step();
}
_generator.GetResult(_resultRT);
GpuBackend.ResetToDefaultCommandBuffer();
// Composite pass
props.SetTexture(ShaderIDs.EdgeTex, _sourceRT);
cmd.BlitFullscreenTriangle(_resultRT, context.destination, sheet, 1);
cmd.EndSample("Pix2Pix");
}
//
// We want to generate the report
//
private void button_GenerateReport_Click(object sender, EventArgs e)
{
// We need a report name
string expectedTextRegEx = @"^[a-zA-Z0-9][A-Za-z0-9_. -]*$";
if (string.IsNullOrWhiteSpace(textBox_ReportName.Text) == true || Regex.IsMatch(textBox_ReportName.Text, expectedTextRegEx) == false)
{
m_logger.Log(@"No file name provided when generating report");
MessageBox.Show("You need to provide a valid Report Name before generating the stats.\n\nValid characters are 'a-z', 'A-Z', '0-9', _, ., [space] and -. The name must start with either a-z or 0-9", @"Stats Generation Error", MessageBoxButtons.OK, MessageBoxIcon.Error);
return;
}
// Format the report name
string reportName = textBox_ReportName.Text.Trim();
// Kick it off and we're done
Display.SetDisplayProperties(this, label_Progress, progressBar_Progress, button_GenerateReport, m_logger);
Generator.Start(this, m_fileList, reportName, m_logger, m_injectPaths, () =>
{
// Lose our dialog
m_logger.Log("Closing dialog - work done");
this.Close();
});
}
public MMnQueue_Modular(double hourlyArrivalRate, double hourlyServiceRate, int nServers, int seed = 0)
: base(seed)
{
HourlyArrivalRate = hourlyArrivalRate;
HourlyServiceRate = hourlyServiceRate;
Generator = AddChild(new Generator(new Generator.Statics
{
InterArrivalTime = rs => Exponential.Sample(rs, TimeSpan.FromHours(1 / HourlyArrivalRate))
}, DefaultRS.Next()));
Queue = AddChild(new Queue(double.PositiveInfinity, DefaultRS.Next()));
Server = AddChild(new Server(new Server.Statics
{
Capacity = nServers,
ServiceTime = (rs, load) => Exponential.Sample(rs, TimeSpan.FromHours(1 / HourlyServiceRate)),
}, DefaultRS.Next()));
Generator.OnArrive += () => Queue.RqstEnqueue(new Load());
Generator.OnArrive += Arrive;
Queue.OnEnqueued += Server.RqstStart;
Server.OnStarted += Queue.Dequeue;
Server.OnReadyToDepart += Server.Depart;
Server.OnReadyToDepart += load => Depart();
HC_InSystem = AddHourCounter();
/// Initial event
Generator.Start();
}
public void MinTimeInterval_Argument_Must_Be_Greater_Than_Zero()
{
// Arrange
var generator = new Generator();
// Act
generator.Start(0, 0, minTimeInterval: -1, maxTimeInterval: 100);
// Assert
}
static void Main(string[] args)
{
var gen = new Generator();
gen.Start();
var serv = new Server(gen);
serv.Start();
}
public void Start()
{
if (Generator.ThreadState == ThreadState.Suspended)
{
Generator.Resume();
}
else
{
Generator.Start();
}
}
public Network(Statics config, int seed, string tag = null) : base(config, seed, tag)
{
Name = "Network";
Display = true;
for (int i = 0; i < Config.NNodes; i++)
{
for (int j = 0; j < Config.NNodes; j++)
{
if (i != j && Config.DemandRates[i, j] > 0)
{
int o = i, d = j;
var g = new Generator <Order>(
new Generator <Order> .Statics
{
Create = rs => new Order(new Order.Statics
{
Origin = o,
Destination = d,
