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Found via: `rg --multiline "=\n\t*\{\n"`
729 lines
21 KiB
C++
729 lines
21 KiB
C++
// Copyright (C) 2002-2012 Nikolaus Gebhardt
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// This file is part of the "Irrlicht Engine".
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// For conditions of distribution and use, see copyright notice in irrlicht.h
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#pragma once
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#include "irrTypes.h"
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#include "irrMath.h"
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namespace irr
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{
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namespace video
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{
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//! An enum for the color format of textures used by the Irrlicht Engine.
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/** A color format specifies how color information is stored.
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NOTE: Byte order in memory is usually flipped (it's probably correct in bitmap files, but flipped on reading).
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So for example ECF_A8R8G8B8 is BGRA in memory same as in DX9's D3DFMT_A8R8G8B8 format.
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*/
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enum ECOLOR_FORMAT
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{
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//! 16 bit color format used by the software driver.
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/** It is thus preferred by all other irrlicht engine video drivers.
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There are 5 bits for every color component, and a single bit is left
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for alpha information. */
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ECF_A1R5G5B5 = 0,
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//! Standard 16 bit color format.
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ECF_R5G6B5,
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//! 24 bit color, no alpha channel, but 8 bit for red, green and blue.
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//! Warning: 24 bit formats tend to be badly supported. Depending on driver it's usually converted to another
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// format or even not working at all. It's mostly better to use 16-bit or 32-bit formats.
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ECF_R8G8B8,
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//! Default 32 bit color format. 8 bits are used for every component: red, green, blue and alpha.
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//! Warning: This tends to be BGRA in memory (it's ARGB on file, but with usual big-endian memory it's flipped)
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ECF_A8R8G8B8,
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/** The following formats may only be used for render target textures. */
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/** Floating point formats. */
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//! 16 bit format using 16 bits for the red channel.
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ECF_R16F,
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//! 32 bit format using 16 bits for the red and green channels.
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ECF_G16R16F,
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//! 64 bit format using 16 bits for the red, green, blue and alpha channels.
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ECF_A16B16G16R16F,
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//! 32 bit format using 32 bits for the red channel.
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ECF_R32F,
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//! 64 bit format using 32 bits for the red and green channels.
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ECF_G32R32F,
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//! 128 bit format using 32 bits for the red, green, blue and alpha channels.
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ECF_A32B32G32R32F,
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/** Unsigned normalized integer formats. */
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//! 8 bit format using 8 bits for the red channel.
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ECF_R8,
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//! 16 bit format using 8 bits for the red and green channels.
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ECF_R8G8,
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//! 16 bit format using 16 bits for the red channel.
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ECF_R16,
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//! 32 bit format using 16 bits for the red and green channels.
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ECF_R16G16,
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/** Depth and stencil formats. */
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//! 16 bit format using 16 bits for depth.
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ECF_D16,
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//! 32 bit format using 32 bits for depth.
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ECF_D32,
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//! 32 bit format using 24 bits for depth and 8 bits for stencil.
