Let say we have an object:
#:checkDirty
class Test {
var a:Int;
var b(default, default):String;
var c(get, set):Array<Int>;
public function new() {
...
}
public function get_c() {
...
}
public function set_c(n) {
...
}
}
Could we write a macro checkDirty so that any change to field/properties would set property dirty to true. Macro would generate dirty field as Bool and clearDirty function to set it to false.
var test = new Test();
trace(test.dirty); // false
test.a = 12;
trace(test.dirty); // true
test.clearDirty();
trace(test.dirty); //false
test.b = "test"
trace(test.dirty); //true
test.clearDirty();
test.c = [1,2,3];
trace(test.dirty); //true
Just to note - whenever you consider proxying access to an object, in my experience, there are always hidden costs / added complexity. :)
That said, you have a few approaches:
First, if you want it to be pure Haxe, then either a macro or an abstract can get the job done. Either way, you're effectively transforming every property access into a function call that sets the value and also sets dirty.
For example, an abstract using the #:resolve getter and setter can be found in the NME source code, replicated here for convenience:
#:forward(decode,toString)
abstract URLVariables(URLVariablesBase)
{
public function new(?inEncoded:String)
{
this = new URLVariablesBase(inEncoded);
}
#:resolve
public function set(name:String, value:String) : String
{
return this.set(name,value);
}
#:resolve
public function get(name:String):String
{
return this.get(name);
}
}
This may be an older syntax, I'm not sure... also look at the operator overloading examples on the Haxe manual:
#:op(a.b) public function fieldRead(name:String)
return this.indexOf(name);
#:op(a.b) public function fieldWrite(name:String, value:String)
return this.split(name).join(value);
Second, I'd just point out that if the underlying language / runtime supports some kind of Proxy object (e.g. JavaScript Proxy), and macro / abstract isn't working as expected, then you could build your functionality on top of that.
I wrote a post (archive) about doing this kind of thing (except for emitting events) before - you can use a #:build macro to modify class members, be it appending an extra assignment into setter or replacing the field with a property.
So a modified version might look like so:
class Macro {
public static macro function build():Array<Field> {
var fields = Context.getBuildFields();
for (field in fields.copy()) { // (copy fields so that we don't go over freshly added ones)
switch (field.kind) {
case FVar(fieldType, fieldExpr), FProp("default", "default", fieldType, fieldExpr):
var fieldName = field.name;
if (fieldName == "dirty") continue;
var setterName = "set_" + fieldName;
var tmp_class = macro class {
public var $fieldName(default, set):$fieldType = $fieldExpr;
public function $setterName(v:$fieldType):$fieldType {
$i{fieldName} = v;
this.dirty = true;
return v;
}
};
for (mcf in tmp_class.fields) fields.push(mcf);
fields.remove(field);
case FProp(_, "set", t, e):
var setter = Lambda.find(fields, (f) -> f.name == "set_" + field.name);
if (setter == null) continue;
switch (setter.kind) {
case FFun(f):
f.expr = macro { dirty = true; ${f.expr}; };
default:
}
default:
}
}
if (Lambda.find(fields, (f) -> f.name == "dirty") == null) fields.push((macro class {
public var dirty:Bool = false;
}).fields[0]);
return fields;
}
}
which, if used as
#:build(Macro.build())
#:keep class Some {
public function new() {}
public var one:Int;
public var two(default, set):String;
function set_two(v:String):String {
two = v;
return v;
}
}
Would emit the following JS:
var Some = function() {
this.dirty = false;
};
Some.prototype = {
set_two: function(v) {
this.dirty = true;
this.two = v;
return v;
}
,set_one: function(v) {
this.one = v;
this.dirty = true;
return v;
}
};
I'm trying to use Teapot instead of the cube object in the object recognition sample app, but the Teapot is placed too far away from my target.
I will really appreciate any help.
