irrlicht/source/Irrlicht/CTRTextureFlatWire.cpp

// Copyright (C) 2002-2012 Nikolaus Gebhardt
// This file is part of the "Irrlicht Engine".
// For conditions of distribution and use, see copyright notice in irrlicht.h

#include "IrrCompileConfig.h"
#include "CTRTextureGouraud.h"

#ifdef _IRR_COMPILE_WITH_SOFTWARE_

namespace irr
{
namespace video
{

class CTRTextureFlatWire : public CTRTextureGouraud
{
public:

	CTRTextureFlatWire(IZBuffer* zbuffer)
		: CTRTextureGouraud(zbuffer)
	{
		#ifdef _DEBUG
		setDebugName("CTRTextureFlatWire");
		#endif
	}

	//! draws an indexed triangle list
	virtual void drawIndexedTriangleList(S2DVertex* vertices, s32 vertexCount, const u16* indexList, s32 triangleCount) IRR_OVERRIDE
	{
		const S2DVertex *v1, *v2, *v3;

		f32 tmpDiv; // temporary division factor
		f32 longest; // saves the longest span
		s32 height; // saves height of triangle
		u16* targetSurface; // target pointer where to plot pixels
		s32 spanEnd; // saves end of spans
		f32 leftdeltaxf; // amount of pixels to increase on left side of triangle
		f32 rightdeltaxf; // amount of pixels to increase on right side of triangle
		s32 leftx, rightx; // position where we are
		f32 leftxf, rightxf; // same as above, but as f32 values
		s32 span; // current span
		s32 leftTx, rightTx, leftTy, rightTy; // texture interpolating values
		s32 leftTxStep, rightTxStep, leftTyStep, rightTyStep; // texture interpolating values
		core::rect<s32> TriangleRect;

		s32 leftZValue, rightZValue;
		s32 leftZStep, rightZStep;
		TZBufferType* zTarget; // target of ZBuffer;

		lockedSurface = (u16*)RenderTarget->getData();
		lockedZBuffer = ZBuffer->lock();
		lockedTexture = (u16*)Texture->getData();

		for (s32 i=0; i<triangleCount; ++i)
		{
			v1 = &vertices[*indexList];
			++indexList;
			v2 = &vertices[*indexList];
			++indexList;
			v3 = &vertices[*indexList];
			++indexList;

			// back face culling

			if (BackFaceCullingEnabled)
			{
				s32 z = ((v3->Pos.X - v1->Pos.X) * (v3->Pos.Y - v2->Pos.Y)) -
					((v3->Pos.Y - v1->Pos.Y) * (v3->Pos.X - v2->Pos.X));

				if (z < 0)
					continue;
			}

			//near plane clipping

			if (v1->ZValue<0 && v2->ZValue<0 && v3->ZValue<0)
				continue;

			// sort for width for inscreen clipping

			if (v1->Pos.X > v2->Pos.X)	swapVertices(&v1, &v2);
			if (v1->Pos.X > v3->Pos.X)	swapVertices(&v1, &v3);
			if (v2->Pos.X > v3->Pos.X)	swapVertices(&v2, &v3);

			if ((v1->Pos.X - v3->Pos.X) == 0)
				continue;

			TriangleRect.UpperLeftCorner.X = v1->Pos.X;
			TriangleRect.LowerRightCorner.X = v3->Pos.X;

			// sort for height for faster drawing.

			if (v1->Pos.Y > v2->Pos.Y)	swapVertices(&v1, &v2);
			if (v1->Pos.Y > v3->Pos.Y)	swapVertices(&v1, &v3);
			if (v2->Pos.Y > v3->Pos.Y)	swapVertices(&v2, &v3);

			TriangleRect.UpperLeftCorner.Y = v1->Pos.Y;
			TriangleRect.LowerRightCorner.Y = v3->Pos.Y;

			if (!TriangleRect.isRectCollided(ViewPortRect))
				continue;

			// calculate height of triangle
			height = v3->Pos.Y - v1->Pos.Y;
			if (!height)
				continue;