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ECF_D24S8,
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//! Unknown color format:
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ECF_UNKNOWN
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};
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//! Names for ECOLOR_FORMAT types
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const c8 *const ColorFormatNames[ECF_UNKNOWN + 2] = {
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"A1R5G5B5",
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"R5G6B5",
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"R8G8B8",
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"A8R8G8B8",
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"R16F",
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"G16R16F",
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"A16B16G16R16F",
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"R32F",
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"G32R32F",
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"A32B32G32R32F",
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"R8",
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"R8G8",
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"R16",
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"R16G16",
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"D16",
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"D32",
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"D24S8",
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"UNKNOWN",
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0,
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};
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//! Creates a 16 bit A1R5G5B5 color
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inline u16 RGBA16(u32 r, u32 g, u32 b, u32 a = 0xFF)
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{
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return (u16)((a & 0x80) << 8 |
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(r & 0xF8) << 7 |
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(g & 0xF8) << 2 |
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(b & 0xF8) >> 3);
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}
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//! Creates a 16 bit A1R5G5B5 color
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inline u16 RGB16(u32 r, u32 g, u32 b)
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{
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return RGBA16(r, g, b);
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}
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//! Creates a 16bit A1R5G5B5 color, based on 16bit input values
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inline u16 RGB16from16(u16 r, u16 g, u16 b)
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{
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return (0x8000 |
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(r & 0x1F) << 10 |
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(g & 0x1F) << 5 |
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(b & 0x1F));
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}
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//! Converts a 32bit (X8R8G8B8) color to a 16bit A1R5G5B5 color
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inline u16 X8R8G8B8toA1R5G5B5(u32 color)
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{
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return (u16)(0x8000 |
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(color & 0x00F80000) >> 9 |
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(color & 0x0000F800) >> 6 |
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(color & 0x000000F8) >> 3);
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}
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//! Converts a 32bit (A8R8G8B8) color to a 16bit A1R5G5B5 color
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inline u16 A8R8G8B8toA1R5G5B5(u32 color)
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{
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return (u16)((color & 0x80000000) >> 16 |
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(color & 0x00F80000) >> 9 |
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(color & 0x0000F800) >> 6 |
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(color & 0x000000F8) >> 3);
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}
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//! Converts a 32bit (A8R8G8B8) color to a 16bit R5G6B5 color
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inline u16 A8R8G8B8toR5G6B5(u32 color)
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{
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return (u16)((color & 0x00F80000) >> 8 |
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(color & 0x0000FC00) >> 5 |
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(color & 0x000000F8) >> 3);
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}
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//! Convert A8R8G8B8 Color from A1R5G5B5 color
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/** build a nicer 32bit Color by extending dest lower bits with source high bits. */
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inline u32 A1R5G5B5toA8R8G8B8(u16 color)
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{
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return (((-((s32)color & 0x00008000) >> (s32)31) & 0xFF000000) |
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((color & 0x00007C00) << 9) | ((color & 0x00007000) << 4) |
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((color & 0x000003E0) << 6) | ((color & 0x00000380) << 1) |
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((color & 0x0000001F) << 3) | ((color & 0x0000001C) >> 2));
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}
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//! Returns A8R8G8B8 Color from R5G6B5 color
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inline u32 R5G6B5toA8R8G8B8(u16 color)
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{
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return 0xFF000000 |
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((color & 0xF800) << 8) |
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((color & 0x07E0) << 5) |
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((color & 0x001F) << 3);
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}
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//! Returns A1R5G5B5 Color from R5G6B5 color
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inline u16 R5G6B5toA1R5G5B5(u16 color)
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{
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return 0x8000 | (((color & 0xFFC0) >> 1) | (color & 0x1F));
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}
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//! Returns R5G6B5 Color from A1R5G5B5 color
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inline u16 A1R5G5B5toR5G6B5(u16 color)
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{
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return (((color & 0x7FE0) << 1) | (color & 0x1F));
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}
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//! Returns the alpha component from A1R5G5B5 color
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/** In Irrlicht, alpha refers to opacity.
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\return The alpha value of the color. 0 is transparent, 1 is opaque. */
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inline u32 getAlpha(u16 color)
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{
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return ((color >> 15) & 0x1);
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}
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//! Returns the red component from A1R5G5B5 color.
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/** Shift left by 3 to get 8 bit value. */
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inline u32 getRed(u16 color)
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{
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return ((color >> 10) & 0x1F);
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}
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//! Returns the green component from A1R5G5B5 color
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/** Shift left by 3 to get 8 bit value. */
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inline u32 getGreen(u16 color)
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{
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return ((color >> 5) & 0x1F);
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}
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//! Returns the blue component from A1R5G5B5 color
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/** Shift left by 3 to get 8 bit value. */
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inline u32 getBlue(u16 color)
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{
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return (color & 0x1F);
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}
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//! Returns the average from a 16 bit A1R5G5B5 color
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inline s32 getAverage(s16 color)
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{
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return ((getRed(color) << 3) + (getGreen(color) << 3) + (getBlue(color) << 3)) / 3;
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}
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//! Class representing a 32 bit ARGB color.
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/** The color values for alpha, red, green, and blue are
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stored in a single u32. So all four values may be between 0 and 255.