Here is my ObjectTargetRenderer:
public class ObjectTargetRenderer implements GLSurfaceView.Renderer, SampleAppRendererControl
{
private static final String LOGTAG = "ObjectTargetRenderer";
private SampleApplicationSession vuforiaAppSession;
private ObjectTargets mActivity;
private SampleAppRenderer mSampleAppRenderer;
private Vector<Texture> mTextures;
private int shaderProgramID;
private int vertexHandle;
private int textureCoordHandle;
private int texSampler2DHandle;
private int mvpMatrixHandle;
private int opacityHandle;
private int colorHandle;
private CubeObject mCubeObject;
private Teapot mTeapot;
private Renderer mRenderer;
private boolean mIsActive = false;
public ObjectTargetRenderer(ObjectTargets activity,
SampleApplicationSession session)
{
mActivity = activity;
vuforiaAppSession = session;
// SampleAppRenderer used to encapsulate the use of RenderingPrimitives setting
// the device mode AR/VR and stereo mode
mSampleAppRenderer = new SampleAppRenderer(this, mActivity, Device.MODE.MODE_AR, false, 10f, 5000f);
}
// Called to draw the current frame.
#Override
public void onDrawFrame(GL10 gl)
{
if (!mIsActive)
return;
// Call our function to render content from SampleAppRenderer class
mSampleAppRenderer.render();
}
// Called when the surface is created or recreated.
#Override
public void onSurfaceCreated(GL10 gl, EGLConfig config)
{
Log.d(LOGTAG, "GLRenderer.onSurfaceCreated");
// Call Vuforia function to (re)initialize rendering after first use
// or after OpenGL ES context was lost (e.g. after onPause/onResume):
vuforiaAppSession.onSurfaceCreated();
mSampleAppRenderer.onSurfaceCreated();
}
// Called when the surface changed size.
#Override
public void onSurfaceChanged(GL10 gl, int width, int height)
{
Log.d(LOGTAG, "GLRenderer.onSurfaceChanged");
// Call Vuforia function to handle render surface size changes:
vuforiaAppSession.onSurfaceChanged(width, height);
// RenderingPrimitives to be updated when some rendering change is done
mSampleAppRenderer.onConfigurationChanged(mIsActive);
// Init rendering
initRendering();
}
public void setActive(boolean active)
{
mIsActive = active;
if(mIsActive)
mSampleAppRenderer.configureVideoBackground();
}
// Function for initializing the renderer.
private void initRendering()
{
// mCubeObject = new CubeObject();
mTeapot = new Teapot();
mRenderer = Renderer.getInstance();
// Now generate the OpenGL texture objects and add settings
for (Texture t : mTextures)
{
GLES20.glGenTextures(1, t.mTextureID, 0);
GLES20.glBindTexture(GLES20.GL_TEXTURE_2D, t.mTextureID[0]);
GLES20.glTexParameterf(GLES20.GL_TEXTURE_2D,
GLES20.GL_TEXTURE_MIN_FILTER, GLES20.GL_LINEAR);
GLES20.glTexParameterf(GLES20.GL_TEXTURE_2D,
GLES20.GL_TEXTURE_MAG_FILTER, GLES20.GL_LINEAR);
GLES20.glTexImage2D(GLES20.GL_TEXTURE_2D, 0, GLES20.GL_RGBA,
t.mWidth, t.mHeight, 0, GLES20.GL_RGBA,
GLES20.GL_UNSIGNED_BYTE, t.mData);
}
SampleUtils.checkGLError("ObjectTarget GLInitRendering");
GLES20.glClearColor(0.0f, 0.0f, 0.0f, Vuforia.requiresAlpha() ? 0.0f
: 1.0f);
shaderProgramID = SampleUtils.createProgramFromShaderSrc(
CubeShaders.CUBE_MESH_VERTEX_SHADER,
CubeShaders.CUBE_MESH_FRAGMENT_SHADER);
vertexHandle = GLES20.glGetAttribLocation(shaderProgramID,
"vertexPosition");
textureCoordHandle = GLES20.glGetAttribLocation(shaderProgramID,
"vertexTexCoord");
texSampler2DHandle = GLES20.glGetUniformLocation(shaderProgramID,
"texSampler2D");
mvpMatrixHandle = GLES20.glGetUniformLocation(shaderProgramID,
"modelViewProjectionMatrix");
opacityHandle = GLES20.glGetUniformLocation(shaderProgramID,
"opacity");
colorHandle = GLES20.glGetUniformLocation(shaderProgramID, "color");
// Hide the Loading Dialog
mActivity.loadingDialogHandler
.sendEmptyMessage(LoadingDialogHandler.HIDE_LOADING_DIALOG);
}
// The render function called from SampleAppRendering by using RenderingPrimitives views.