			// calculate longest span

			longest = (v2->Pos.Y - v1->Pos.Y) / (f32)height * (v3->Pos.X - v1->Pos.X) + (v1->Pos.X - v2->Pos.X);

			spanEnd = v2->Pos.Y;
			span = v1->Pos.Y;
			leftxf = (f32)v1->Pos.X;
			rightxf = (f32)v1->Pos.X;

			leftZValue = v1->ZValue;
			rightZValue = v1->ZValue;

			leftTx = rightTx = v1->TCoords.X;
			leftTy = rightTy = v1->TCoords.Y;

			targetSurface = lockedSurface + span * SurfaceWidth;
			zTarget = lockedZBuffer + span * SurfaceWidth;

			if (longest < 0.0f)
			{
				tmpDiv = 1.0f / (f32)(v2->Pos.Y - v1->Pos.Y);
				rightdeltaxf = (v2->Pos.X - v1->Pos.X) * tmpDiv;
				rightZStep = (s32)((v2->ZValue - v1->ZValue) * tmpDiv);
				rightTxStep = (s32)((v2->TCoords.X - rightTx) * tmpDiv);
				rightTyStep = (s32)((v2->TCoords.Y - rightTy) * tmpDiv);

				tmpDiv = 1.0f / (f32)height;
				leftdeltaxf = (v3->Pos.X - v1->Pos.X) * tmpDiv;
				leftZStep = (s32)((v3->ZValue - v1->ZValue) * tmpDiv);
				leftTxStep = (s32)((v3->TCoords.X - leftTx) * tmpDiv);
				leftTyStep = (s32)((v3->TCoords.Y - leftTy) * tmpDiv);
			}
			else
			{
				tmpDiv = 1.0f / (f32)height;
				rightdeltaxf = (v3->Pos.X - v1->Pos.X) * tmpDiv;
				rightZStep = (s32)((v3->ZValue - v1->ZValue) * tmpDiv);
				rightTxStep = (s32)((v3->TCoords.X - rightTx) * tmpDiv);
				rightTyStep = (s32)((v3->TCoords.Y - rightTy) * tmpDiv);

				tmpDiv = 1.0f / (f32)(v2->Pos.Y - v1->Pos.Y);
				leftdeltaxf = (v2->Pos.X - v1->Pos.X) * tmpDiv;
				leftZStep = (s32)((v2->ZValue - v1->ZValue) * tmpDiv);
				leftTxStep = (s32)((v2->TCoords.X - leftTx) * tmpDiv);
				leftTyStep = (s32)((v2->TCoords.Y - leftTy) * tmpDiv);
			}


			// do it twice, once for the first half of the triangle,
			// end then for the second half.

			for (s32 triangleHalf=0; triangleHalf<2; ++triangleHalf)
			{
				if (spanEnd > ViewPortRect.LowerRightCorner.Y)
					spanEnd = ViewPortRect.LowerRightCorner.Y;

				// if the span <0, than we can skip these spans,
				// and proceed to the next spans which are really on the screen.
				if (span < ViewPortRect.UpperLeftCorner.Y)
				{
					// we'll use leftx as temp variable
					if (spanEnd < ViewPortRect.UpperLeftCorner.Y)
					{
						leftx = spanEnd - span;
						span = spanEnd;
					}
					else
					{
						leftx = ViewPortRect.UpperLeftCorner.Y - span;
						span = ViewPortRect.UpperLeftCorner.Y;
					}

					leftxf += leftdeltaxf*leftx;
					rightxf += rightdeltaxf*leftx;
					targetSurface += SurfaceWidth*leftx;
					zTarget += SurfaceWidth*leftx;
					leftZValue += leftZStep*leftx;
					rightZValue += rightZStep*leftx;

					leftTx += leftTxStep*leftx;
					leftTy += leftTyStep*leftx;
					rightTx += rightTxStep*leftx;
					rightTy += rightTyStep*leftx;
				}


				// the main loop. Go through every span and draw it.

				while (span < spanEnd)
				{
					leftx = (s32)(leftxf);
					rightx = (s32)(rightxf + 0.5f);

