/* =========================================================================== Copyright (C) 2000 - 2013, Raven Software, Inc. Copyright (C) 2001 - 2013, Activision, Inc. Copyright (C) 2013 - 2015, OpenJK contributors This file is part of the OpenJK source code. OpenJK is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, see . =========================================================================== */ // tr_glow.c -- this file deals with the arb shaders for dynamic glow #include "tr_local.h" ///////////////////////////////////////////////////////////////////////////////////////////////////////////// // Vertex and Pixel Shader definitions. - AReis /***********************************************************************************************************/ // This vertex shader basically passes through most values and calculates no lighting. The only // unusual thing it does is add the inputed texel offsets to all four texture units (this allows // nearest neighbor pixel peeking). const unsigned char g_strGlowVShaderARB[] = { "!!ARBvp1.0\ \ # Input.\n\ ATTRIB iPos = vertex.position;\ ATTRIB iColor = vertex.color;\ ATTRIB iTex0 = vertex.texcoord[0];\ ATTRIB iTex1 = vertex.texcoord[1];\ ATTRIB iTex2 = vertex.texcoord[2];\ ATTRIB iTex3 = vertex.texcoord[3];\ \ # Output.\n\ OUTPUT oPos = result.position;\ OUTPUT oColor = result.color;\ OUTPUT oTex0 = result.texcoord[0];\ OUTPUT oTex1 = result.texcoord[1];\ OUTPUT oTex2 = result.texcoord[2];\ OUTPUT oTex3 = result.texcoord[3];\ \ # Constants.\n\ PARAM ModelViewProj[4]= { state.matrix.mvp };\ PARAM TexelOffset0 = program.env[0];\ PARAM TexelOffset1 = program.env[1];\ PARAM TexelOffset2 = program.env[2];\ PARAM TexelOffset3 = program.env[3];\ \ # Main.\n\ DP4 oPos.x, ModelViewProj[0], iPos;\ DP4 oPos.y, ModelViewProj[1], iPos;\ DP4 oPos.z, ModelViewProj[2], iPos;\ DP4 oPos.w, ModelViewProj[3], iPos;\ MOV oColor, iColor;\ # Notice the optimization of using one texture coord instead of all four.\n\ ADD oTex0, iTex0, TexelOffset0;\ ADD oTex1, iTex0, TexelOffset1;\ ADD oTex2, iTex0, TexelOffset2;\ ADD oTex3, iTex0, TexelOffset3;\ \ END" }; // This Pixel Shader loads four texture units and adds them all together (with a modifier // multiplied to each in the process). The final output is r0 = t0 + t1 + t2 + t3. const unsigned char g_strGlowPShaderARB[] = { "!!ARBfp1.0\ \ # Input.\n\ ATTRIB iColor = fragment.color.primary;\ \ # Output.\n\ OUTPUT oColor = result.color;\ \ # Constants.\n\ PARAM Weight = program.env[0];\ TEMP t0;\ TEMP t1;\ TEMP t2;\ TEMP t3;\ TEMP r0;\ \ # Main.\n\ TEX t0, fragment.texcoord[0], texture[0], RECT;\ TEX t1, fragment.texcoord[1], texture[1], RECT;\ TEX t2, fragment.texcoord[2], texture[2], RECT;\ TEX t3, fragment.texcoord[3], texture[3], RECT;\ \ MUL r0, t0, Weight;\ MAD r0, t1, Weight, r0;\ MAD r0, t2, Weight, r0;\ MAD r0, t3, Weight, r0;\ \ MOV oColor, r0;\ \ END" }; /***********************************************************************************************************/ #ifndef HAVE_GLES #define GL_PROGRAM_ERROR_STRING_ARB 0x8874 #define GL_PROGRAM_ERROR_POSITION_ARB 0x864B void ARB_InitGlowShaders(void) { // Allocate and Load the global 'Glow' Vertex Program. - AReis if ( qglGenProgramsARB ) { qglGenProgramsARB( 1, &tr.glowVShader ); qglBindProgramARB( GL_VERTEX_PROGRAM_ARB, tr.glowVShader ); qglProgramStringARB( GL_VERTEX_PROGRAM_ARB, GL_PROGRAM_FORMAT_ASCII_ARB, ( GLsizei ) strlen( ( char * ) g_strGlowVShaderARB ), g_strGlowVShaderARB ); // const GLubyte *strErr = qglGetString( GL_PROGRAM_ERROR_STRING_ARB ); int iErrPos = 0; qglGetIntegerv( GL_PROGRAM_ERROR_POSITION_ARB, &iErrPos ); assert( iErrPos == -1 ); } // NOTE: I make an assumption here. If you have (current) nvidia hardware, you obviously support register combiners instead of fragment // programs, so use those. The problem with this is that nv30 WILL support fragment shaders, breaking this logic. The good thing is that // if you always ask for regcoms before fragment shaders, you'll always just use regcoms (problem solved... for now). - AReis // Load Pixel Shaders (either regcoms or fragprogs). if ( qglCombinerParameteriNV ) { // The purpose of this regcom is to blend all the pixels together from the 4 texture units, but with their // texture coordinates offset by 1 (or more) texels, effectively letting us blend adjoining pixels. The weight is // used to either strengthen or weaken the pixel intensity. The more it diffuses (the higher the radius of the glow), // the higher the intensity should be for a noticable effect. // Regcom result is: ( tex1 * fBlurWeight ) + ( tex2 * fBlurWeight ) + ( tex2 * fBlurWeight ) + ( tex2 * fBlurWeight ) // VV guys, this is the pixel shader you would use instead :-) /* // c0 is the blur weight. ps 1.1 tex t0 tex t1 tex t2 tex t3 mul r0, c0, t0; madd r0, c0, t1, r0; madd r0, c0, t2, r0; madd r0, c0, t3, r0; */ tr.glowPShader = qglGenLists( 1 ); qglNewList( tr.glowPShader, GL_COMPILE ); qglCombinerParameteriNV( GL_NUM_GENERAL_COMBINERS_NV, 2 ); // spare0 = fBlend * tex0 + fBlend * tex1. qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV, GL_TEXTURE0_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, GL_CONSTANT_COLOR0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_C_NV, GL_TEXTURE1_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_D_NV, GL_CONSTANT_COLOR0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerOutputNV( GL_COMBINER0_NV, GL_RGB, GL_DISCARD_NV, GL_DISCARD_NV, GL_SPARE0_NV, GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE ); // spare1 = fBlend * tex2 + fBlend * tex3. qglCombinerInputNV( GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_A_NV, GL_TEXTURE2_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerInputNV( GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_B_NV, GL_CONSTANT_COLOR0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerInputNV( GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_C_NV, GL_TEXTURE3_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerInputNV( GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_D_NV, GL_CONSTANT_COLOR0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglCombinerOutputNV( GL_COMBINER1_NV, GL_RGB, GL_DISCARD_NV, GL_DISCARD_NV, GL_SPARE1_NV, GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE ); // ( A * B ) + ( ( 1 - A ) * C ) + D = ( spare0 * 1 ) + ( ( 1 - spare0 ) * 0 ) + spare1 == spare0 + spare1. qglFinalCombinerInputNV( GL_VARIABLE_A_NV, GL_SPARE0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglFinalCombinerInputNV( GL_VARIABLE_B_NV, GL_ZERO, GL_UNSIGNED_INVERT_NV, GL_RGB ); qglFinalCombinerInputNV( GL_VARIABLE_C_NV, GL_ZERO, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglFinalCombinerInputNV( GL_VARIABLE_D_NV, GL_SPARE1_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB ); qglEndList(); } else if ( qglGenProgramsARB ) { qglGenProgramsARB( 1, &tr.glowPShader ); qglBindProgramARB( GL_FRAGMENT_PROGRAM_ARB, tr.glowPShader ); qglProgramStringARB( GL_FRAGMENT_PROGRAM_ARB, GL_PROGRAM_FORMAT_ASCII_ARB, ( GLsizei ) strlen( ( char * ) g_strGlowPShaderARB ), g_strGlowPShaderARB ); // const GLubyte *strErr = qglGetString( GL_PROGRAM_ERROR_STRING_ARB ); int iErrPos = 0; qglGetIntegerv( GL_PROGRAM_ERROR_POSITION_ARB, &iErrPos ); assert( iErrPos == -1 ); } } #endif