// The state is owned by SampleAppRenderer which is controlling it's lifecycle.
// State should not be cached outside this method.
public void renderFrame(State state, float[] projectionMatrix)
{
// Renders video background replacing Renderer.DrawVideoBackground()
mSampleAppRenderer.renderVideoBackground();
GLES20.glEnable(GLES20.GL_DEPTH_TEST);
GLES20.glEnable(GLES20.GL_CULL_FACE);
GLES20.glEnable(GLES20.GL_BLEND);
GLES20.glBlendFunc(GLES20.GL_SRC_ALPHA, GLES20.GL_ONE_MINUS_SRC_ALPHA);
// did we find any trackables this frame?
for (int tIdx = 0; tIdx < state.getNumTrackableResults(); tIdx++)
{
TrackableResult result = state.getTrackableResult(tIdx);
Trackable trackable = result.getTrackable();
printUserData(trackable);
if (!result.isOfType(ObjectTargetResult.getClassType()))
continue;
ObjectTarget objectTarget = (ObjectTarget) trackable;
Matrix44F modelViewMatrix_Vuforia = Tool
.convertPose2GLMatrix(result.getPose());
float[] modelViewMatrix = modelViewMatrix_Vuforia.getData();
// deal with the modelview and projection matrices
float[] modelViewProjection = new float[16];
float[] objectSize = objectTarget.getSize().getData();
Matrix.translateM(modelViewMatrix, 0, objectSize[0]/2, objectSize[1]/2,
objectSize[2]/2);
Matrix.scaleM(modelViewMatrix, 0, objectSize[0]/2,
objectSize[1]/2, objectSize[2]/2);
Matrix.multiplyMM(modelViewProjection, 0, projectionMatrix, 0, modelViewMatrix, 0);
// activatrigidBodyTarget.xmle the shader program and bind the vertex/normal/tex coords
GLES20.glUseProgram(shaderProgramID);
GLES20.glVertexAttribPointer(vertexHandle, 3, GLES20.GL_FLOAT,
false, 0, mTeapot.getVertices());
GLES20.glUniform1f(opacityHandle, 0.3f);
GLES20.glUniform3f(colorHandle, 0.0f, 0.0f, 0.0f);
GLES20.glVertexAttribPointer(textureCoordHandle, 2,
GLES20.GL_FLOAT, false, 0, mTeapot.getTexCoords());
GLES20.glEnableVertexAttribArray(vertexHandle);
GLES20.glEnableVertexAttribArray(textureCoordHandle);
GLES20.glActiveTexture(GLES20.GL_TEXTURE0);
GLES20.glBindTexture(GLES20.GL_TEXTURE_2D,
mTextures.get(0).mTextureID[0]);
GLES20.glUniformMatrix4fv(mvpMatrixHandle, 1, false,
modelViewProjection, 0);
GLES20.glUniform1i(texSampler2DHandle, 0);
// pass the model view matrix to the shader
GLES20.glUniformMatrix4fv(mvpMatrixHandle, 1, false,
modelViewProjection, 0);
// finally render
GLES20.glDrawElements(GLES20.GL_TRIANGLES,
mTeapot.getNumObjectIndex(), GLES20.GL_UNSIGNED_SHORT,
mTeapot.getIndices());
// disable the enabled arrays
GLES20.glDisableVertexAttribArray(vertexHandle);
GLES20.glDisableVertexAttribArray(textureCoordHandle);
SampleUtils.checkGLError("Render Frame");
}
GLES20.glDisable(GLES20.GL_DEPTH_TEST);
GLES20.glDisable(GLES20.GL_BLEND);
mRenderer.end();
}
private void printUserData(Trackable trackable)
{
String userData = (String) trackable.getUserData();
Log.d(LOGTAG, "UserData:Retreived User Data \"" + userData + "\"");
}
public void setTextures(Vector<Texture> textures)
{
mTextures = textures;
}
}
If the object is far, it could be that the Z translation or scaling is wrong. Check if your objectSize[2] is correct. Anyway, you can control the distance with Matrix.translateM (the last argument is Z)
I have a sprite that I can drag around on screen. I want to be able to drag this sprite into an area (box). As it stands now I can only drop the sprite into the box, but when I drag it directly inn, the the program crashes.