					// perform some clipping

					if (leftx>=ViewPortRect.UpperLeftCorner.X &&
						leftx<=ViewPortRect.LowerRightCorner.X)
					{
						if (leftZValue > *(zTarget + leftx))
						{
							*(zTarget + leftx) = leftZValue;
							*(targetSurface + leftx) = lockedTexture[((leftTy>>8)&textureYMask) * lockedTextureWidth + ((rightTx>>8)&textureXMask)];
						}
					}


					if (rightx>=ViewPortRect.UpperLeftCorner.X &&
						rightx<=ViewPortRect.LowerRightCorner.X)
					{
						if (rightZValue > *(zTarget + rightx))
						{
							*(zTarget + rightx) = rightZValue;
							*(targetSurface + rightx) = lockedTexture[((rightTy>>8)&textureYMask) * lockedTextureWidth + ((rightTx>>8)&textureXMask)];
						}

					}


					leftxf += leftdeltaxf;
					rightxf += rightdeltaxf;
					++span;
					targetSurface += SurfaceWidth;
					zTarget += SurfaceWidth;
					leftZValue += leftZStep;
					rightZValue += rightZStep;

					leftTx += leftTxStep;
					leftTy += leftTyStep;
					rightTx += rightTxStep;
					rightTy += rightTyStep;
				}

				if (triangleHalf>0) // break, we've gout only two halves
					break;


				// setup variables for second half of the triangle.

				if (longest < 0.0f)
				{
					tmpDiv = 1.0f / (v3->Pos.Y - v2->Pos.Y);

					rightdeltaxf = (v3->Pos.X - v2->Pos.X) * tmpDiv;
					rightxf = (f32)v2->Pos.X;

					rightZValue = v2->ZValue;
					rightZStep = (s32)((v3->ZValue - v2->ZValue) * tmpDiv);

					rightTx = v2->TCoords.X;
					rightTy = v2->TCoords.Y;
					rightTxStep = (s32)((v3->TCoords.X - rightTx) * tmpDiv);
					rightTyStep = (s32)((v3->TCoords.Y - rightTy) * tmpDiv);
				}
				else
				{
					tmpDiv = 1.0f / (v3->Pos.Y - v2->Pos.Y);

					leftdeltaxf = (v3->Pos.X - v2->Pos.X) * tmpDiv;
					leftxf = (f32)v2->Pos.X;

					leftZValue = v2->ZValue;
					leftZStep = (s32)((v3->ZValue - v2->ZValue) * tmpDiv);

					leftTx = v2->TCoords.X;
					leftTy = v2->TCoords.Y;
					leftTxStep = (s32)((v3->TCoords.X - leftTx) * tmpDiv);
					leftTyStep = (s32)((v3->TCoords.Y - leftTy) * tmpDiv);
				}


				spanEnd = v3->Pos.Y;
			}

		}

		ZBuffer->unlock();
	}
};

} // end namespace video
} // end namespace irr

#endif // _IRR_COMPILE_WITH_SOFTWARE_

namespace irr
{
namespace video
{

//! creates a flat triangle renderer
ITriangleRenderer* createTriangleRendererTextureFlatWire(IZBuffer* zbuffer)
{
	#ifdef _IRR_COMPILE_WITH_SOFTWARE_
	return new CTRTextureFlatWire(zbuffer);
	#else
	return 0;
	#endif // _IRR_COMPILE_WITH_SOFTWARE_
}

} // end namespace video
} // end namespace irr
Avoid warning and make local variable lower-case. git-svn-id: svn://svn.code.sf.net/p/irrlicht/code/trunk@6000 dfc29bdd-3216-0410-991c-e03cc46cb475 2019-12-12 17:32:41 +01:00			`// Copyright (C) 2002-2012 Nikolaus Gebhardt`
			`// This file is part of the "Irrlicht Engine".`
			`// For conditions of distribution and use, see copyright notice in irrlicht.h`

			`#include "IrrCompileConfig.h"`
			`#include "CTRTextureGouraud.h"`

			`#ifdef _IRR_COMPILE_WITH_SOFTWARE_`

			`namespace irr`
			`{`
			`namespace video`
			`{`

			`class CTRTextureFlatWire : public CTRTextureGouraud`
			`{`
			`public:`

			`CTRTextureFlatWire(IZBuffer* zbuffer)`
			`: CTRTextureGouraud(zbuffer)`
			`{`
			`#ifdef _DEBUG`
			`setDebugName("CTRTextureFlatWire");`
			`#endif`
			`}`

