irrlicht/media/d3d9.hlsl

// Part of the Irrlicht Engine Shader example.
// These simple Direct3D9 pixel and vertex shaders will be loaded by the shaders
// example. Please note that these example shaders don't do anything really useful.
// They only demonstrate that shaders can be used in Irrlicht.

//-----------------------------------------------------------------------------
// Global variables
//-----------------------------------------------------------------------------
float4x4 mWorldViewProj; // World * View * Projection transformation
float4x4 mInvWorld;      // Inverted world matrix
float4x4 mTransWorld;    // Transposed world matrix
float3 mLightPos;        // Light position (actually just camera-pos in this case)
float4 mLightColor;      // Light color


// Vertex shader output structure
struct VS_OUTPUT
{
	float4 Position : POSITION;  // vertex position
	float4 Diffuse  : COLOR0;    // vertex diffuse color
	float2 TexCoord : TEXCOORD0; // tex coords
};


VS_OUTPUT vertexMain(in float4 vPosition : POSITION,
					in float3 vNormal    : NORMAL,
					float2 texCoord      : TEXCOORD0 )
{
	VS_OUTPUT Output;

	// transform position to clip space
	Output.Position = mul(vPosition, mWorldViewProj);

	// transform normal somehow (NOTE: for the real vertex normal you would use an inverse-transpose world matrix instead of mInvWorld)
	float3 normal = mul(float4(vNormal,0.0), mInvWorld);

	// renormalize normal
	normal = normalize(normal);

	// position in world coordinates (NOTE: not sure why transposed world is used instead of world?)
	float3 worldpos = mul(mTransWorld, vPosition);

	// calculate light vector, vtxpos - lightpos
	float3 lightVector = worldpos - mLightPos;

	// normalize light vector
	lightVector = normalize(lightVector);

	// calculate light color
	float3 tmp = dot(-lightVector, normal);
	tmp = lit(tmp.x, tmp.y, 1.0);

	tmp = mLightColor * tmp.y;
	Output.Diffuse = float4(tmp.x, tmp.y, tmp.z, 0);
	Output.TexCoord = texCoord;

	return Output;
}


// Pixel shader output structure
struct PS_OUTPUT
{
	float4 RGBColor : COLOR0; // Pixel color
};


sampler2D myTexture;
	
PS_OUTPUT pixelMain(float2 TexCoord : TEXCOORD0,
					float4 Position : POSITION,
					float4 Diffuse  : COLOR0 ) 
{
	PS_OUTPUT Output;

	float4 col = tex2D( myTexture, TexCoord ); // sample color map

	// multiply with diffuse and do other senseless operations
	Output.RGBColor = Diffuse * col;
	Output.RGBColor *= 4.0;

	return Output;
}
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			`// Part of the Irrlicht Engine Shader example.`
			`// These simple Direct3D9 pixel and vertex shaders will be loaded by the shaders`
			`// example. Please note that these example shaders don't do anything really useful.`
			`// They only demonstrate that shaders can be used in Irrlicht.`

			`//-----------------------------------------------------------------------------`
			`// Global variables`
			`//-----------------------------------------------------------------------------`
			`float4x4 mWorldViewProj; // World * View * Projection transformation`
			`float4x4 mInvWorld; // Inverted world matrix`
			`float4x4 mTransWorld; // Transposed world matrix`
			`float3 mLightPos; // Light position (actually just camera-pos in this case)`
			`float4 mLightColor; // Light color`


			`// Vertex shader output structure`
			`struct VS_OUTPUT`
			`{`
			`float4 Position : POSITION; // vertex position`
			`float4 Diffuse : COLOR0; // vertex diffuse color`
			`float2 TexCoord : TEXCOORD0; // tex coords`
			`};`


			`VS_OUTPUT vertexMain(in float4 vPosition : POSITION,`
			`in float3 vNormal : NORMAL,`
			`float2 texCoord : TEXCOORD0 )`
			`{`
			`VS_OUTPUT Output;`

			`// transform position to clip space`
			`Output.Position = mul(vPosition, mWorldViewProj);`

			`// transform normal somehow (NOTE: for the real vertex normal you would use an inverse-transpose world matrix instead of mInvWorld)`
			`float3 normal = mul(float4(vNormal,0.0), mInvWorld);`

			`// renormalize normal`
			`normal = normalize(normal);`

			`// position in world coordinates (NOTE: not sure why transposed world is used instead of world?)`
			`float3 worldpos = mul(mTransWorld, vPosition);`

			`// calculate light vector, vtxpos - lightpos`
			`float3 lightVector = worldpos - mLightPos;`

			`// normalize light vector`
			`lightVector = normalize(lightVector);`

			`// calculate light color`
			`float3 tmp = dot(-lightVector, normal);`
			`tmp = lit(tmp.x, tmp.y, 1.0);`

			`tmp = mLightColor * tmp.y;`
			`Output.Diffuse = float4(tmp.x, tmp.y, tmp.z, 0);`
			`Output.TexCoord = texCoord;`

			`return Output;`
			`}`


			`// Pixel shader output structure`
			`struct PS_OUTPUT`
			`{`
			`float4 RGBColor : COLOR0; // Pixel color`
			`};`


			`sampler2D myTexture;`

			`PS_OUTPUT pixelMain(float2 TexCoord : TEXCOORD0,`
			`float4 Position : POSITION,`
			`float4 Diffuse : COLOR0 )`
			`{`
			`PS_OUTPUT Output;`

			`float4 col = tex2D( myTexture, TexCoord ); // sample color map`

			`// multiply with diffuse and do other senseless operations`
			`Output.RGBColor = Diffuse * col;`
			`Output.RGBColor *= 4.0;`

			`return Output;`
			`}`