*Im developing in FlashDevelop but windows gave me av option to debug in VS.
I debugged in VS and got this ERROR:
Unhandled exception at 0x00ACCEE9 in Proj.exe: 0xC0000005: Access violation reading location 0x00000008.
Relevant code:
class Drag extends FlxGroup {
var mouseJoint:DistanceJoint;
public inline function registerPhysSprite(spr:FlxNapeSprite)
{
MouseEventManager.add(spr, createMouseJoint);
}
function createMouseJoint(spr:FlxSprite)
{
var body:Body = cast(spr, FlxNapeSprite).body;
mouseJoint = new DistanceJoint(FlxNapeState.space.world, body, new Vec2(FlxG.mouse.x, FlxG.mouse.y),
body.worldPointToLocal(new Vec2(FlxG.mouse.x, FlxG.mouse.y)), 0, 0);
mouseJoint.space = FlxNapeState.space;
}
override public function update():Void
{
super.update();
if (mouseJoint != null)
{
mouseJoint.anchor1 = new Vec2(FlxG.mouse.x, FlxG.mouse.y);
if (FlxG.mouse.justReleased)
{
mouseJoint.space = null;
}
}
}
}
class PlayState extends FlxNapeState {
override public function create()
{
super.create();
bgColor = FlxColor.BLACK;
napeDebugEnabled = true;
var light = new Light(10, 10);
var box = new Box(100, 100);
var drag:Drag;
createWalls(1, 1, 1024, 768, 10, new Material(1, 1, 2, 1, 0.001));
add(light);
add(box);
drag = new Drag();
add(drag);
drag.registerPhysSprite(light);
light.body.velocity.y = 200;
FlxNapeState.space.listeners.add(new InteractionListener(
CbEvent.BEGIN,
InteractionType.COLLISION,
Light.CB_TYPE,
Box.CB_TYPE,
collideLightBox));
}
function collideLightBox(callback:InteractionCallback)
{
var light:Light = cast callback.int1.castBody.userData.sprite;
light.kill();
}
}
class Light extends FlxNapeSprite {
public static var CB_TYPE(default, null) = new CbType();
public function new(x:Float, y:Float)
{
super(x, y);
makeGraphic(10, 10, FlxColor.TRANSPARENT);
var radius = 5;
drawCircle(5, 5, radius, FlxColor.WHITE);
createCircularBody(radius);
body.cbTypes.add(CB_TYPE);
body.userData.sprite = this;
}
}
class Box extends FlxNapeSprite {
public static var CB_TYPE(default, null) = new CbType();
public function new(x:Float, y:Float)
{
super(x, y);
makeGraphic(100, 50, FlxColor.GREEN);
createRectangularBody(width, height);
body.cbTypes.add(CB_TYPE);
body.type = BodyType.STATIC;
}
}
If you're possibly accessing a null pointer, consider the answer given in this question:
Why is this Haxe try-catch block still crashing, when using Release mode for C++ target
That way you can turn on null pointer checks in hxcpp so you can get better debug information.
Also, if you're trying to debug hxcpp directly in FlashDevelop (step-through and all that), that feature isn't released yet, but I spoke with the team recently and they're working on it.