}, rs.Next()),
InterArrivalTime = rs => TimeSpan.FromDays(
Exponential.Sample(rs, 1 / Config.DemandRates[o, d])),
SkipFirst = true,
}, DefaultRS.Next());
g.OnArrive.Add(order => new DemandArriveEvent {
This = this, Order = order
});
Generators.Add(new Tuple <int, int>(i, j), g);
InitEvents.Add(g.Start());
}
}
}
Transporters.AddRange(Enumerable.Range(0, Config.NTransporters)
.Select(i => new Transporter(new Transporter.Statics(), DefaultRS.Next())
{
Display = Display,
Tag = "Transporter#" + i,
}));
foreach (var t in Transporters)
{
t.OnFinishTransport.Add(order => new DeliverEvent {
This = this, Order = order
});
}
InitEvents.AddRange(Transporters.Select(t => t.Init(this)));
}
private void SetTimer()
{
uint t = 0;
if (uint.TryParse(IntervalBox.Text, out t))
{
if (t > 0)
{
Generator.Stop();
Generator.Interval = TimeSpan.FromMilliseconds(t);
Generator.Start();
}
else
{
IntervalBox.Text = "1";
}
}
}
void Start()
{
Debug.Log(get_number());
Debug.Log(get_string());
call_callback((msg) => { Debug.Log(msg); });
generator = new Generator();
generator.OnUpdate
.Subscribe((v) => { Debug.Log(v); })
.AddTo(gameObject);
generator.OnUpdate
.BatchFrame(0, FrameCountType.Update)
.Subscribe((v) => {
textField.text = v.Last();
})
.AddTo(gameObject);
generator.Start();
}
static void Main(string[] args)
{
// Configure cancel key press handler (to stop the app)
Console.CancelKeyPress += new ConsoleCancelEventHandler(
CancelKeyPressHandler);
// Connect to the cloud
var deviceClient = DeviceClientHelper.Init();
// Telemetry generator produces random temperature
// and humidity, and then sends them both to the cloud
var telemetryGenerator = new Generator(
deviceClient, cancellationTokenSource.Token);
// Associate handler to update device properties according to cloud requests
deviceClient.SetDesiredPropertyUpdateCallbackAsync(
PropertyUpdateCallback, telemetryGenerator).Wait();
// Start telemetry
telemetryGenerator.Start().Wait();
}
void Start()
{
Generator.Start();
}
public static void Main()
{
// Print library information:
PrintInfo.PrintLibraryInfo();
// Enable network search:
Network.AutoDetectEnabled = true;
// Update device list:
DeviceList.Update();
// Try to open a generator with burst support:
Generator gen = null;
for (UInt32 i = 0; i < DeviceList.Count; i++)
{
DeviceListItem item = DeviceList.GetItemByIndex(i);
if (item.CanOpen(DeviceType.Generator))
{
gen = item.OpenGenerator();
// Check for burst support:
if ((gen.ModesNative & Constants.GM_BURST_COUNT) != 0)
{
break;
}
else
{
gen.Dispose();
gen = null;
}
}
}
if (gen != null)
{
try
{
// Set signal type:
gen.SignalType = SignalType.Sine;
// Set frequency:
gen.Frequency = 50; // 50 Hz
// Set amplitude:
gen.Amplitude = 2; // 2 V
// Set offset:
gen.Offset = 0; // 0 V
// Set burst mode:
gen.Mode = GeneratorMode.BurstCount;
// Set burst count:
gen.BurstCount = 100; // 100 periods
// Enable output:
gen.OutputOn = true;
// Print Generator info:
PrintInfo.PrintDeviceInfo(gen);
// Start signal generation
gen.Start();
// Wait for burst to complete:
while (gen.IsBurstActive)
{
Thread.Sleep(10); // 10 ms delay, to save CPU time.
