public override void draw()
        {
            CCTMXTiledMap map = (CCTMXTiledMap)getChildByTag(1);
            CCTMXObjectGroup group = map.objectGroupNamed("Object Group 1");

            List<Dictionary<string, string>> objects = group.Objects;
            Dictionary<string, string> dict;

            for (int i = 0; i < objects.Count; i++)
            {
                dict = objects[i];//dynamic_cast<CCStringToStringDictionary*>(*it);

                if (dict == null)
                    break;
                string key = "x";
                int x = int.Parse(dict[key]);//dynamic_cast<NSNumber*>(dict->objectForKey("x"))->getNumber();
                key = "y";
                int y = int.Parse(dict[key]);//dynamic_cast<NSNumber*>(dict->objectForKey("y"))->getNumber();
                key = "width";
                int width = int.Parse(dict[key]);//dynamic_cast<NSNumber*>(dict->objectForKey("width"))->getNumber();
                key = "height";
                int height = int.Parse(dict[key]);//dynamic_cast<NSNumber*>(dict->objectForKey("height"))->getNumber();

                //glLineWidth(3);

                ccColor4F color = new ccColor4F(255, 255, 255, 255);

                CCDrawingPrimitives.ccDrawLine(new CCPoint(x, y), new CCPoint(x + width, y), color);
                CCDrawingPrimitives.ccDrawLine(new CCPoint(x + width, y), new CCPoint(x + width, y + height), color);
                CCDrawingPrimitives.ccDrawLine(new CCPoint(x + width, y + height), new CCPoint(x, y + height), color);
                CCDrawingPrimitives.ccDrawLine(new CCPoint(x, y + height), new CCPoint(x, y), color);

                //glLineWidth(1);
            }
        }
示例#2
0
 public static bool ccc4FEqual(ccColor4F a, ccColor4F b)
 {
     if (a.r != b.r || a.g != b.g || a.b != b.b)
     {
         return(false);
     }
     return(a.a == b.a);
 }
示例#3
0
 public CCParticle()
 {
     this.pos        = new CCPoint();
     this.startPos   = new CCPoint();
     this.color      = new ccColor4F();
     this.deltaColor = new ccColor4F();
     this.modeA      = new CCParticle.sModeA();
     this.modeB      = new CCParticle.sModeB();
 }
        public override void doTest()
        {
            CCSize s = CCDirector.sharedDirector().getWinSize();
            CCParticleSystem particleSystem = (CCParticleSystem)getChildByTag(PerformanceParticleTest.kTagParticleSystem);

            // duration
            particleSystem.Duration = -1;

            // gravity
            particleSystem.setGravity(new CCPoint(0, -90));

            // angle
            particleSystem.Angle = 90;
            particleSystem.AngleVar = 0;

            // radial
            particleSystem.setRadialAccel(0);
            particleSystem.setRadialAccelVar(0);

            // speed of particles
            particleSystem.setSpeed(180);
            particleSystem.setSpeedVar(50);

            // emitter position
            particleSystem.position = new CCPoint(s.width / 2, 100);
            particleSystem.PosVar = new CCPoint(s.width / 2, 0);

            // life of particles
            particleSystem.Life = 2.0f;
            particleSystem.LifeVar = 1;

            // emits per frame
            particleSystem.EmissionRate = particleSystem.TotalParticles / particleSystem.Life;

            // color of particles
            ccColor4F startColor = new ccColor4F { r = 0.5f, g = 0.5f, b = 0.5f, a = 1.0f };
            particleSystem.StartColor = startColor;

            ccColor4F startColorVar = new ccColor4F { r = 0.5f, g = 0.5f, b = 0.5f, a = 1.0f };
            particleSystem.StartColorVar = startColorVar;

            ccColor4F endColor = new ccColor4F { r = 0.1f, g = 0.1f, b = 0.1f, a = 0.2f };
            particleSystem.EndColor = endColor;

            ccColor4F endColorVar = new ccColor4F { r = 0.1f, g = 0.1f, b = 0.1f, a = 0.2f };
            particleSystem.EndColorVar = endColorVar;

            // size, in pixels
            particleSystem.EndSize = 32.0f;
            particleSystem.StartSize = 32.0f;
            particleSystem.EndSizeVar = 0;
            particleSystem.StartSizeVar = 0;

            // additive
            particleSystem.IsBlendAdditive = false;
        }
示例#5
0
        public static void ccDrawLine(CCPoint origin, CCPoint destination, ccColor4F color)
        {
            float contentScaleFactor = CCDirector.sharedDirector().ContentScaleFactor;

            VertexPositionColor[] vertexPositionColor = new VertexPositionColor[] { new VertexPositionColor(new Vector3(origin.x * contentScaleFactor, origin.y * contentScaleFactor, 0f), new Color(color.r, color.g, color.b, color.a)), new VertexPositionColor(new Vector3(destination.x * contentScaleFactor, destination.y * contentScaleFactor, 0f), new Color(color.r, color.g, color.b, color.a)) };
            CCApplication         cCApplication       = CCApplication.sharedApplication();

            cCApplication.basicEffect.TextureEnabled     = false;
            cCApplication.basicEffect.VertexColorEnabled = true;
            foreach (EffectPass pass in cCApplication.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();
                cCApplication.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineList, vertexPositionColor, 0, 1);
            }
        }
        /// <summary>
        /// draws a line given the origin and destination point measured in points
        /// </summary>
        public static void ccDrawLine(CCPoint origin, CCPoint destination, ccColor4F color)
        {
            float factor = CCDirector.sharedDirector().ContentScaleFactor;

            VertexPositionColor[] vertices = new VertexPositionColor[2];
            vertices[0] = new VertexPositionColor(new Vector3(origin.x * factor, origin.y * factor, 0), new Color(color.r, color.g, color.b, color.a));
            vertices[1] = new VertexPositionColor(new Vector3(destination.x * factor, destination.y * factor, 0), new Color(color.r, color.g, color.b, color.a));