			`//! draws an indexed triangle list`
API BREAKER: Replacing defines in irrTypes.h which are conflicting with c++ reserved identifier rules. C++ has undefined behavior for identifiers starting with __ or with _ followed by an uppercase letter. We still have many more (in IrrCompileConfig.h and in all header-guards), will likely replace those later as well. As a workaround for users which might use irrlicht defines in their code, I've added the header irrLegacyDefines.h Including that allows to continue using old defines for a while - or make it easier to have code which compiles with old and new Irrlicht library versions. git-svn-id: svn://svn.code.sf.net/p/irrlicht/code/trunk@6251 dfc29bdd-3216-0410-991c-e03cc46cb475 2021-08-27 14:55:10 +02:00			`virtual void drawIndexedTriangleList(S2DVertex* vertices, s32 vertexCount, const u16* indexList, s32 triangleCount) IRR_OVERRIDE`
Avoid warning and make local variable lower-case. git-svn-id: svn://svn.code.sf.net/p/irrlicht/code/trunk@6000 dfc29bdd-3216-0410-991c-e03cc46cb475 2019-12-12 17:32:41 +01:00			`{`
			`const S2DVertex v1, v2, *v3;`

			`f32 tmpDiv; // temporary division factor`
			`f32 longest; // saves the longest span`
			`s32 height; // saves height of triangle`
			`u16* targetSurface; // target pointer where to plot pixels`
			`s32 spanEnd; // saves end of spans`
			`f32 leftdeltaxf; // amount of pixels to increase on left side of triangle`
			`f32 rightdeltaxf; // amount of pixels to increase on right side of triangle`
			`s32 leftx, rightx; // position where we are`
			`f32 leftxf, rightxf; // same as above, but as f32 values`
			`s32 span; // current span`
			`s32 leftTx, rightTx, leftTy, rightTy; // texture interpolating values`
			`s32 leftTxStep, rightTxStep, leftTyStep, rightTyStep; // texture interpolating values`
			`core::rect<s32> TriangleRect;`

			`s32 leftZValue, rightZValue;`
			`s32 leftZStep, rightZStep;`
			`TZBufferType* zTarget; // target of ZBuffer;`

			`lockedSurface = (u16*)RenderTarget->getData();`
			`lockedZBuffer = ZBuffer->lock();`
			`lockedTexture = (u16*)Texture->getData();`

			`for (s32 i=0; i<triangleCount; ++i)`
			`{`
			`v1 = &vertices[*indexList];`
			`++indexList;`
			`v2 = &vertices[*indexList];`
			`++indexList;`
			`v3 = &vertices[*indexList];`
			`++indexList;`

			`// back face culling`

			`if (BackFaceCullingEnabled)`
			`{`
			`s32 z = ((v3->Pos.X - v1->Pos.X) * (v3->Pos.Y - v2->Pos.Y)) -`
			`((v3->Pos.Y - v1->Pos.Y) * (v3->Pos.X - v2->Pos.X));`

			`if (z < 0)`
			`continue;`
			`}`

			`//near plane clipping`

			`if (v1->ZValue<0 && v2->ZValue<0 && v3->ZValue<0)`
			`continue;`

			`// sort for width for inscreen clipping`

			`if (v1->Pos.X > v2->Pos.X) swapVertices(&v1, &v2);`
			`if (v1->Pos.X > v3->Pos.X) swapVertices(&v1, &v3);`
			`if (v2->Pos.X > v3->Pos.X) swapVertices(&v2, &v3);`

			`if ((v1->Pos.X - v3->Pos.X) == 0)`
			`continue;`

			`TriangleRect.UpperLeftCorner.X = v1->Pos.X;`
			`TriangleRect.LowerRightCorner.X = v3->Pos.X;`

			`// sort for height for faster drawing.`

			`if (v1->Pos.Y > v2->Pos.Y) swapVertices(&v1, &v2);`
			`if (v1->Pos.Y > v3->Pos.Y) swapVertices(&v1, &v3);`
			`if (v2->Pos.Y > v3->Pos.Y) swapVertices(&v2, &v3);`

			`TriangleRect.UpperLeftCorner.Y = v1->Pos.Y;`
			`TriangleRect.LowerRightCorner.Y = v3->Pos.Y;`