Just ran into this issue in Haxe and was wondering if this was a bug or if it was done on purpose...
I was binding a function that prints a timestamp. The timestamp in this case was a getter in my globals class. I expected that if I were to wait a few seconds and then invoke the bound function, it would use the value of the getter at the time the function was bound. That was not the case. Instead, it seems to be calling the getter to get the current value each time.
I checked to see if this happens if I switched from using a getter to a normal function call to fetch my timestamp as my parameter. The latter works as expected.
function printTime(time:Int):Void {
trace("The time is: " + time);
}
var p:Void->Void = printTime.bind(Globals.timestampgetter);
var p2:Void->Void = printTime.bind(Global.timestampfunc());
// wait 5 seconds
p(); // prints CURRENT timestamp, i.e. adds the 5 seconds that passed
p2(); // prints time at which printTime.bind was called
EDIT:
Forgot to mention... I'm using Haxe 3.1.3 and OpenFL 3.0.0 beta, compiling to a Flash target.
After some more tries I reduced the test case to the following and I can confirm that it is a bug in the Flash generator. I reported it here: https://github.com/HaxeFoundation/haxe/issues/4089
class Test {
static function main() {
function printTime(time:Float)
trace("The time is: " + time);
timestamp = timestampfunc();
var t = timestampfunc();
var p1 = printTime.bind(timestamp);
var p2 = printTime.bind(t);
var p3 = printTime.bind(timestampfunc());
p1();
p2();
p3();
haxe.Timer.delay(function() {
t = timestamp = timestampfunc();
p1();
p2();
p3();
}, 1000);
}
public static var timestamp : Float;
static function timestampfunc() return Date.now().getTime();
}
I tried your code and it works as expected for me. The values are set at bind time and do not change even if you delay the calls of p and p2.
Here is the code I tested:
class Test {
static function main() {
function printTime(time:Float):Void {
trace("The time is: " + time);
}
var p = printTime.bind(Test.timestampgetter);
var p2 = printTime.bind(Test.timestampfunc());
p();
p2();
haxe.Timer.delay(function() {
p();
p2();
}, 1000);
}
public static var timestampgetter(get, null) : Float;
static function timestampfunc() return Date.now().getTime();
static function get_timestampgetter() return Date.now().getTime();
}
You can test it yourself here: http://try.haxe.org/#C85Ce
Interesting... the problem seems to stem from using "default" instead of "get" for the getter.
Franco's code works. But this code doesn't:
class Test {
static function main() {
function printTime(time:Float):Void {
trace("The time is: " + time);
}
updateTimestamp();
var p = printTime.bind(Test.timestampgetter);
var p2 = printTime.bind(Test.timestampfunc());
p();
p2();
haxe.Timer.delay(function() {
p();
p2();
}, 1000);
}
static function updateTimestamp():Void {
timestampgetter = Date.now().getTime();
haxe.Timer.delay(updateTimestamp, 1000);
}
public static var timestampgetter(default, null) : Float;
static function timestampfunc() return Date.now().getTime();
static function get_timestampgetter() return Date.now().getTime();
}
I'm trying to write a simple property grid to allow the users to modify the colours of a Chart. By default, a Chart has a "Palette" property, which is of the enumeration type "ChartColorPalette". If the object which underlies my property grid also has a "Palette" property of the same type, I get the drop-down list of possible values. What I don't get however, is the little stripey images to the left of the value names.
Now, I can write a UITypeEditor derived class and have the "PaintValue" draw little resource bitmaps which I have culled from the screen using "Paint" or somesuch, but this seems rather tedious.
Does anyone know if there is already a type editor for the "ChartColorPalette" enumeration which I can use to get the little bitmaps ?
as it happens, writing the UITypeEditor is not that tricky, and not that much code either.