            CCApplication app = CCApplication.sharedApplication();
            app.basicEffect.TextureEnabled = false;
            app.basicEffect.VertexColorEnabled = true;
            foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();

                app.GraphicsDevice.DrawUserPrimitives<VertexPositionColor>(PrimitiveType.LineList, vertices, 0, 1);
            }
        }
 public CCParticle()
 {
     pos = new CCPoint();
     startPos = new CCPoint();
     color = new ccColor4F();
     deltaColor = new ccColor4F();
     modeA = new sModeA();
     modeB = new sModeB();
 }
示例#8
0
 /** Returns a ccColor4F from a ccColor4B.
  @since v0.99.1
  */
 public static ccColor4F ccc4FFromccc4B(ccColor4B c)
 {
     ccColor4F c4 = new ccColor4F(c.r / 255.0f, c.g / 255.0f, c.b / 255.0f, c.a / 255.0f);
     return c4;
 }
        public override void onEnter()
        {
            base.onEnter();

            Color = new ccColor3B(0,0,0);
            removeChild(m_background, true);
            m_background = null;

            m_emitter = new CCParticleSystemQuad();
            m_emitter.initWithTotalParticles(100);
            addChild(m_emitter, 10);
            m_emitter.Texture = CCTextureCache.sharedTextureCache().addImage("Images/fire");

            // duration
            m_emitter.Duration = (float)eParticleShowingProperty.kCCParticleDurationInfinity;

            // radius mode
            m_emitter.EmitterMode = (int)eParticleMode.kCCParticleModeRadius;

            // radius mode: start and end radius in pixels
            m_emitter.setStartRadius(50);
            m_emitter.setStartRadiusVar(0);
            m_emitter.setEndRadius((float)eParticleShowingProperty.kCCParticleStartRadiusEqualToEndRadius);
            m_emitter.setEndRadiusVar(0);

            // radius mode: degrees per second
            m_emitter.setRotatePerSecond(0);
            m_emitter.setRotatePerSecondVar(0);

            // angle
            m_emitter.Angle = 90;
            m_emitter.AngleVar = 0;

            // emitter position
            CCSize size = CCDirector.sharedDirector().getWinSize();
            m_emitter.position = new CCPoint(size.width/2, size.height/2);
            m_emitter.PosVar = new CCPoint(0,0);

            // life of particles
            m_emitter.Life = 5;
            m_emitter.LifeVar = 0;

            // spin of particles
            m_emitter.StartSpin = 0;
            m_emitter.StartSpinVar = 0;
            m_emitter.EndSpin = 0;
            m_emitter.EndSpinVar = 0;

            // color of particles
            ccColor4F startColor = new ccColor4F(0.5f, 0.5f, 0.5f, 1.0f);
            m_emitter.StartColor = startColor;

            ccColor4F startColorVar = new ccColor4F(0.5f, 0.5f, 0.5f, 1.0f);
            m_emitter.StartColorVar = startColorVar;

                ccColor4F endColor = new ccColor4F(0.1f, 0.1f, 0.1f, 0.2f);
            m_emitter.EndColor = endColor;

            ccColor4F endColorVar = new ccColor4F(0.1f, 0.1f, 0.1f, 0.2f);
            m_emitter.EndColorVar = endColorVar;

            // size, in pixels
            m_emitter.StartSize = 16;
            m_emitter.StartSizeVar = 0;
            m_emitter.EndSize = (float)eParticleShowingProperty.kCCParticleStartSizeEqualToEndSize;

            // emits per second
            m_emitter.EmissionRate = m_emitter.TotalParticles / m_emitter.Life;

            // additive
            m_emitter.IsBlendAdditive = false;

            CCRotateBy rot = CCRotateBy.actionWithDuration(16, 360);
            m_emitter.runAction(CCRepeatForever.actionWithAction(rot));
        }
示例#10
0
        public override void onEnter()
        {
            base.onEnter();

            m_emitter = new CCParticleSystemPoint();
            m_emitter.initWithTotalParticles(1000);
            //m_emitter.autorelease();

            m_background.addChild(m_emitter, 10);
            ////m_emitter.release();

            CCSize s = CCDirector.sharedDirector().getWinSize();

            // duration
            m_emitter.Duration = -1;

            // gravity
            m_emitter.setGravity(new CCPoint(0, 0));

            // angle
            m_emitter.Angle = 0;
            m_emitter.AngleVar = 360;

            // radial
            m_emitter.setRadialAccel(70);
            m_emitter.setRadialAccelVar(10);

            // tagential
            m_emitter.setTangentialAccel(80);
            m_emitter.setTangentialAccelVar(0);

            // speed of particles
            m_emitter.setSpeed(50);
            m_emitter.setSpeedVar(10);

            // emitter position
            m_emitter.position = new CCPoint(s.width / 2, s.height / 2);
            m_emitter.PosVar = new CCPoint(0, 0);

            // life of particles
            m_emitter.Life = 2.0f;
            m_emitter.LifeVar = 0.3f;

            // emits per frame
            m_emitter.EmissionRate = m_emitter.TotalParticles / m_emitter.Life;

            // color of particles
            ccColor4F startColor = new ccColor4F(0.5f, 0.5f, 0.5f, 1.0f);
            m_emitter.StartColor = startColor;

            ccColor4F startColorVar = new ccColor4F(0.5f, 0.5f, 0.5f, 1.0f);
            m_emitter.StartColorVar = startColorVar;

            ccColor4F endColor = new ccColor4F(0.1f, 0.1f, 0.1f, 0.2f);
            m_emitter.EndColor = endColor;

            ccColor4F endColorVar = new ccColor4F(0.1f, 0.1f, 0.1f, 0.2f);
            m_emitter.EndColorVar = endColorVar;