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Alpha in Irrlicht is opacity, so 0 is fully transparent, 255 is fully opaque (solid).
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This class is used by most parts of the Irrlicht Engine
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to specify a color. Another way is using the class SColorf, which
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stores the color values in 4 floats.
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This class must consist of only one u32 and must not use virtual functions.
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*/
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class SColor
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{
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public:
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//! Constructor of the Color. Does nothing.
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/** The color value is not initialized to save time. */
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SColor() {}
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//! Constructs the color from 4 values representing the alpha, red, green and blue component.
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/** Must be values between 0 and 255. */
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constexpr SColor(u32 a, u32 r, u32 g, u32 b) :
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color(((a & 0xff) << 24) | ((r & 0xff) << 16) | ((g & 0xff) << 8) | (b & 0xff)) {}
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//! Constructs the color from a 32 bit value. Could be another color.
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constexpr SColor(u32 clr) :
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color(clr) {}
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//! Returns the alpha component of the color.
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/** The alpha component defines how opaque a color is.
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\return The alpha value of the color. 0 is fully transparent, 255 is fully opaque. */
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u32 getAlpha() const { return color >> 24; }
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//! Returns the red component of the color.
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/** \return Value between 0 and 255, specifying how red the color is.
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0 means no red, 255 means full red. */
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u32 getRed() const { return (color >> 16) & 0xff; }
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//! Returns the green component of the color.
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/** \return Value between 0 and 255, specifying how green the color is.
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0 means no green, 255 means full green. */
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u32 getGreen() const { return (color >> 8) & 0xff; }
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//! Returns the blue component of the color.
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/** \return Value between 0 and 255, specifying how blue the color is.
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0 means no blue, 255 means full blue. */
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u32 getBlue() const { return color & 0xff; }
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//! Get lightness of the color in the range [0,255]
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f32 getLightness() const
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{
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return 0.5f * (core::max_(core::max_(getRed(), getGreen()), getBlue()) + core::min_(core::min_(getRed(), getGreen()), getBlue()));
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}
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//! Get luminance of the color in the range [0,255].
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f32 getLuminance() const
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{
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return 0.3f * getRed() + 0.59f * getGreen() + 0.11f * getBlue();
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}
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//! Get average intensity of the color in the range [0,255].
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u32 getAverage() const
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{
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return (getRed() + getGreen() + getBlue()) / 3;
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}
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//! Sets the alpha component of the Color.
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/** The alpha component defines how transparent a color should be.
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\param a The alpha value of the color. 0 is fully transparent, 255 is fully opaque. */
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void setAlpha(u32 a) { color = ((a & 0xff) << 24) | (color & 0x00ffffff); }
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//! Sets the red component of the Color.
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/** \param r: Has to be a value between 0 and 255.
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0 means no red, 255 means full red. */
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void setRed(u32 r) { color = ((r & 0xff) << 16) | (color & 0xff00ffff); }
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//! Sets the green component of the Color.
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/** \param g: Has to be a value between 0 and 255.
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0 means no green, 255 means full green. */
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void setGreen(u32 g) { color = ((g & 0xff) << 8) | (color & 0xffff00ff); }
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//! Sets the blue component of the Color.
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/** \param b: Has to be a value between 0 and 255.
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0 means no blue, 255 means full blue. */
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void setBlue(u32 b) { color = (b & 0xff) | (color & 0xffffff00); }
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//! Calculates a 16 bit A1R5G5B5 value of this color.
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/** \return 16 bit A1R5G5B5 value of this color. */
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u16 toA1R5G5B5() const { return A8R8G8B8toA1R5G5B5(color); }
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//! Converts color to OpenGL color format
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/** From ARGB to RGBA in 4 byte components for endian aware
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passing to OpenGL
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\param dest: address where the 4x8 bit OpenGL color is stored. */
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void toOpenGLColor(u8 *dest) const
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{
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*dest = (u8)getRed();
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*++dest = (u8)getGreen();
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*++dest = (u8)getBlue();
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*++dest = (u8)getAlpha();
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}
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//! Sets all four components of the color at once.
