C# (CSharp) Duality MathF.Cos Exemples

Langage de programmation: C# (CSharp)

Espace de nommage/Pack: Duality

Class/Type: MathF

Méthode/Fonction: Cos

Exemples au hotexamples.com: 1

C# (CSharp) Duality MathF.Cos - 1 exemples trouvés. Ce sont les exemples réels les mieux notés de Duality.MathF.Cos extraits de projets open source. Vous pouvez noter les exemples pour nous aider à en améliorer la qualité.

Méthodes fréquemment utilisées

Afficher Cacher

RoundToInt(6)

Min(6)

Round(5)

Clamp(4)

Abs(3)

Pow(3)

Max(2)

Sin(2)

Atan2(1)

Cos(1)

GetTransformDotVec(1)

NormalizeVar(1)

Méthodes fréquemment utilisées

RoundToInt (6)

Min (6)

Round (5)

Clamp (4)

Abs (3)

Pow (3)

Max (2)

Sin (2)

Atan2 (1)

Cos (1)

Méthodes fréquemment utilisées

GetTransformDotVec (1)

NormalizeVar (1)

Exemple #1

0

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public unsafe void DrawString(ref int charOffset, string text, float x, float y, Alignment alignment, ColorRgba? color = null, float scale = 1f, float angleOffset = 0f, float varianceX = 4f, float varianceY = 4f, float speed = 4f, float charSpacing = 1f, float lineSpacing = 1f) { const int MaxColorizeIndex = 7; if (string.IsNullOrEmpty(text)) { return; } float phase = (float)Time.GameTimer.TotalSeconds * speed; bool hasColor = false; // Pre-compute text size //int lines = 1; float totalWidth = 0f, lastWidth = 0f, totalHeight = 0f; float charSpacingPre = charSpacing; float scalePre = scale; for (int i = 0; i < text.Length; i++) { if (text[i] == '\n') { if (lastWidth < totalWidth) { lastWidth = totalWidth; } totalWidth = 0f; totalHeight += (charHeight * scale * lineSpacing); //lines++; continue; } else if (text[i] == '\f' && text[i + 1] == '[') { i += 2; int formatIndex = i; while (text[i] != ']') { i++; } if (text[formatIndex + 1] == ':') { int paramInt; switch (text[formatIndex]) { case 'c': // Color hasColor = true; break; case 's': // Scale if (int.TryParse(text.Substring(formatIndex + 2, i - (formatIndex + 2)), out paramInt)) { scalePre = paramInt * 0.01f; } break; case 'w': // Char spacing if (int.TryParse(text.Substring(formatIndex + 2, i - (formatIndex + 2)), out paramInt)) { charSpacingPre = paramInt * 0.01f; } break; } } continue; } Rect uvRect; if (!unicodeChars.TryGetValue(text[i], out uvRect)) { byte ascii = (byte)text[i]; if (ascii < 128) { uvRect = asciiChars[ascii]; } else { uvRect = new Rect(); } } if (uvRect.W > 0 && uvRect.H > 0) { totalWidth += (uvRect.W + baseSpacing) * charSpacingPre * scalePre; } } if (lastWidth < totalWidth) { lastWidth = totalWidth; } totalHeight += (charHeight * scale * lineSpacing); VertexC1P3T2[] vertexData = canvas.RentVertices(text.Length * 4); // Set default material bool colorize, allowColorChange; ContentRef<Material> material; ColorRgba mainColor; if (color.HasValue) { mainColor = color.Value; if (mainColor == ColorRgba.TransparentBlack) { if (hasColor) { material = materialColor; mainColor = new ColorRgba(0.46f, 0.46f, 0.4f, 0.5f); } else { material = materialPlain; mainColor = ColorRgba.White; } } else { material = materialColor; } colorize = false; if (mainColor.R == 0 && mainColor.G == 0 && mainColor.B == 0) { allowColorChange = false; } else { allowColorChange = true; } } else { material = materialColor; mainColor = ColorRgba.White; colorize = true; allowColorChange = false; } Vector2 uvRatio = new Vector2( 1f / materialPlain.Res.MainTexture.Res.ContentWidth, 1f / materialPlain.Res.MainTexture.Res.ContentHeight ); int vertexIndex = 0; Vector2 originPos = new Vector2(x, y); alignment.ApplyTo(ref originPos, new Vector2(lastWidth, totalHeight)); float lineStart = originPos.X; for (int i = 0; i < text.Length; i++) { if (text[i] == '\n') { // New