			`if (!TriangleRect.isRectCollided(ViewPortRect))`
			`continue;`

			`// calculate height of triangle`
			`height = v3->Pos.Y - v1->Pos.Y;`
			`if (!height)`
			`continue;`

			`// calculate longest span`

			`longest = (v2->Pos.Y - v1->Pos.Y) / (f32)height * (v3->Pos.X - v1->Pos.X) + (v1->Pos.X - v2->Pos.X);`

			`spanEnd = v2->Pos.Y;`
			`span = v1->Pos.Y;`
			`leftxf = (f32)v1->Pos.X;`
			`rightxf = (f32)v1->Pos.X;`

			`leftZValue = v1->ZValue;`
			`rightZValue = v1->ZValue;`

			`leftTx = rightTx = v1->TCoords.X;`
			`leftTy = rightTy = v1->TCoords.Y;`

			`targetSurface = lockedSurface + span * SurfaceWidth;`
			`zTarget = lockedZBuffer + span * SurfaceWidth;`

			`if (longest < 0.0f)`
			`{`
			`tmpDiv = 1.0f / (f32)(v2->Pos.Y - v1->Pos.Y);`
			`rightdeltaxf = (v2->Pos.X - v1->Pos.X) * tmpDiv;`
			`rightZStep = (s32)((v2->ZValue - v1->ZValue) * tmpDiv);`
			`rightTxStep = (s32)((v2->TCoords.X - rightTx) * tmpDiv);`
			`rightTyStep = (s32)((v2->TCoords.Y - rightTy) * tmpDiv);`

			`tmpDiv = 1.0f / (f32)height;`
			`leftdeltaxf = (v3->Pos.X - v1->Pos.X) * tmpDiv;`
			`leftZStep = (s32)((v3->ZValue - v1->ZValue) * tmpDiv);`
			`leftTxStep = (s32)((v3->TCoords.X - leftTx) * tmpDiv);`
			`leftTyStep = (s32)((v3->TCoords.Y - leftTy) * tmpDiv);`
			`}`
			`else`
			`{`
			`tmpDiv = 1.0f / (f32)height;`
			`rightdeltaxf = (v3->Pos.X - v1->Pos.X) * tmpDiv;`
			`rightZStep = (s32)((v3->ZValue - v1->ZValue) * tmpDiv);`
			`rightTxStep = (s32)((v3->TCoords.X - rightTx) * tmpDiv);`
			`rightTyStep = (s32)((v3->TCoords.Y - rightTy) * tmpDiv);`

			`tmpDiv = 1.0f / (f32)(v2->Pos.Y - v1->Pos.Y);`
			`leftdeltaxf = (v2->Pos.X - v1->Pos.X) * tmpDiv;`
			`leftZStep = (s32)((v2->ZValue - v1->ZValue) * tmpDiv);`
			`leftTxStep = (s32)((v2->TCoords.X - leftTx) * tmpDiv);`
			`leftTyStep = (s32)((v2->TCoords.Y - leftTy) * tmpDiv);`
			`}`


			`// do it twice, once for the first half of the triangle,`
			`// end then for the second half.`

			`for (s32 triangleHalf=0; triangleHalf<2; ++triangleHalf)`
			`{`
			`if (spanEnd > ViewPortRect.LowerRightCorner.Y)`
			`spanEnd = ViewPortRect.LowerRightCorner.Y;`

			`// if the span <0, than we can skip these spans,`
			`// and proceed to the next spans which are really on the screen.`
			`if (span < ViewPortRect.UpperLeftCorner.Y)`
			`{`
			`// we'll use leftx as temp variable`
			`if (spanEnd < ViewPortRect.UpperLeftCorner.Y)`
			`{`
			`leftx = spanEnd - span;`
			`span = spanEnd;`
			`}`
			`else`
			`{`
			`leftx = ViewPortRect.UpperLeftCorner.Y - span;`
			`span = ViewPortRect.UpperLeftCorner.Y;`
			`}`

			`leftxf += leftdeltaxf*leftx;`
			`rightxf += rightdeltaxf*leftx;`
			`targetSurface += SurfaceWidth*leftx;`
			`zTarget += SurfaceWidth*leftx;`
			`leftZValue += leftZStep*leftx;`
			`rightZValue += rightZStep*leftx;`