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/** Constructs the color from 4 values representing the alpha,
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red, green and blue components of the color. Must be values
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between 0 and 255.
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\param a: Alpha component of the color. The alpha component
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defines how transparent a color should be. Has to be a value
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between 0 and 255. 255 means not transparent (opaque), 0 means
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fully transparent.
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\param r: Sets the red component of the Color. Has to be a
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value between 0 and 255. 0 means no red, 255 means full red.
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\param g: Sets the green component of the Color. Has to be a
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value between 0 and 255. 0 means no green, 255 means full
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green.
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\param b: Sets the blue component of the Color. Has to be a
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value between 0 and 255. 0 means no blue, 255 means full blue. */
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void set(u32 a, u32 r, u32 g, u32 b)
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{
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color = (((a & 0xff) << 24) | ((r & 0xff) << 16) | ((g & 0xff) << 8) | (b & 0xff));
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}
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void set(u32 col) { color = col; }
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//! Compares the color to another color.
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/** \return True if the colors are the same, and false if not. */
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bool operator==(const SColor &other) const { return other.color == color; }
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//! Compares the color to another color.
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/** \return True if the colors are different, and false if they are the same. */
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bool operator!=(const SColor &other) const { return other.color != color; }
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//! comparison operator
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/** \return True if this color is smaller than the other one */
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bool operator<(const SColor &other) const { return (color < other.color); }
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//! Adds two colors, result is clamped to 0..255 values
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/** \param other Color to add to this color
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\return Addition of the two colors, clamped to 0..255 values */
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SColor operator+(const SColor &other) const
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{
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return SColor(core::min_(getAlpha() + other.getAlpha(), 255u),
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core::min_(getRed() + other.getRed(), 255u),
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core::min_(getGreen() + other.getGreen(), 255u),
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core::min_(getBlue() + other.getBlue(), 255u));
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}
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//! Interpolates the color with a f32 value to another color
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/** \param other: Other color
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\param d: value between 0.0f and 1.0f. d=0 returns other, d=1 returns this, values between interpolate.
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\return Interpolated color. */
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SColor getInterpolated(const SColor &other, f32 d) const
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{
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d = core::clamp(d, 0.f, 1.f);
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const f32 inv = 1.0f - d;
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return SColor((u32)core::round32(other.getAlpha() * inv + getAlpha() * d),
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(u32)core::round32(other.getRed() * inv + getRed() * d),
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(u32)core::round32(other.getGreen() * inv + getGreen() * d),
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(u32)core::round32(other.getBlue() * inv + getBlue() * d));
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}
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//! Returns interpolated color. ( quadratic )
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/** \param c1: first color to interpolate with
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\param c2: second color to interpolate with
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\param d: value between 0.0f and 1.0f. */
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SColor getInterpolated_quadratic(const SColor &c1, const SColor &c2, f32 d) const
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{
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// this*(1-d)*(1-d) + 2 * c1 * (1-d) + c2 * d * d;
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d = core::clamp(d, 0.f, 1.f);
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const f32 inv = 1.f - d;
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const f32 mul0 = inv * inv;
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const f32 mul1 = 2.f * d * inv;
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const f32 mul2 = d * d;
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return SColor(
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core::clamp(core::floor32(
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getAlpha() * mul0 + c1.getAlpha() * mul1 + c2.getAlpha() * mul2),
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0, 255),