            // size, in pixels
            m_emitter.StartSize = 1.0f;
            m_emitter.StartSizeVar = 1.0f;
            m_emitter.EndSize = 32.0f;
            m_emitter.EndSizeVar = 8.0f;

            // texture
            m_emitter.Texture = CCTextureCache.sharedTextureCache().addImage(TestResource.s_fire);

            // additive
            m_emitter.IsBlendAdditive = false;

            setEmitterPosition();
        }
        /// <summary>
        /// draws a polygon given a pointer to CCPoint coordiantes and the number of vertices measured in points.
        /// The polygon can be closed or open and optionally filled with current GL color
        /// </summary>
        public static void ccDrawPoly(CCPoint[] vertices, int numOfVertices, bool closePolygon, bool fill, ccColor4F color)
        {
            VertexPositionColor[] newPoint = new VertexPositionColor[numOfVertices + 1];
            for (int i = 0; i < numOfVertices; i++)
            {
                newPoint[i] = new VertexPositionColor();
                newPoint[i].Position = new Vector3(vertices[i].x, vertices[i].y, 0);
                newPoint[i].Color = new Color(color.r, color.g, color.b, color.a);
            }

            CCApplication app = CCApplication.sharedApplication();
            app.GraphicsDevice.RasterizerState = new RasterizerState() { CullMode = CullMode.None };
            app.basicEffect.TextureEnabled = false;
            app.basicEffect.VertexColorEnabled = true;

            short[] indexes = new short[(numOfVertices - 2) * 3];
            if (fill)
            {
                for (int i = 0; i < numOfVertices - 2; i++)
                {
                    indexes[i * 3 + 0] = 0;
                    indexes[i * 3 + 1] = (short)(i + 2);
                    indexes[i * 3 + 2] = (short)(i + 1);
                }

                foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
                {
                    pass.Apply();

                    app.GraphicsDevice.DrawUserIndexedPrimitives<VertexPositionColor>(PrimitiveType.TriangleStrip,
                        newPoint, 0, numOfVertices,
                        indexes, 0, numOfVertices - 2);
                }
            }
            else
            {
                if (closePolygon)
                {
                    newPoint[numOfVertices] = newPoint[0];
                    numOfVertices += 1;
                }

                foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
                {
                    pass.Apply();

                    app.GraphicsDevice.DrawUserPrimitives<VertexPositionColor>(PrimitiveType.LineStrip,
                          newPoint, 0, numOfVertices - 1);
                }
            }

            //if (closePolygon)
            //{
            //    glDrawArrays(fill ? GL_TRIANGLE_FAN : GL_LINE_LOOP, 0, numberOfPoints);
            //}
            //else
            //{
            //    glDrawArrays(fill ? GL_TRIANGLE_FAN : GL_LINE_STRIP, 0, numberOfPoints);
            //}
        }
        /// <summary>
        /// draws a cubic bezier path
        /// @since v0.8
        /// </summary>
        public static void ccDrawCubicBezier(CCPoint origin, CCPoint control1, CCPoint control2, CCPoint destination, int segments, ccColor4F color)
        {
            VertexPositionColor[] vertices = new VertexPositionColor[segments + 1];
            float factor = CCDirector.sharedDirector().ContentScaleFactor;
            CCApplication app = CCApplication.sharedApplication();

            float t = 0;
            for (int i = 0; i < segments; ++i)
            {
                float x = (float)Math.Pow(1 - t, 3) * origin.x + 3.0f * (float)Math.Pow(1 - t, 2) * t * control1.x + 3.0f * (1 - t) * t * t * control2.x + t * t * t * destination.x;
                float y = (float)Math.Pow(1 - t, 3) * origin.y + 3.0f * (float)Math.Pow(1 - t, 2) * t * control1.y + 3.0f * (1 - t) * t * t * control2.y + t * t * t * destination.y;
                vertices[i] = new VertexPositionColor();
                vertices[i].Position = new Vector3(x * factor, y * factor, 0);
                vertices[i].Color = new Color(color.r, color.g, color.b, color.a);
                t += 1.0f / segments;
            }
            vertices[segments] = new VertexPositionColor()
            {
                Color = new Color(color.r, color.g, color.b, color.a),
                Position = new Vector3(destination.x * factor, destination.y * factor, 0)
            };

            app.basicEffect.TextureEnabled = false;
            app.basicEffect.VertexColorEnabled = true;
            foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();

                app.GraphicsDevice.DrawUserPrimitives<VertexPositionColor>(PrimitiveType.LineStrip, vertices, 0, segments);
            }

            // Default GL states: GL_TEXTURE_2D, GL_VERTEX_ARRAY, GL_COLOR_ARRAY, GL_TEXTURE_COORD_ARRAY
            // Needed states: GL_VERTEX_ARRAY,
            // Unneeded states: GL_TEXTURE_2D, GL_TEXTURE_COORD_ARRAY, GL_COLOR_ARRAY
            //glDisable(GL_TEXTURE_2D);
            //glDisableClientState(GL_TEXTURE_COORD_ARRAY);
            //glDisableClientState(GL_COLOR_ARRAY);

            //glVertexPointer(2, GL_FLOAT, 0, vertices);
            //glDrawArrays(GL_LINE_STRIP, 0, (GLsizei)segments + 1);
            //delete[] vertices;