Firstly I created a type editor that looked like this:
private class ChartColorPaletteEditor : UITypeEditor
{
public override bool GetPaintValueSupported(ITypeDescriptorContext context)
{
return true;
}
public override void PaintValue(PaintValueEventArgs e)
{
String paletteName = e.Value.ToString();
String baseName = this.GetType().Namespace + ".MyChart";
ResourceManager mgr = new ResourceManager(baseName, this.GetType().Assembly);
Bitmap bmp = mgr.GetObject(paletteName) as Bitmap;
if (bmp != null)
{
e.Graphics.DrawImage(bmp, e.Bounds);
bmp.Dispose();
}
}
}
I attached this to my control property in the usual way:
[DefaultValue(typeof(ChartColorPalette), "BrightPastel")]
[Editor(typeof(ChartColorPaletteEditor), typeof(System.Drawing.Design.UITypeEditor))]
[Category("Appearance")]
[Description("The named palette to use when choosing the colour scheme for the chart series lines.")]
public ChartColorPalette Palette { get; set; }
Then I added a small PNG resource for each of the little palette images. I had a derived control "MyChart" which inherited from "Chart" and I added the images to that as resources (making sure to set the "Persistance" property to "Embedded in .resx" to save having to keep the PNG files about). The names of the PNG files matched the names in the ChartColorPalette enumeration.
The only issue was where to get the little 20 x 14 images from. I originally just culled them using Paint.exe but didn't like that, so I wrote some code to generate them for me. That was fairly simple, once I had found the colour values that are used by the Charting control. One subtlety is that, where there are more than 12 colours in a palette, the little bitmap uses every other colour. That code looked like this:
using System;
using System.Drawing;
using System.Drawing.Imaging;
using System.IO;
using System.Reflection;
using System.Windows.Forms.DataVisualization.Charting;
namespace ConsoleApplication10
{
class Program
{
static void Main(string[] args)
{
Enum.GetValues(typeof(ChartColorPalette)).OfType<ChartColorPalette>().ToList().ForEach(GeneratePNG);
}
static void GeneratePNG(ChartColorPalette palette)
{
if (palette == ChartColorPalette.None) return;
Color[] colours = palette.GetColors();
if (colours.Length >= 12)
{
colours = new Color[] { colours[0], colours[2], colours[4], colours[6], colours[8], colours[10] };
}
else
{
colours = new Color[] { colours[0], colours[1], colours[2], colours[3], colours[4], colours[5] };
}
using (Bitmap bmp = new Bitmap(20, 14))
{
using (Graphics gr = Graphics.FromImage(bmp))
{
using (SolidBrush b1 = new SolidBrush(colours[0]),
b2 = new SolidBrush(colours[1]),
b3 = new SolidBrush(colours[2]),
b4 = new SolidBrush(colours[3]),
b5 = new SolidBrush(colours[4]),
b6 = new SolidBrush(colours[5]))
{
int height = bmp.Height - 2;
gr.DrawRectangle(Pens.Black, 0, 0, bmp.Width - 1, bmp.Height - 1);
gr.FillRectangle(b1, new Rectangle(1, 1, 3, height));
gr.FillRectangle(b2, new Rectangle(4, 1, 3, height));
gr.FillRectangle(b3, new Rectangle(7, 1, 3, height));
gr.FillRectangle(b4, new Rectangle(10, 1, 3, height));