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core::clamp(core::floor32(
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getRed() * mul0 + c1.getRed() * mul1 + c2.getRed() * mul2),
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0, 255),
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core::clamp(core::floor32(
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getGreen() * mul0 + c1.getGreen() * mul1 + c2.getGreen() * mul2),
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0, 255),
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core::clamp(core::floor32(
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getBlue() * mul0 + c1.getBlue() * mul1 + c2.getBlue() * mul2),
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0, 255));
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}
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//! set the color by expecting data in the given format
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/** \param data: must point to valid memory containing color information in the given format
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\param format: tells the format in which data is available
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*/
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void setData(const void *data, ECOLOR_FORMAT format)
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{
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switch (format) {
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case ECF_A1R5G5B5:
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color = A1R5G5B5toA8R8G8B8(*(u16 *)data);
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break;
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case ECF_R5G6B5:
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color = R5G6B5toA8R8G8B8(*(u16 *)data);
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break;
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case ECF_A8R8G8B8:
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color = *(u32 *)data;
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break;
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case ECF_R8G8B8: {
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const u8 *p = (u8 *)data;
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set(255, p[0], p[1], p[2]);
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} break;
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default:
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color = 0xffffffff;
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break;
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}
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}
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//! Write the color to data in the defined format
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/** \param data: target to write the color. Must contain sufficiently large memory to receive the number of bytes neede for format
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\param format: tells the format used to write the color into data
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*/
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void getData(void *data, ECOLOR_FORMAT format) const
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{
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switch (format) {
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case ECF_A1R5G5B5: {
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u16 *dest = (u16 *)data;
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*dest = video::A8R8G8B8toA1R5G5B5(color);
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} break;
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case ECF_R5G6B5: {
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u16 *dest = (u16 *)data;
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*dest = video::A8R8G8B8toR5G6B5(color);
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} break;
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|
|
|
case ECF_R8G8B8: {
|
|
u8 *dest = (u8 *)data;
|
|
dest[0] = (u8)getRed();
|
|
dest[1] = (u8)getGreen();
|
|
dest[2] = (u8)getBlue();
|
|
} break;
|
|
|
|
case ECF_A8R8G8B8: {
|
|
u32 *dest = (u32 *)data;
|
|
*dest = color;
|
|
} break;
|
|
|
|
default:
|
|
break;
|
|
}
|
|
}
|
|
|
|
//! color in A8R8G8B8 Format
|
|
u32 color;
|
|
};
|
|
|
|
//! Class representing a color with four floats.
|
|
/** The color values for red, green, blue
|
|
and alpha are each stored in a 32 bit floating point variable.
|
|
So all four values may be between 0.0f and 1.0f.
|
|
Another, faster way to define colors is using the class SColor, which
|
|
stores the color values in a single 32 bit integer.
|
|
*/
|
|
class SColorf
|
|
{
|
|
public:
|
|
//! Default constructor for SColorf.
|
|
/** Sets red, green and blue to 0.0f and alpha to 1.0f. */
|
|
SColorf() :
|
|
r(0.0f), g(0.0f), b(0.0f), a(1.0f) {}
|
|
|
|
//! Constructs a color from up to four color values: red, green, blue, and alpha.
|
|
/** \param r: Red color component. Should be a value between
|
|
0.0f meaning no red and 1.0f, meaning full red.
|
|
\param g: Green color component. Should be a value between 0.0f
|
|
meaning no green and 1.0f, meaning full green.
|
|
\param b: Blue color component. Should be a value between 0.0f
|
|
meaning no blue and 1.0f, meaning full blue.
|
|
\param a: Alpha color component of the color. The alpha
|
|
component defines how transparent a color should be. Has to be
|
|
a value between 0.0f and 1.0f, 1.0f means not transparent
|
|
(opaque), 0.0f means fully transparent. */
|
|
SColorf(f32 r, f32 g, f32 b, f32 a = 1.0f) :
|
|
r(r), g(g), b(b), a(a) {}
|
|
|
|
//! Constructs a color from 32 bit Color.
|
|
/** \param c: 32 bit color from which this SColorf class is
|
|
constructed from. */
|
|
SColorf(SColor c)
|
|
{
|
|
const f32 inv = 1.0f / 255.0f;
|
|
r = c.getRed() * inv;
|
|
g = c.getGreen() * inv;
|
|
b = c.getBlue() * inv;
|
|
a = c.getAlpha() * inv;
|
|
}
|
|
|
|
//! Converts this color to a SColor without floats.
|
|
SColor toSColor() const
|
|
{
|
|
return SColor((u32)core::round32(a * 255.0f), (u32)core::round32(r * 255.0f), (u32)core::round32(g * 255.0f), (u32)core::round32(b * 255.0f));
|
|
}
|
|
|
|
//! Sets three color components to new values at once.
|
|
/** \param rr: Red color component. Should be a value between 0.0f meaning
|
|
no red (=black) and 1.0f, meaning full red.