            //// restore default state
            //glEnableClientState(GL_COLOR_ARRAY);
            //glEnableClientState(GL_TEXTURE_COORD_ARRAY);
            //glEnable(GL_TEXTURE_2D);
        }
示例#13
0
        public static ccColor4F ccc4FFromccc4B(ccColor4B c)
        {
            ccColor4F _ccColor4F = new ccColor4F((float)c.r / 255f, (float)c.g / 255f, (float)c.b / 255f, (float)c.a / 255f);

            return(_ccColor4F);
        }
示例#14
0
        public static void ccDrawCubicBezier(CCPoint origin, CCPoint control1, CCPoint control2, CCPoint destination, int segments, ccColor4F color)
        {
            VertexPositionColor[] vector3    = new VertexPositionColor[segments + 1];
            float         contentScaleFactor = CCDirector.sharedDirector().ContentScaleFactor;
            CCApplication cCApplication      = CCApplication.sharedApplication();
            float         single             = 0f;

            for (int i = 0; i < segments; i++)
            {
                float single1 = (float)Math.Pow((double)(1f - single), 3) * origin.x + 3f * (float)Math.Pow((double)(1f - single), 2) * single * control1.x + 3f * (1f - single) * single * single * control2.x + single * single * single * destination.x;
                float single2 = (float)Math.Pow((double)(1f - single), 3) * origin.y + 3f * (float)Math.Pow((double)(1f - single), 2) * single * control1.y + 3f * (1f - single) * single * single * control2.y + single * single * single * destination.y;
                vector3[i]          = new VertexPositionColor();
                vector3[i].Position = new Vector3(single1 * contentScaleFactor, single2 * contentScaleFactor, 0f);
                vector3[i].Color    = new Color(color.r, color.g, color.b, color.a);
                single = single + 1f / (float)segments;
            }
            VertexPositionColor vertexPositionColor = new VertexPositionColor()
            {
                Color    = new Color(color.r, color.g, color.b, color.a),
                Position = new Vector3(destination.x * contentScaleFactor, destination.y * contentScaleFactor, 0f)
            };

            vector3[segments] = vertexPositionColor;
            cCApplication.basicEffect.TextureEnabled     = false;
            cCApplication.basicEffect.VertexColorEnabled = true;
            foreach (EffectPass pass in cCApplication.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();
                cCApplication.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineStrip, vector3, 0, segments);
            }
        }
示例#15
0
        public static void ccDrawPoly(CCPoint[] vertices, int numOfVertices, bool closePolygon, bool fill, ccColor4F color)
        {
            VertexPositionColor[] vector3 = new VertexPositionColor[numOfVertices + 1];
            for (int i = 0; i < numOfVertices; i++)
            {
                vector3[i]          = new VertexPositionColor();
                vector3[i].Position = new Vector3(vertices[i].x, vertices[i].y, 0f);
                vector3[i].Color    = new Color(color.r, color.g, color.b, color.a);
            }
            CCApplication rasterizerState = CCApplication.sharedApplication();

            rasterizerState.GraphicsDevice.RasterizerState = new RasterizerState()
            {
                CullMode = CullMode.None
            };
            rasterizerState.basicEffect.TextureEnabled     = false;
            rasterizerState.basicEffect.VertexColorEnabled = true;
            short[] numArray = new short[(numOfVertices - 2) * 3];
            if (!fill)
            {
                if (closePolygon)
                {
                    vector3[numOfVertices] = vector3[0];
                    numOfVertices++;
                }
                foreach (EffectPass pass in rasterizerState.basicEffect.CurrentTechnique.Passes)
                {
                    pass.Apply();
                    rasterizerState.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineStrip, vector3, 0, numOfVertices - 1);
                }
            }
            else
            {
                for (int j = 0; j < numOfVertices - 2; j++)
                {
                    numArray[j * 3]     = 0;
                    numArray[j * 3 + 1] = (short)(j + 2);
                    numArray[j * 3 + 2] = (short)(j + 1);
                }
                foreach (EffectPass effectPass in rasterizerState.basicEffect.CurrentTechnique.Passes)
                {
                    effectPass.Apply();
                    rasterizerState.GraphicsDevice.DrawUserIndexedPrimitives <VertexPositionColor>(PrimitiveType.TriangleStrip, vector3, 0, numOfVertices, numArray, 0, numOfVertices - 2);
                }
            }
        }
示例#16
0
        /** Returns a ccColor4F from a ccColor4B.
         * @since v0.99.1
         */
        public static ccColor4F ccc4FFromccc4B(ccColor4B c)
        {
            ccColor4F c4 = new ccColor4F(c.r / 255.0f, c.g / 255.0f, c.b / 255.0f, c.a / 255.0f);

            return(c4);
        }
示例#17
0
 /** returns YES if both ccColor4F are equal. Otherwise it returns NO.
  * @since v0.99.1
  */
 public static bool ccc4FEqual(ccColor4F a, ccColor4F b)
 {
     return(a.r == b.r && a.g == b.g && a.b == b.b && a.a == b.a);
 }
示例#18
0
        public void initParticle(CCParticle particle)
        {
            particle.timeToLive = this.m_fLife + (this.m_fLifeVar * ccMacros.CCRANDOM_MINUS1_1());
            particle.timeToLive = (0f > particle.timeToLive) ? 0f : particle.timeToLive;
            particle.pos.x      = this.m_tSourcePosition.x + (this.m_tPosVar.x * ccMacros.CCRANDOM_MINUS1_1());
            particle.pos.x     *= CCDirector.sharedDirector().ContentScaleFactor;
            particle.pos.y      = this.m_tSourcePosition.y + (this.m_tPosVar.y * ccMacros.CCRANDOM_MINUS1_1());
            particle.pos.y     *= CCDirector.sharedDirector().ContentScaleFactor;
            ccColor4F colorf = new ccColor4F
            {
                r = CCPointExtension.clampf(this.m_tStartColor.r + (this.m_tStartColorVar.r * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
                g = CCPointExtension.clampf(this.m_tStartColor.g + (this.m_tStartColorVar.g * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
                b = CCPointExtension.clampf(this.m_tStartColor.b + (this.m_tStartColorVar.b * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
                a = CCPointExtension.clampf(this.m_tStartColor.a + (this.m_tStartColorVar.a * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f)
            };
            ccColor4F colorf2 = new ccColor4F
            {
                r = CCPointExtension.clampf(this.m_tEndColor.r + (this.m_tEndColorVar.r * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
                g = CCPointExtension.clampf(this.m_tEndColor.g + (this.m_tEndColorVar.g * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
                b = CCPointExtension.clampf(this.m_tEndColor.b + (this.m_tEndColorVar.b * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f),
                a = CCPointExtension.clampf(this.m_tEndColor.a + (this.m_tEndColorVar.a * ccMacros.CCRANDOM_MINUS1_1()), 0f, 1f)
            };