}
// Disable output:
gen.OutputOn = false;
}
catch (System.Exception e)
{
Console.WriteLine("Exception: " + e.Message);
Environment.Exit(1);
}
// Close generator:
gen.Dispose();
gen = null;
}
else
{
Console.WriteLine("No generator available with burst support!");
Environment.Exit(1);
}
Environment.Exit(0);
}
public static void Main()
{
// Print library information:
PrintInfo.PrintLibraryInfo();
// Enable network search:
Network.AutoDetectEnabled = true;
// Update device list:
DeviceList.Update();
// Try to open a generator with triggered burst support:
Generator gen = null;
for (UInt32 i = 0; i < DeviceList.Count; i++)
{
DeviceListItem item = DeviceList.GetItemByIndex(i);
if (item.CanOpen(DeviceType.Generator))
{
gen = item.OpenGenerator();
// Check for triggered burst support:
if ((gen.ModesNative & Constants.GM_BURST_COUNT) != 0 && gen.TriggerInputs.Count > 0)
{
break;
}
else
{
gen.Dispose();
gen = null;
}
}
}
if (gen != null)
{
try
{
// Set signal type:
gen.SignalType = SignalType.Square;
// Set frequency:
gen.Frequency = 100e3; // 100 kHz
// Set amplitude:
gen.Amplitude = 2.5; // 2.5 V
// Set offset:
gen.Offset = 2.5; // 2.5 V
// Set symmetry (duty cycle):
gen.Symmetry = 0.25; // 25 %
// Set burst mode:
gen.Mode = GeneratorMode.BurstCount;
// Set burst count:
gen.BurstCount = 20; // 20 periods
// Locate trigger input:
TriggerInput triggerInput = gen.TriggerInputs.GetById(Constants.TIID_EXT1);
if (triggerInput == null)
{
triggerInput = gen.TriggerInputs.GetById(Constants.TIID_EXT2);
}
if (triggerInput == null)
{
throw new System.Exception("Unknown trigger input!");
}
// Enable trigger input:
triggerInput.Enabled = true;
// Set trigger input kind:
triggerInput.Kind = TriggerKind.FallingEdge;
// Enable output:
gen.OutputOn = true;
// Print generator info:
PrintInfo.PrintDeviceInfo(gen);
// Start signal generation
gen.Start();
// Wait for keystroke:
Console.WriteLine("Press Enter to stop signal generation...");
Console.ReadLine();
// Stop generator:
gen.Stop();
// Disable output:
gen.OutputOn = false;
}
catch (System.Exception e)
{
Console.WriteLine("Exception: " + e.Message);
Environment.Exit(1);
}
// Close generator:
gen.Dispose();
gen = null;
}
else
{
Console.WriteLine("No generator available with triggered burst support!");
Environment.Exit(1);
}
Environment.Exit(0);
}
public static void Main()
{
// Print library information:
PrintInfo.PrintLibraryInfo();
// Enable network search:
Network.AutoDetectEnabled = true;
// Update device list:
DeviceList.Update();
// Try to open an oscilloscope with block measurement support and a generator in the same device:
Oscilloscope scp = null;
Generator gen = null;
for (UInt32 i = 0; i < DeviceList.Count; i++)
{
DeviceListItem item = DeviceList.GetItemByIndex(i);
if (item.CanOpen(DeviceType.Oscilloscope) && item.CanOpen(DeviceType.Generator))
{
scp = item.OpenOscilloscope();
if ((scp.MeasureModes & Constants.MM_BLOCK) != 0)
{
gen = item.OpenGenerator();
break;
}
else
{
scp.Dispose();
scp = null;
}
}
}
if (scp != null && gen != null)
{
try
{
// Oscilloscope settings:
// Get the number of channels:
UInt16 channelCount = Convert.ToUInt16(scp.Channels.Count);
// Set measure mode:
scp.MeasureMode = MeasureMode.Block;
// Set sample frequency:
scp.SampleFrequency = 1e6; // 1 MHz
// Set record length:
scp.RecordLength = 10000; // 10 kS
UInt64 recordLength = scp.RecordLength; // Read actual record length.
// Set pre sample ratio:
scp.PreSampleRatio = 0; // 0 %
// For all channels:
for (UInt16 ch = 0; ch < channelCount; ch++)
{
OscilloscopeChannel channel = scp.Channels[ch];
// Enable channel to measure it:
channel.Enabled = true;
// Set range:
channel.Range = 8; // 8 V
// Set coupling:
channel.Coupling = Coupling.DCV; // DC Volt
}
// Set trigger timeout:
scp.TriggerTimeOut = 1; // 1 s
// Disable all channel trigger sources:
for (UInt16 ch = 0; ch < channelCount; ch++)
{
scp.Channels[ch].Trigger.Enabled = false;
}
// Locate trigger input:
TriggerInput triggerInput = scp.TriggerInputs.GetById(Constants.TIID_GENERATOR_NEW_PERIOD); // or Constants.TIID_GENERATOR_START or Constants.TIID_GENERATOR_STOP
if (triggerInput == null)
{
throw new System.Exception("Unknown trigger input!");
}
// Enable trigger input:
triggerInput.Enabled = true;
// Generator settings:
// Set signal type:
gen.SignalType = SignalType.Triangle;
// Set frequency:
gen.Frequency = 1e3; // 1 kHz
// Set amplitude:
gen.Amplitude = 2; // 2 V
// Set offset:
gen.Offset = 0; // 0 V
// Enable output:
gen.OutputOn = true;
// Print oscilloscope info:
PrintInfo.PrintDeviceInfo(scp);
// Print generator info:
PrintInfo.PrintDeviceInfo(gen);
// Start measurement:
scp.Start();
// Start signal generation:
gen.Start();
// Wait for measurement to complete:
while (!scp.IsDataReady)
{
Thread.Sleep(10); // 10 ms delay, to save CPU time.