gr.FillRectangle(b5, new Rectangle(13, 1, 3, height));
gr.FillRectangle(b6, new Rectangle(16, 1, 3, height));
}
}
String path = System.Environment.GetFolderPath(Environment.SpecialFolder.MyDocuments);
path = Path.Combine(path, #"Visual Studio 2010\Projects\DataVisualization.Charting\Palette Bitmaps");
String filename = palette.ToString() + ".png";
bmp.Save(Path.Combine(path, filename), ImageFormat.Png);
}
}
}
public static class Extensions
{
public static Color[] GetColors(this ChartColorPalette value)
{
switch (value)
{
case ChartColorPalette.Berry:
return GetColors(0x8a2be2, 0xba55d3, 0x4169e1, 0xc71585, 0x0000ff, 0x8a2be2, 0xda70d6, 0x7b68ee, 0xc000c0, 0x0000cd, 0x800080);
case ChartColorPalette.Bright:
return GetColors(0x008000, 0x0000ff, 0x800080, 0x00ff00, 0xff00ff, 0x008080, 0xffff00, 0x808080, 0x00ffff, 0x000080, 0x800000, 0xff0000, 0x808000, 0xc0c0c0, 0xff6347, 0xffe4b5);
case ChartColorPalette.BrightPastel:
return GetColors(0x418cf0, 0xfcb441, 0xe0400a, 0x056492, 0xbfbfbf, 0x1a3b69, 0xffe382, 0x129cdd, 0xca6b4b, 0x005cdb, 0xf3d288, 0x506381, 0xf1b9a8, 0xe0830a, 0x7893be);
case ChartColorPalette.Chocolate:
return GetColors(0xa0522d, 0xd2691e, 0x8b0000, 0xcd853f, 0xa52a2a, 0xf4a460, 0x8b4513, 0xc04000, 0xb22222, 0xb65c3a);
case ChartColorPalette.EarthTones:
return GetColors(0xff8000, 0xb8860b, 0xc04000, 0x6b8e23, 0xcd853f, 0xc0c000, 0x228b22, 0xd2691e, 0x808000, 0x20b2aa, 0xf4a460, 0x00c000, 0x8fbc8b, 0xb22222, 0x8b4513, 0xc00000);
case ChartColorPalette.Excel:
return GetColors(0x9999ff, 0x993366, 0xffffcc, 0xccffff, 0x660066, 0xff8080, 0x0066cc, 0xccccff, 0x000080, 0xff00ff, 0xffff00, 0x00ffff, 0x800080, 0x800000, 0x008080, 0x0000ff);
case ChartColorPalette.Fire:
return GetColors(0xffd700, 0xff0000, 0xff1493, 0xdc143c, 0xff8c00, 0xff00ff, 0xffff00, 0xff4500, 0xc71585, 0xdde221);
case ChartColorPalette.Grayscale:
return GetColors(0xc8c8c8, 0xbdbdbd, 0xb2b2b2, 0xa7a7a7, 0x9c9c9c, 0x919191, 0x868686, 0x7b7b7b, 0x707070, 0x656565, 0x5a5a5a, 0x4f4f4f, 0x444444, 0x393939, 0x2e2e2e, 0x232323);
case ChartColorPalette.Light:
return GetColors(0xe6e6fa, 0xfff0f5, 0xffdab9, 0xfffacd, 0xffe4e1, 0xf0fff0, 0xf0f8ff, 0xf5f5f5, 0xfaebd7, 0xe0ffff);
case ChartColorPalette.Pastel:
return GetColors(0x87ceeb, 0x32cd32, 0xba55d3, 0xf08080, 0x4682b4, 0x9acd32, 0x40e0d0, 0xff69b4, 0xf0e68c, 0xd2b48c, 0x8fbc8b, 0x6495ed, 0xdda0dd, 0x5f9ea0, 0xffdab9, 0xffa07a);
case ChartColorPalette.SeaGreen:
return GetColors(0x2e8b57, 0x66cdaa, 0x4682b4, 0x008b8b, 0x5f9ea0, 0x3cb371, 0x48d1cc, 0xb0c4de, 0xffffff, 0x87ceeb);
case ChartColorPalette.SemiTransparent:
return GetColors(0xff6969, 0x69ff69, 0x6969ff, 0xffff69, 0x69ffff, 0xff69ff, 0xcdb075, 0xffafaf, 0xafffaf, 0xafafff, 0xffffaf, 0xafffff, 0xffafff, 0xe4d5b5, 0xa4b086, 0x819ec1);
case ChartColorPalette.None:
default:
return GetColors(0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000);
}
}
private static Color[] GetColors(params Int32[] values)
{
return values.Select(value => Color.FromArgb(255, Color.FromArgb(value))).ToArray(); // alpha channel of 255 for fully opaque
}
}
}
Hope this is useful to someone out there...