            particle.color        = colorf;
            particle.deltaColor.r = (colorf2.r - colorf.r) / particle.timeToLive;
            particle.deltaColor.g = (colorf2.g - colorf.g) / particle.timeToLive;
            particle.deltaColor.b = (colorf2.b - colorf.b) / particle.timeToLive;
            particle.deltaColor.a = (colorf2.a - colorf.a) / particle.timeToLive;
            float num = this.m_fStartSize + (this.m_fStartSizeVar * ccMacros.CCRANDOM_MINUS1_1());

            num           = (0f > num) ? 0f : num;
            num          *= CCDirector.sharedDirector().ContentScaleFactor;
            particle.size = num;
            if (this.m_fEndSize == -1f)
            {
                particle.deltaSize = 0f;
            }
            else
            {
                float num2 = this.m_fEndSize + (this.m_fEndSizeVar * ccMacros.CCRANDOM_MINUS1_1());
                num2  = (0f > num2) ? 0f : num2;
                num2 *= CCDirector.sharedDirector().ContentScaleFactor;
                particle.deltaSize = (num2 - num) / particle.timeToLive;
            }
            float num3 = this.m_fStartSpin + (this.m_fStartSpinVar * ccMacros.CCRANDOM_MINUS1_1());
            float num4 = this.m_fEndSpin + (this.m_fEndSpinVar * ccMacros.CCRANDOM_MINUS1_1());

            particle.rotation      = num3;
            particle.deltaRotation = (num4 - num3) / particle.timeToLive;
            if (this.m_ePositionType == eParticlePositionType.kCCPositionTypeFree)
            {
                CCPoint v = base.convertToWorldSpace(new CCPoint(0f, 0f));
                particle.startPos = CCPointExtension.ccpMult(v, CCDirector.sharedDirector().ContentScaleFactor);
            }
            else if (this.m_ePositionType == eParticlePositionType.kCCPositionTypeRelative)
            {
                particle.startPos = CCPointExtension.ccpMult(base.m_tPosition, CCDirector.sharedDirector().ContentScaleFactor);
            }
            float num5 = ccMacros.CC_DEGREES_TO_RADIANS(this.m_fAngle + (this.m_fAngleVar * ccMacros.CCRANDOM_MINUS1_1()));

            if (this.m_nEmitterMode == 0)
            {
                CCPoint point2 = new CCPoint((float)Math.Cos((double)num5), (float)Math.Sin((double)num5));
                float   s      = this.modeA.speed + (this.modeA.speedVar * ccMacros.CCRANDOM_MINUS1_1());
                s *= CCDirector.sharedDirector().ContentScaleFactor;
                particle.modeA.dir              = CCPointExtension.ccpMult(point2, s);
                particle.modeA.radialAccel      = this.modeA.radialAccel + (this.modeA.radialAccelVar * ccMacros.CCRANDOM_MINUS1_1());
                particle.modeA.radialAccel     *= CCDirector.sharedDirector().ContentScaleFactor;
                particle.modeA.tangentialAccel  = this.modeA.tangentialAccel + (this.modeA.tangentialAccelVar * ccMacros.CCRANDOM_MINUS1_1());
                particle.modeA.tangentialAccel *= CCDirector.sharedDirector().ContentScaleFactor;
            }
            else
            {
                float num7 = this.modeB.startRadius + (this.modeB.startRadiusVar * ccMacros.CCRANDOM_MINUS1_1());
                float num8 = this.modeB.endRadius + (this.modeB.endRadiusVar * ccMacros.CCRANDOM_MINUS1_1());
                num7 *= CCDirector.sharedDirector().ContentScaleFactor;
                num8 *= CCDirector.sharedDirector().ContentScaleFactor;
                particle.modeB.radius = num7;
                if (this.modeB.endRadius == -1f)
                {
                    particle.modeB.deltaRadius = 0f;
                }
                else
                {
                    particle.modeB.deltaRadius = (num8 - num7) / particle.timeToLive;
                }
                particle.modeB.angle            = num5;
                particle.modeB.degreesPerSecond = ccMacros.CC_DEGREES_TO_RADIANS(this.modeB.rotatePerSecond + (this.modeB.rotatePerSecondVar * ccMacros.CCRANDOM_MINUS1_1()));
            }
        }
 /// <summary>
 /// draws a polygon given a pointer to CCPoint coordiantes and the number of vertices measured in points.
 /// The polygon can be closed or open
 /// </summary>
 public static void ccDrawPoly(CCPoint[] vertices, int numOfVertices, bool closePolygon, ccColor4F color)
 {
     ccDrawPoly(vertices, numOfVertices, closePolygon, false, color);
 }
 /// <summary>
 /// draws a polygon given a pointer to CCPoint coordiantes and the number of vertices measured in points.
 /// The polygon can be closed or open
 /// </summary>
 public static void ccDrawPoly(CCPoint[] vertices, int numOfVertices, bool closePolygon, ccColor4F color)
 {
     ccDrawPoly(vertices, numOfVertices, closePolygon, false, color);
 }
        /// <summary>
        /// draws a quad bezier path
        /// @since v0.8
        /// </summary>
        public static void ccDrawQuadBezier(CCPoint origin, CCPoint control, CCPoint destination, int segments, ccColor4F color)
        {
            VertexPositionColor[] vertices = new VertexPositionColor[segments + 1];
            float factor = CCDirector.sharedDirector().ContentScaleFactor;
            CCApplication app = CCApplication.sharedApplication();