|
|
\param gg: Green color component. Should be a value between 0.0f meaning
|
|
no green (=black) and 1.0f, meaning full green.
|
|
\param bb: Blue color component. Should be a value between 0.0f meaning
|
|
no blue (=black) and 1.0f, meaning full blue. */
|
|
void set(f32 rr, f32 gg, f32 bb)
|
|
{
|
|
r = rr;
|
|
g = gg;
|
|
b = bb;
|
|
}
|
|
|
|
//! Sets all four color components to new values at once.
|
|
/** \param aa: Alpha component. Should be a value between 0.0f meaning
|
|
fully transparent and 1.0f, meaning opaque.
|
|
\param rr: Red color component. Should be a value between 0.0f meaning
|
|
no red and 1.0f, meaning full red.
|
|
\param gg: Green color component. Should be a value between 0.0f meaning
|
|
no green and 1.0f, meaning full green.
|
|
\param bb: Blue color component. Should be a value between 0.0f meaning
|
|
no blue and 1.0f, meaning full blue. */
|
|
void set(f32 aa, f32 rr, f32 gg, f32 bb)
|
|
{
|
|
a = aa;
|
|
r = rr;
|
|
g = gg;
|
|
b = bb;
|
|
}
|
|
|
|
//! Interpolates the color with a f32 value to another color
|
|
/** \param other: Other color
|
|
\param d: value between 0.0f and 1.0f
|
|
\return Interpolated color. */
|
|
SColorf getInterpolated(const SColorf &other, f32 d) const
|
|
{
|
|
d = core::clamp(d, 0.f, 1.f);
|
|
const f32 inv = 1.0f - d;
|
|
return SColorf(other.r * inv + r * d,
|
|
other.g * inv + g * d, other.b * inv + b * d, other.a * inv + a * d);
|
|
}
|
|
|
|
//! Returns interpolated color. ( quadratic )
|
|
/** \param c1: first color to interpolate with
|
|
\param c2: second color to interpolate with
|
|
\param d: value between 0.0f and 1.0f. */
|
|
inline SColorf getInterpolated_quadratic(const SColorf &c1, const SColorf &c2,
|
|
f32 d) const
|
|
{
|
|
d = core::clamp(d, 0.f, 1.f);
|
|
// this*(1-d)*(1-d) + 2 * c1 * (1-d) + c2 * d * d;
|
|
const f32 inv = 1.f - d;
|
|
const f32 mul0 = inv * inv;
|
|
const f32 mul1 = 2.f * d * inv;
|
|
const f32 mul2 = d * d;
|
|
|
|
return SColorf(r * mul0 + c1.r * mul1 + c2.r * mul2,
|
|
g * mul0 + c1.g * mul1 + c2.g * mul2,
|
|
b * mul0 + c1.b * mul1 + c2.b * mul2,
|
|
a * mul0 + c1.a * mul1 + c2.a * mul2);
|
|
}
|
|
|
|
//! Sets a color component by index. R=0, G=1, B=2, A=3
|
|
void setColorComponentValue(s32 index, f32 value)
|
|
{
|
|
switch (index) {
|
|
case 0:
|
|
r = value;
|
|
break;
|
|
case 1:
|
|
g = value;
|
|
break;
|
|
case 2:
|
|
b = value;
|
|
break;
|
|
case 3:
|
|
a = value;
|
|
break;
|
|
}
|
|
}
|
|
|
|
//! Returns the alpha component of the color in the range 0.0 (transparent) to 1.0 (opaque)
|
|
f32 getAlpha() const { return a; }
|
|
|
|
//! Returns the red component of the color in the range 0.0 to 1.0
|
|
f32 getRed() const { return r; }
|
|
|
|
//! Returns the green component of the color in the range 0.0 to 1.0
|
|
f32 getGreen() const { return g; }
|
|
|
|