}
// Stop generator:
gen.Stop();
// Disable output:
gen.OutputOn = false;
// Get data:
float[][] data = scp.GetData();
// Open file with write/update permissions:
string filename = "OscilloscopeGeneratorTrigger.csv";
StreamWriter file = new StreamWriter(filename, false);
// Output CSV data:
if (File.Exists(filename))
{
// Write csv header:
file.Write("Sample");
for (UInt16 i = 0; i < channelCount; i++)
{
file.Write(string.Format(";Ch{0}", i + 1));
}
file.Write(Environment.NewLine);
// Write the data to csv:
for (UInt64 i = 0; i < recordLength; i++)
{
file.Write(i.ToString());
for (UInt16 ch = 0; ch < channelCount; ch++)
{
file.Write(";" + data[ch][i].ToString());
}
file.Write(Environment.NewLine);
}
Console.WriteLine("Data written to: " + filename);
// Close file:
file.Close();
}
else
{
Console.WriteLine("Couldn't open file: " + filename);
Environment.Exit(1);
}
}
catch (System.Exception e)
{
Console.WriteLine("Exception: " + e.Message);
Environment.Exit(1);
}
// Close oscilloscope:
scp.Dispose();
scp = null;
// Close generator:
gen.Dispose();
gen = null;
}
else
{
Console.WriteLine("No oscilloscope available with block measurement support!");
Environment.Exit(1);
}
Environment.Exit(0);
}
// --------------------------------------------------------------------------------
// Event Handlers
private void buttonGenerate_Click(object sender, EventArgs e)
{
this.buttonGenerate.Enabled = false;
this.checkBoxRealTime.Enabled = false;
this.buttonViewFloorDown.Enabled = false;
this.buttonViewFloorUp.Enabled = false;
// initialize a new maze using sizes specified
this.maze = new Maze3D((int)this.numericUpDownWidth.Value, (int)this.numericUpDownHeight.Value, (int)this.numericUpDownLevels.Value);
// create the bitmaps for rendering each level of the maze
this.floorLevelBitmap = new Bitmap[this.maze.Levels];
for (int floorIndex = 0; floorIndex < this.maze.Levels; floorIndex++)
{
this.floorLevelBitmap[floorIndex] = new Bitmap(this.maze.Width * cellSize + 2 * offsetX, this.maze.Height * cellSize + 2 * offsetY);
}
// create the ungenerated floors of the maze
InitializeMazeLevelBitmaps();
this.viewLevel = 1;
this.pictureBoxCanvas.Image = this.floorLevelBitmap[this.viewLevel - 1];
if (this.checkBoxRealTime.Checked)
{
this.labelViewingFloor.Enabled = true;
this.pictureBoxCanvas.Visible = true;
this.setLevelViewButtons();
}
else
{
this.labelViewingFloor.Enabled = false;
this.pictureBoxCanvas.Visible = false;
this.labelViewingFloor.Text = "Viewing Floor: none";
}
// set up the tool strip lable and progress bar
int generatorSteps = this.maze.Width * this.maze.Height * this.maze.Levels;
this.toolStripProgressBar1.Maximum = generatorSteps;
this.toolStripProgressBar1.Value = 0;
this.toolStripProgressBar1.Visible = true;
int generatorStepCount = 1;
this.toolStripStatusLabel2.Visible = true;
this.toolStripStatusLabel2.Text = "Generating maze...0%";
// create the maze generator and provide it a reference to the maze it will operate upon
Generator generator = new Generator(this.maze);
// start the maze generator in manual step mode
bool generating = generator.Start();
while (generating)
{
var stepResult = generator.Step();
Cell changedCell = stepResult.Item1;
string changedWall = stepResult.Item2;
if (changedCell != null)
this.toolStripStatusLabel1.Text = String.Format("Cell: ({0}, {1}, {2})", changedCell.X, changedCell.Y, changedCell.Z);
switch (changedWall)
{
case "Floor":
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z]))
{
bitmapGraphics.DrawLine(Pens.Red, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4);
bitmapGraphics.DrawLine(Pens.Red, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 - 3,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4 - 3);
bitmapGraphics.DrawLine(Pens.Red, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 + 3,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4 - 3);
}
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z - 1]))
{
bitmapGraphics.DrawLine(Pens.Blue, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4);