            float t = 0.0f;
            for (int i = 0; i < segments; i++)
            {
                float x = (float)Math.Pow(1 - t, 2) * origin.x + 2.0f * (1 - t) * t * control.x + t * t * destination.x;
                float y = (float)Math.Pow(1 - t, 2) * origin.y + 2.0f * (1 - t) * t * control.y + t * t * destination.y;
                vertices[i] = new VertexPositionColor();
                vertices[i].Position = new Vector3(x * factor, y * factor, 0);
                vertices[i].Color = new Color(color.r, color.g, color.b, color.a);
                t += 1.0f / segments;
            }
            vertices[segments] = new VertexPositionColor()
            {
                Position = new Vector3(destination.x * factor, destination.y * factor, 0),
                Color = new Color(color.r, color.g, color.b, color.a),
            };

            app.basicEffect.TextureEnabled = false;
            app.basicEffect.VertexColorEnabled = true;
            foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();
                app.GraphicsDevice.DrawUserPrimitives<VertexPositionColor>(PrimitiveType.LineStrip, vertices, 0, segments);
            }
        }
        /// <summary>
        /// draws a polygon given a pointer to CCPoint coordiantes and the number of vertices measured in points.
        /// The polygon can be closed or open and optionally filled with current GL color
        /// </summary>
        public static void ccDrawPoly(CCPoint[] vertices, int numOfVertices, bool closePolygon, bool fill, ccColor4F color)
        {
            VertexPositionColor[] newPoint = new VertexPositionColor[numOfVertices + 1];
            for (int i = 0; i < numOfVertices; i++)
            {
                newPoint[i]          = new VertexPositionColor();
                newPoint[i].Position = new Vector3(vertices[i].x, vertices[i].y, 0);
                newPoint[i].Color    = new Color(color.r, color.g, color.b, color.a);
            }

            CCApplication app = CCApplication.sharedApplication();

            app.GraphicsDevice.RasterizerState = new RasterizerState()
            {
                CullMode = CullMode.None
            };
            app.basicEffect.TextureEnabled     = false;
            app.basicEffect.VertexColorEnabled = true;

            short[] indexes = new short[(numOfVertices - 2) * 3];
            if (fill)
            {
                for (int i = 0; i < numOfVertices - 2; i++)
                {
                    indexes[i * 3 + 0] = 0;
                    indexes[i * 3 + 1] = (short)(i + 2);
                    indexes[i * 3 + 2] = (short)(i + 1);
                }

                foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
                {
                    pass.Apply();

                    app.GraphicsDevice.DrawUserIndexedPrimitives <VertexPositionColor>(PrimitiveType.TriangleStrip,
                                                                                       newPoint, 0, numOfVertices,
                                                                                       indexes, 0, numOfVertices - 2);
                }
            }
            else
            {
                if (closePolygon)
                {
                    newPoint[numOfVertices] = newPoint[0];
                    numOfVertices          += 1;
                }

                foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
                {
                    pass.Apply();

                    app.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineStrip,
                                                                                newPoint, 0, numOfVertices - 1);
                }
            }



            //if (closePolygon)
            //{
            //    glDrawArrays(fill ? GL_TRIANGLE_FAN : GL_LINE_LOOP, 0, numberOfPoints);
            //}
            //else
            //{
            //    glDrawArrays(fill ? GL_TRIANGLE_FAN : GL_LINE_STRIP, 0, numberOfPoints);
            //}
        }
示例#23
0
        public override void onEnter()
        {
            base.onEnter();

            m_emitter = new CCParticleSystemQuad();
            m_emitter.initWithTotalParticles(300);
            //m_emitter.autorelease();

            m_background.addChild(m_emitter, 10);
            ////m_emitter.release();	// win32 : Remove this line
            m_emitter.Texture = CCTextureCache.sharedTextureCache().addImage(TestResource.s_stars2);

            // duration
            m_emitter.Duration = -1;

            // gravity
            m_emitter.setGravity( new CCPoint(0,0));

            // angle
            m_emitter.Angle = 90;
            m_emitter.AngleVar = 360;

            // speed of particles
            m_emitter.setSpeed(160);
            m_emitter.setSpeedVar(20);

            // radial
            m_emitter.setRadialAccel(-120);
            m_emitter.setRadialAccelVar(0);

            // tagential
            m_emitter.setTangentialAccel(30);
            m_emitter.setTangentialAccelVar(0);

            // emitter position
            m_emitter.position =  new CCPoint(160,240);
            m_emitter.PosVar = new CCPoint(0,0);

            // life of particles
            m_emitter.Life = 3;
            m_emitter.LifeVar = 1;

            // spin of particles
            m_emitter.StartSpin = 0;
            m_emitter.StartSpinVar = 0;
            m_emitter.EndSpin = 0;
            m_emitter.EndSpinVar = 2000;

            // color of particles
            ccColor4F startColor = new ccColor4F(0.5f, 0.5f, 0.5f, 1.0f);
            m_emitter.StartColor = startColor;

            ccColor4F startColorVar = new ccColor4F(0.5f, 0.5f, 0.5f, 1.0f);
            m_emitter.StartColorVar = startColorVar;

            ccColor4F endColor = new ccColor4F(0.1f, 0.1f, 0.1f, 0.2f);
            m_emitter.EndColor = endColor;

            ccColor4F endColorVar = new ccColor4F(0.1f, 0.1f, 0.1f, 0.2f);
            m_emitter.EndColorVar = endColorVar;

            // size, in pixels
            m_emitter.StartSize = 30.0f;
            m_emitter.StartSizeVar = 00.0f;
            m_emitter.EndSize = (float)eParticleShowingProperty.kParticleStartSizeEqualToEndSize;