//! Returns the blue component of the color in the range 0.0 to 1.0
|
|
f32 getBlue() const { return b; }
|
|
|
|
//! red color component
|
|
f32 r;
|
|
|
|
//! green color component
|
|
f32 g;
|
|
|
|
//! blue component
|
|
f32 b;
|
|
|
|
//! alpha color component
|
|
f32 a;
|
|
};
|
|
|
|
//! Class representing a color in HSL format
|
|
/** The color values for hue, saturation, luminance
|
|
are stored in 32bit floating point variables. Hue is in range [0,360],
|
|
Luminance and Saturation are in percent [0,100]
|
|
*/
|
|
class SColorHSL
|
|
{
|
|
public:
|
|
constexpr SColorHSL(f32 h = 0.f, f32 s = 0.f, f32 l = 0.f) :
|
|
Hue(h), Saturation(s), Luminance(l) {}
|
|
|
|
void fromRGB(const SColorf &color);
|
|
void toRGB(SColorf &color) const;
|
|
|
|
f32 Hue;
|
|
f32 Saturation;
|
|
f32 Luminance;
|
|
|
|
private:
|
|
inline f32 toRGB1(f32 rm1, f32 rm2, f32 rh) const;
|
|
};
|
|
|
|
inline void SColorHSL::fromRGB(const SColorf &color)
|
|
{
|
|
const f32 maxVal = core::max_(color.getRed(), color.getGreen(), color.getBlue());
|
|
const f32 minVal = (f32)core::min_(color.getRed(), color.getGreen(), color.getBlue());
|
|
Luminance = (maxVal + minVal) * 50;
|
|
if (core::equals(maxVal, minVal)) {
|
|
Hue = 0.f;
|
|
Saturation = 0.f;
|
|
return;
|
|
}
|
|
|
|
const f32 delta = maxVal - minVal;
|
|
if (Luminance <= 50) {
|
|
Saturation = (delta) / (maxVal + minVal);
|
|
} else {
|
|
Saturation = (delta) / (2 - maxVal - minVal);
|
|
}
|
|
Saturation *= 100;
|
|
|
|
if (core::equals(maxVal, color.getRed()))
|
|
Hue = (color.getGreen() - color.getBlue()) / delta;
|
|
else if (core::equals(maxVal, color.getGreen()))
|
|
Hue = 2 + ((color.getBlue() - color.getRed()) / delta);
|
|
else // blue is max
|
|
Hue = 4 + ((color.getRed() - color.getGreen()) / delta);
|
|
|
|
Hue *= 60.0f;
|
|
while (Hue < 0.f)
|
|
Hue += 360;
|
|
}
|
|
|
|
inline void SColorHSL::toRGB(SColorf &color) const
|
|
{
|
|
const f32 l = Luminance / 100;
|
|
if (core::iszero(Saturation)) { // grey
|
|
color.set(l, l, l);
|
|
return;
|
|
}
|
|
|
|
f32 rm2;
|
|
|
|
if (Luminance <= 50) {
|
|
rm2 = l + l * (Saturation / 100);
|
|
} else {
|
|
rm2 = l + (1 - l) * (Saturation / 100);
|
|
}
|
|
|
|
const f32 rm1 = 2.0f * l - rm2;
|
|
|
|
const f32 h = Hue / 360.0f;
|
|
color.set(toRGB1(rm1, rm2, h + 1.f / 3.f),
|
|
toRGB1(rm1, rm2, h),
|
|
toRGB1(rm1, rm2, h - 1.f / 3.f));
|
|
}
|
|
|
|
// algorithm from Foley/Van-Dam
|
|
inline f32 SColorHSL::toRGB1(f32 rm1, f32 rm2, f32 rh) const
|
|
{
|
|
if (rh < 0)
|
|
rh += 1;
|
|
if (rh > 1)
|
|
rh -= 1;
|
|
|
|
if (rh < 1.f / 6.f)
|
|
rm1 = rm1 + (rm2 - rm1) * rh * 6.f;
|
|
else if (rh < 0.5f)
|
|
rm1 = rm2;
|
|
else if (rh < 2.f / 3.f)
|
|
rm1 = rm1 + (rm2 - rm1) * ((2.f / 3.f) - rh) * 6.f;
|
|
|
|
return rm1;
|
|
}
|
|
|
|
} // end namespace video
|
|
} // end namespace irr
|