			`leftTx += leftTxStep*leftx;`
			`leftTy += leftTyStep*leftx;`
			`rightTx += rightTxStep*leftx;`
			`rightTy += rightTyStep*leftx;`
			`}`


			`// the main loop. Go through every span and draw it.`

			`while (span < spanEnd)`
			`{`
			`leftx = (s32)(leftxf);`
			`rightx = (s32)(rightxf + 0.5f);`

			`// perform some clipping`

			`if (leftx>=ViewPortRect.UpperLeftCorner.X &&`
			`leftx<=ViewPortRect.LowerRightCorner.X)`
			`{`
			`if (leftZValue > *(zTarget + leftx))`
			`{`
			`*(zTarget + leftx) = leftZValue;`
			`(targetSurface + leftx) = lockedTexture[((leftTy>>8)&textureYMask) lockedTextureWidth + ((rightTx>>8)&textureXMask)];`
			`}`
			`}`


			`if (rightx>=ViewPortRect.UpperLeftCorner.X &&`
			`rightx<=ViewPortRect.LowerRightCorner.X)`
			`{`
			`if (rightZValue > *(zTarget + rightx))`
			`{`
			`*(zTarget + rightx) = rightZValue;`
			`(targetSurface + rightx) = lockedTexture[((rightTy>>8)&textureYMask) lockedTextureWidth + ((rightTx>>8)&textureXMask)];`
			`}`

			`}`


			`leftxf += leftdeltaxf;`
			`rightxf += rightdeltaxf;`
			`++span;`
			`targetSurface += SurfaceWidth;`
			`zTarget += SurfaceWidth;`
			`leftZValue += leftZStep;`
			`rightZValue += rightZStep;`

			`leftTx += leftTxStep;`
			`leftTy += leftTyStep;`
			`rightTx += rightTxStep;`
			`rightTy += rightTyStep;`
			`}`

			`if (triangleHalf>0) // break, we've gout only two halves`
			`break;`


			`// setup variables for second half of the triangle.`

			`if (longest < 0.0f)`
			`{`
			`tmpDiv = 1.0f / (v3->Pos.Y - v2->Pos.Y);`

			`rightdeltaxf = (v3->Pos.X - v2->Pos.X) * tmpDiv;`
			`rightxf = (f32)v2->Pos.X;`

			`rightZValue = v2->ZValue;`
			`rightZStep = (s32)((v3->ZValue - v2->ZValue) * tmpDiv);`

			`rightTx = v2->TCoords.X;`
			`rightTy = v2->TCoords.Y;`
			`rightTxStep = (s32)((v3->TCoords.X - rightTx) * tmpDiv);`
			`rightTyStep = (s32)((v3->TCoords.Y - rightTy) * tmpDiv);`
			`}`
			`else`
			`{`
			`tmpDiv = 1.0f / (v3->Pos.Y - v2->Pos.Y);`

			`leftdeltaxf = (v3->Pos.X - v2->Pos.X) * tmpDiv;`
			`leftxf = (f32)v2->Pos.X;`

			`leftZValue = v2->ZValue;`
			`leftZStep = (s32)((v3->ZValue - v2->ZValue) * tmpDiv);`

			`leftTx = v2->TCoords.X;`
			`leftTy = v2->TCoords.Y;`
			`leftTxStep = (s32)((v3->TCoords.X - leftTx) * tmpDiv);`
			`leftTyStep = (s32)((v3->TCoords.Y - leftTy) * tmpDiv);`
			`}`


			`spanEnd = v3->Pos.Y;`
			`}`

			`}`

			`ZBuffer->unlock();`
			`}`
			`};`

			`} // end namespace video`
			`} // end namespace irr`

			`#endif // _IRR_COMPILE_WITH_SOFTWARE_`

			`namespace irr`
			`{`
			`namespace video`
			`{`

			`//! creates a flat triangle renderer`
			`ITriangleRenderer* createTriangleRendererTextureFlatWire(IZBuffer* zbuffer)`
			`{`
			`#ifdef _IRR_COMPILE_WITH_SOFTWARE_`
			`return new CTRTextureFlatWire(zbuffer);`
			`#else`
			`return 0;`
			`#endif // _IRR_COMPILE_WITH_SOFTWARE_`
			`}`

			`} // end namespace video`
			`} // end namespace irr`