line originPos.X = lineStart; originPos.Y += (charHeight * scale * lineSpacing); continue; } else if (text[i] == '\f' && text[i + 1] == '[') { // Format i += 2; int formatIndex = i; while (text[i] != ']') { i++; } if (text[formatIndex + 1] == ':') { int paramInt; switch (text[formatIndex]) { case 'c': // Color if (allowColorChange && int.TryParse(text.Substring(formatIndex + 2, i - (formatIndex + 2)), out paramInt)) { if (paramInt == -1) { colorize = true; } else { colorize = false; mainColor = colors[paramInt % colors.Length]; } } break; case 's': // Scale if (int.TryParse(text.Substring(formatIndex + 2, i - (formatIndex + 2)), out paramInt)) { scale = paramInt * 0.01f; } break; case 'w': // Char spacing if (int.TryParse(text.Substring(formatIndex + 2, i - (formatIndex + 2)), out paramInt)) { charSpacing = paramInt * 0.01f; } break; default: // Unknown formatting break; } } continue; } Rect uvRect; if (!unicodeChars.TryGetValue(text[i], out uvRect)) { byte ascii = (byte)text[i]; if (ascii < 128) { uvRect = asciiChars[ascii]; } else { uvRect = new Rect(); } } if (uvRect.W > 0 && uvRect.H > 0) { if (colorize) { mainColor = colors[charOffset % MaxColorizeIndex]; } Vector3 pos = new Vector3(originPos); if (angleOffset > 0f) { float currentPhase = (phase + charOffset) * angleOffset * MathF.Pi; if (speed > 0f && charOffset % 2 == 1) { currentPhase = -currentPhase; } pos.X += MathF.Cos(currentPhase) * varianceX * scale; pos.Y += MathF.Sin(currentPhase) * varianceY * scale; } pos.X = MathF.Round(pos.X); pos.Y = MathF.Round(pos.Y); float x2 = MathF.Round(pos.X + uvRect.W * scale); float y2 = MathF.Round(pos.Y + uvRect.H * scale); vertexData[vertexIndex + 0].Pos = pos; vertexData[vertexIndex + 0].TexCoord.X = uvRect.X; vertexData[vertexIndex + 0].TexCoord.Y = uvRect.Y; vertexData[vertexIndex + 0].Color = mainColor; vertexData[vertexIndex + 1].Pos.X = pos.X; vertexData[vertexIndex + 1].Pos.Y = y2; vertexData[vertexIndex + 1].Pos.Z = pos.Z; vertexData[vertexIndex + 1].TexCoord.X = uvRect.X; vertexData[vertexIndex + 1].TexCoord.Y = uvRect.Y + uvRect.H * uvRatio.Y; vertexData[vertexIndex + 1].Color = mainColor; vertexData[vertexIndex + 2].Pos.X = x2; vertexData[vertexIndex + 2].Pos.Y = y2; vertexData[vertexIndex + 2].Pos.Z = pos.Z; vertexData[vertexIndex + 2].TexCoord.X = uvRect.X + uvRect.W * uvRatio.X; vertexData[vertexIndex + 2].TexCoord.Y = uvRect.Y + uvRect.H * uvRatio.Y; vertexData[vertexIndex + 2].Color = mainColor; vertexData[vertexIndex + 3].Pos.X = x2; vertexData[vertexIndex + 3].Pos.Y = pos.Y; vertexData[vertexIndex + 3].Pos.Z = pos.Z; vertexData[vertexIndex + 3].TexCoord.X = uvRect.X + uvRect.W * uvRatio.X; vertexData[vertexIndex + 3].TexCoord.Y = uvRect.Y; vertexData[vertexIndex + 3].Color = mainColor; if (MathF.RoundToInt(canvas.DrawDevice.TargetSize.X) != (MathF.RoundToInt(canvas.DrawDevice.TargetSize.X) / 2) * 2) { float align = 0.5f / canvas.DrawDevice.TargetSize.X; vertexData[vertexIndex + 0].Pos.X += align; vertexData[vertexIndex + 1].Pos.X += align; vertexData[vertexIndex + 2].Pos.X += align; vertexData[vertexIndex + 3].Pos.X += align; } if (MathF.RoundToInt(canvas.DrawDevice.TargetSize.Y) != (MathF.RoundToInt(canvas.DrawDevice.TargetSize.Y) / 2) * 2) { float align = 0.5f * scale / canvas.DrawDevice.TargetSize.Y; vertexData[vertexIndex + 0].Pos.Y += align; vertexData[vertexIndex + 1].Pos.Y += align; vertexData[vertexIndex + 2].Pos.Y += align; vertexData[vertexIndex + 3].Pos.Y += align; } vertexIndex += 4; originPos.X += ((uvRect.W + baseSpacing) * scale * charSpacing); } charOffset++; } charOffset++; // Submit all the vertices as one draw batch canvas.DrawDevice.AddVertices( material, VertexMode.Quads, vertexData, 0, vertexIndex); }