bitmapGraphics.DrawLine(Pens.Blue, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 - 3,
this.offsetY + cellSize * changedCell.Y + cellSize / 4 + 3);
bitmapGraphics.DrawLine(Pens.Blue, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 + 3,
this.offsetY + cellSize * changedCell.Y + cellSize / 4 + 3);
}
break;
case "North":
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z]))
{
bitmapGraphics.DrawLine(Pens.LightGray, this.offsetX + (cellSize * changedCell.X) + 1,
this.offsetY + (cellSize * changedCell.Y),
this.offsetX + (cellSize * changedCell.X) + cellSize - 1,
this.offsetY + (cellSize * changedCell.Y));
}
break;
case "South":
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z]))
{
bitmapGraphics.DrawLine(Pens.LightGray, this.offsetX + (cellSize * changedCell.X) + 1,
this.offsetY + (cellSize * changedCell.Y) + cellSize,
this.offsetX + (cellSize * changedCell.X) + cellSize - 1,
this.offsetY + (cellSize * changedCell.Y) + cellSize);
}
break;
case "East":
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z]))
{
bitmapGraphics.DrawLine(Pens.LightGray, this.offsetX + (cellSize * changedCell.X) + cellSize,
this.offsetY + (cellSize * changedCell.Y) + 1,
this.offsetX + (cellSize * changedCell.X) + cellSize,
this.offsetY + (cellSize * changedCell.Y) + cellSize - 1);
}
break;
case "West":
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z]))
{
bitmapGraphics.DrawLine(Pens.LightGray, this.offsetX + (cellSize * changedCell.X),
this.offsetY + (cellSize * changedCell.Y) + 1,
this.offsetX + (cellSize * changedCell.X),
this.offsetY + (cellSize * changedCell.Y) + cellSize - 1);
}
break;
case "Ceiling":
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z]))
{
bitmapGraphics.DrawLine(Pens.Blue, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4);
bitmapGraphics.DrawLine(Pens.Blue, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 - 3,
this.offsetY + cellSize * changedCell.Y + cellSize / 4 + 3);
bitmapGraphics.DrawLine(Pens.Blue, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 + 3,
this.offsetY + cellSize * changedCell.Y + cellSize / 4 + 3);
}
using (Graphics bitmapGraphics = Graphics.FromImage(this.floorLevelBitmap[changedCell.Z + 1]))
{
bitmapGraphics.DrawLine(Pens.Red, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4);
bitmapGraphics.DrawLine(Pens.Red, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 - 3,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4 - 3);
bitmapGraphics.DrawLine(Pens.Red, this.offsetX + cellSize * changedCell.X + cellSize / 2,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4,
this.offsetX + cellSize * changedCell.X + cellSize / 2 + 3,
this.offsetY + cellSize * changedCell.Y + 3 * cellSize / 4 - 3);
}
break;
default:
generating = false;
break;
}
if (this.checkBoxRealTime.Checked)
{
// setting this will force the painting of the picture box
this.pictureBoxCanvas.Image = this.floorLevelBitmap[this.viewLevel - 1];
}
this.toolStripStatusLabel2.Text = String.Format("Generating maze...{0}%", (int)(generatorStepCount * 100 / generatorSteps));
this.toolStripProgressBar1.SetProgressNoAnimation(generatorStepCount++);
Application.DoEvents();
}
// fully restore the form to normal if not real-time viewing
this.labelViewingFloor.Enabled = true;
this.setLevelViewButtons();
this.pictureBoxCanvas.Image = this.floorLevelBitmap[this.viewLevel - 1];
this.pictureBoxCanvas.Visible = true;
this.pictureBoxCanvas.Enabled = true;
this.buttonGenerate.Enabled = true;
this.checkBoxRealTime.Enabled = true;
// remove the generation percentage and progress bar
this.toolStripStatusLabel2.Visible = false;
this.toolStripProgressBar1.Visible = false;
// finished message
this.toolStripStatusLabel1.Text = String.Format("Generation completed.");
// Re-cap
//
// START: maze generator returns the cell that it is changing and which wall is getting removed
// OPTIONAL: update the image of all cells on floor 0 to show the wall selected for removal
// OPTIONAL: update the image to show up/down steps in the cell where the floor/ceiling is selected for removal
// notify maze generator to perform action