            // emits per second
            m_emitter.EmissionRate = m_emitter.TotalParticles/m_emitter.Life;

            // additive
            m_emitter.IsBlendAdditive = false;

            setEmitterPosition();
        }
        /// <summary>
        /// draws a quad bezier path
        /// @since v0.8
        /// </summary>
        public static void ccDrawQuadBezier(CCPoint origin, CCPoint control, CCPoint destination, int segments, ccColor4F color)
        {
            VertexPositionColor[] vertices = new VertexPositionColor[segments + 1];
            float         factor           = CCDirector.sharedDirector().ContentScaleFactor;
            CCApplication app = CCApplication.sharedApplication();

            float t = 0.0f;

            for (int i = 0; i < segments; i++)
            {
                float x = (float)Math.Pow(1 - t, 2) * origin.x + 2.0f * (1 - t) * t * control.x + t * t * destination.x;
                float y = (float)Math.Pow(1 - t, 2) * origin.y + 2.0f * (1 - t) * t * control.y + t * t * destination.y;
                vertices[i]          = new VertexPositionColor();
                vertices[i].Position = new Vector3(x * factor, y * factor, 0);
                vertices[i].Color    = new Color(color.r, color.g, color.b, color.a);
                t += 1.0f / segments;
            }
            vertices[segments] = new VertexPositionColor()
            {
                Position = new Vector3(destination.x * factor, destination.y * factor, 0),
                Color    = new Color(color.r, color.g, color.b, color.a),
            };

            app.basicEffect.TextureEnabled     = false;
            app.basicEffect.VertexColorEnabled = true;
            foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();
                app.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineStrip, vertices, 0, segments);
            }
        }
示例#25
0
 /** returns YES if both ccColor4F are equal. Otherwise it returns NO.
  @since v0.99.1
  */
 public static bool ccc4FEqual(ccColor4F a, ccColor4F b)
 {
     return a.r == b.r && a.g == b.g && a.b == b.b && a.a == b.a;
 }
        /// <summary>
        /// draws a cubic bezier path
        /// @since v0.8
        /// </summary>
        public static void ccDrawCubicBezier(CCPoint origin, CCPoint control1, CCPoint control2, CCPoint destination, int segments, ccColor4F color)
        {
            VertexPositionColor[] vertices = new VertexPositionColor[segments + 1];
            float         factor           = CCDirector.sharedDirector().ContentScaleFactor;
            CCApplication app = CCApplication.sharedApplication();

            float t = 0;

            for (int i = 0; i < segments; ++i)
            {
                float x = (float)Math.Pow(1 - t, 3) * origin.x + 3.0f * (float)Math.Pow(1 - t, 2) * t * control1.x + 3.0f * (1 - t) * t * t * control2.x + t * t * t * destination.x;
                float y = (float)Math.Pow(1 - t, 3) * origin.y + 3.0f * (float)Math.Pow(1 - t, 2) * t * control1.y + 3.0f * (1 - t) * t * t * control2.y + t * t * t * destination.y;
                vertices[i]          = new VertexPositionColor();
                vertices[i].Position = new Vector3(x * factor, y * factor, 0);
                vertices[i].Color    = new Color(color.r, color.g, color.b, color.a);
                t += 1.0f / segments;
            }
            vertices[segments] = new VertexPositionColor()
            {
                Color    = new Color(color.r, color.g, color.b, color.a),
                Position = new Vector3(destination.x * factor, destination.y * factor, 0)
            };

            app.basicEffect.TextureEnabled     = false;
            app.basicEffect.VertexColorEnabled = true;
            foreach (var pass in app.basicEffect.CurrentTechnique.Passes)
            {
                pass.Apply();

                app.GraphicsDevice.DrawUserPrimitives <VertexPositionColor>(PrimitiveType.LineStrip, vertices, 0, segments);
            }

            // Default GL states: GL_TEXTURE_2D, GL_VERTEX_ARRAY, GL_COLOR_ARRAY, GL_TEXTURE_COORD_ARRAY
            // Needed states: GL_VERTEX_ARRAY,
            // Unneeded states: GL_TEXTURE_2D, GL_TEXTURE_COORD_ARRAY, GL_COLOR_ARRAY
            //glDisable(GL_TEXTURE_2D);
            //glDisableClientState(GL_TEXTURE_COORD_ARRAY);
            //glDisableClientState(GL_COLOR_ARRAY);

            //glVertexPointer(2, GL_FLOAT, 0, vertices);
            //glDrawArrays(GL_LINE_STRIP, 0, (GLsizei)segments + 1);
            //delete[] vertices;

            //// restore default state
            //glEnableClientState(GL_COLOR_ARRAY);
            //glEnableClientState(GL_TEXTURE_COORD_ARRAY);
            //glEnable(GL_TEXTURE_2D);
        }
示例#27
0
 public ccV2F_C4F_T2F()
 {
     vertices = new ccVertex2F();
     colors = new ccColor4F();
     texCoords = new ccTex2F();
 }
示例#28
0
 public ccV2F_C4F_T2F()
 {
     vertices  = new ccVertex2F();
     colors    = new ccColor4F();
     texCoords = new ccTex2F();
 }
示例#29
0
        //! Initializes a particle
        public void initParticle(CCParticle particle)
        {
            Debug.Assert(null != particle, "particle shouldn't be null.");

            // timeToLive
            // no negative life. prevent division by 0
            particle.timeToLive = m_fLife + m_fLifeVar * ccMacros.CCRANDOM_MINUS1_1();
            particle.timeToLive = (((0) > (particle.timeToLive)) ? (0) : (particle.timeToLive));