// OPTIONAL: regenerate and show floor 0 of the maze
// notify maze generator to continue
// go back to START if there is more generation to perform
// at this point, the maze generation is completed
// all cells start out isolated with walls up to all neighbor cells
// create list of regions from the maze cells
// create image of all cells on floor 0 in the maze
// START: pick a random region from the region list
// create a list of all of the cells in the region
// create a list of all removable walls in the list of cells
// pick a random wall in the list of walls
// OPTIONAL: update the image of all cells on floor 0 to show the wall selected for removal
// OPTIONAL: update the image to show up/down steps in the cell where the floor/ceiling is selected for removal
// remove the wall from the containing cell
// remove the wall from the newly adjoining cell
// combine the region of the newly adjoining cell into the random region that was previously selected
// recreate the image of all cells on floor 0 in the maze
// go back to START if there is more than one remaining region
// at this point, the maze generation is completed
}
public static void Main()
{
// Print library information:
PrintInfo.PrintLibraryInfo();
// Enable network search:
Network.AutoDetectEnabled = true;
// Update device list:
DeviceList.Update();
// Try to open a generator:
Generator gen = null;
for (UInt32 i = 0; i < DeviceList.Count; i++)
{
DeviceListItem item = DeviceList.GetItemByIndex(i);
if (item.CanOpen(DeviceType.Generator))
{
gen = item.OpenGenerator();
break;
}
}
if (gen != null)
{
try
{
// Set signal type:
gen.SignalType = SignalType.Triangle;
// Set frequency:
gen.Frequency = 100e3; // 100 kHz
// Set amplitude:
gen.Amplitude = 2; // 2 V
// Set offset:
gen.Offset = 0; // 0 V
// Enable output:
gen.OutputOn = true;
// Print Generator info:
PrintInfo.PrintDeviceInfo(gen);
// Start signal generation
gen.Start();
// Wait for keystroke:
Console.WriteLine("Press Enter to stop signal generation...");
Console.ReadLine();
// Stop generator:
gen.Stop();
// Disable output:
gen.OutputOn = false;
}
catch (System.Exception e)
{
Console.WriteLine("Exception: " + e.Message);
Environment.Exit(1);
}
// Close generator:
gen.Dispose();
gen = null;
}
else
{
Console.WriteLine("No generator available!");
Environment.Exit(1);
}
Environment.Exit(0);
}
public static void Main()
{
// Print library information:
PrintInfo.PrintLibraryInfo();
// Enable network search:
Network.AutoDetectEnabled = true;
// Update device list:
DeviceList.Update();
// Try to open a generator with arbitrary support:
Generator gen = null;
for (UInt32 i = 0; i < DeviceList.Count; i++)
{
DeviceListItem item = DeviceList.GetItemByIndex(i);
if (item.CanOpen(DeviceType.Generator))
{
gen = item.OpenGenerator();
// Check for arbitrary support:
if ((gen.SignalTypes & Constants.ST_ARBITRARY) != 0)
{
break;
}
else
{
gen.Dispose();
gen = null;
}
}
}
if (gen != null)
{
try
{
// Set signal type:
gen.SignalType = SignalType.Arbitrary;
// Select frequency mode:
gen.FrequencyMode = FrequencyMode.SampleFrequency;
// Set frequency:
gen.Frequency = 100e3; // 100 kHz
// Set amplitude:
gen.Amplitude = 2; // 2 V
// Set offset:
gen.Offset = 0; // 0 V
// Enable output:
gen.OutputOn = true;
// Create signal array:
float[] data = new float[8192];
for (UInt16 i = 0; i < data.Length; i++)
{
data[i] = (float)(Math.Sin(i / 100.0) * (1 - (i / 8192.0)));
}
// Load the signal array into the generator:
gen.SetData(data);
// Print generator info:
PrintInfo.PrintDeviceInfo(gen);
// Start signal generation:
gen.Start();
// Wait for keystroke:
Console.WriteLine("Press Enter to stop signal generation...");
Console.ReadLine();
// Stop generator:
gen.Stop();
// Disable output:
gen.OutputOn = false;
}
catch (System.Exception e)
{
Console.WriteLine("Exception: " + e.Message);
Environment.Exit(1);
}
// Close generator:
gen.Dispose();
gen = null;
}
else
{
Console.WriteLine("No generator available with arbitrary support!");
Environment.Exit(1);
}
Environment.Exit(0);
}