            // position
            particle.pos.x = m_tSourcePosition.x + m_tPosVar.x * ccMacros.CCRANDOM_MINUS1_1();
            particle.pos.x *= CCDirector.sharedDirector().ContentScaleFactor;
            particle.pos.y = m_tSourcePosition.y + m_tPosVar.y * ccMacros.CCRANDOM_MINUS1_1();
            particle.pos.y *= CCDirector.sharedDirector().ContentScaleFactor;

            // Color
            ccColor4F start = new ccColor4F();
            start.r = CCPointExtension.clampf(m_tStartColor.r + m_tStartColorVar.r * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);
            start.g = CCPointExtension.clampf(m_tStartColor.g + m_tStartColorVar.g * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);
            start.b = CCPointExtension.clampf(m_tStartColor.b + m_tStartColorVar.b * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);
            start.a = CCPointExtension.clampf(m_tStartColor.a + m_tStartColorVar.a * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);

            ccColor4F end = new ccColor4F();
            end.r = CCPointExtension.clampf(m_tEndColor.r + m_tEndColorVar.r * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);
            end.g = CCPointExtension.clampf(m_tEndColor.g + m_tEndColorVar.g * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);
            end.b = CCPointExtension.clampf(m_tEndColor.b + m_tEndColorVar.b * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);
            end.a = CCPointExtension.clampf(m_tEndColor.a + m_tEndColorVar.a * ccMacros.CCRANDOM_MINUS1_1(), 0, 1);

            particle.color = start;
            particle.deltaColor.r = (end.r - start.r) / particle.timeToLive;
            particle.deltaColor.g = (end.g - start.g) / particle.timeToLive;
            particle.deltaColor.b = (end.b - start.b) / particle.timeToLive;
            particle.deltaColor.a = (end.a - start.a) / particle.timeToLive;

            // size
            float startS = m_fStartSize + m_fStartSizeVar * ccMacros.CCRANDOM_MINUS1_1();
            startS = (((0) > (startS)) ? (0) : (startS)); // No negative value
            startS *= CCDirector.sharedDirector().ContentScaleFactor;

            particle.size = startS;

            if( m_fEndSize == (float)eParticleShowingProperty.kCCParticleStartSizeEqualToEndSize )
            {
                particle.deltaSize = 0;
            }
            else
            {
                float endS = m_fEndSize + m_fEndSizeVar * ccMacros.CCRANDOM_MINUS1_1();
                endS = (((0) > (endS)) ? (0) : (endS)); // No negative values
                endS *= CCDirector.sharedDirector().ContentScaleFactor;
                particle.deltaSize = (endS - startS) / particle.timeToLive;
            }

            // rotation
            float startA = m_fStartSpin + m_fStartSpinVar * ccMacros.CCRANDOM_MINUS1_1();
            float endA = m_fEndSpin + m_fEndSpinVar * ccMacros.CCRANDOM_MINUS1_1();
            particle.rotation = startA;
            particle.deltaRotation = (endA - startA) / particle.timeToLive;

            // position
            if( m_ePositionType == eParticlePositionType.kCCPositionTypeFree )
            {
                CCPoint p = this.convertToWorldSpace(new CCPoint(0,0));
                particle.startPos = CCPointExtension.ccpMult( p, CCDirector.sharedDirector().ContentScaleFactor );
            }
            else if ( m_ePositionType == eParticlePositionType.kCCPositionTypeRelative )
            {
                particle.startPos = CCPointExtension.ccpMult( m_tPosition, CCDirector.sharedDirector().ContentScaleFactor );
            }

            // direction
            float a = ccMacros.CC_DEGREES_TO_RADIANS(m_fAngle + m_fAngleVar * ccMacros.CCRANDOM_MINUS1_1());

            // Mode Gravity: A
            if( m_nEmitterMode == (int)eParticleMode.kCCParticleModeGravity )
            {
                CCPoint v = new CCPoint( (float)System.Math.Cos( a ), (float)System.Math.Sin( a ));
                float s = modeA.speed + modeA.speedVar * ccMacros.CCRANDOM_MINUS1_1();
                s *= CCDirector.sharedDirector().ContentScaleFactor;

                // direction
                particle.modeA.dir = CCPointExtension.ccpMult( v, s );

                // radial accel
                particle.modeA.radialAccel = modeA.radialAccel + modeA.radialAccelVar * ccMacros.CCRANDOM_MINUS1_1();
                particle.modeA.radialAccel *= CCDirector.sharedDirector().ContentScaleFactor;

                // tangential accel
                particle.modeA.tangentialAccel = modeA.tangentialAccel + modeA.tangentialAccelVar * ccMacros.CCRANDOM_MINUS1_1();
                particle.modeA.tangentialAccel *= CCDirector.sharedDirector().ContentScaleFactor;
            }

            // Mode Radius: B
            else {
                // Set the default diameter of the particle from the source position
                float startRadius = modeB.startRadius + modeB.startRadiusVar * ccMacros.CCRANDOM_MINUS1_1();
                float endRadius = modeB.endRadius + modeB.endRadiusVar * ccMacros.CCRANDOM_MINUS1_1();
                startRadius *= CCDirector.sharedDirector().ContentScaleFactor;
                endRadius *= CCDirector.sharedDirector().ContentScaleFactor;

                particle.modeB.radius = startRadius;

                if( modeB.endRadius == (float)eParticleShowingProperty.kCCParticleStartRadiusEqualToEndRadius )
                    particle.modeB.deltaRadius = 0;
                else
                    particle.modeB.deltaRadius = (endRadius - startRadius) / particle.timeToLive;

                particle.modeB.angle = a;
                particle.modeB.degreesPerSecond = ccMacros.CC_DEGREES_TO_RADIANS(modeB.rotatePerSecond + modeB.rotatePerSecondVar * ccMacros.CCRANDOM_MINUS1_1());
            }
        }
示例#30
0
 public ccV2F_C4F_T2F()
 {
     this.vertices  = new ccVertex2F();
     this.colors    = new ccColor4F();
     this.texCoords = new ccTex2F();
 }