/* ** Polygon Doom software renderer ** Copyright (c) 2016 Magnus Norddahl ** ** This software is provided 'as-is', without any express or implied ** warranty. In no event will the authors be held liable for any damages ** arising from the use of this software. ** ** Permission is granted to anyone to use this software for any purpose, ** including commercial applications, and to alter it and redistribute it ** freely, subject to the following restrictions: ** ** 1. The origin of this software must not be misrepresented; you must not ** claim that you wrote the original software. If you use this software ** in a product, an acknowledgment in the product documentation would be ** appreciated but is not required. ** 2. Altered source versions must be plainly marked as such, and must not be ** misrepresented as being the original software. ** 3. This notice may not be removed or altered from any source distribution. ** */ #include #include "templates.h" #include "poly_thread.h" #include "screen_scanline_setup.h" #include static uint32_t SampleTexture(uint32_t u, uint32_t v, const void* texPixels, int texWidth, int texHeight, bool texBgra) { int texelX = (u * texWidth) >> 16; int texelY = (v * texHeight) >> 16; int texelOffset = texelX + texelY * texWidth; if (texBgra) { return static_cast(texPixels)[texelOffset]; } else { uint32_t c = static_cast(texPixels)[texelOffset]; return (c << 16) | 0xff000000; } } static void EffectFogBoundary(int x0, int x1, PolyTriangleThreadData* thread) { float uFogDensity = thread->PushConstants->uFogDensity; uint32_t fogcolor = MAKEARGB( 0, static_cast(clamp(thread->mainVertexShader.Data.uFogColor.r, 0.0f, 1.0f) * 255.0f), static_cast(clamp(thread->mainVertexShader.Data.uFogColor.g, 0.0f, 1.0f) * 255.0f), static_cast(clamp(thread->mainVertexShader.Data.uFogColor.b, 0.0f, 1.0f) * 255.0f)); uint32_t* fragcolor = thread->scanline.FragColor; for (int x = x0; x < x1; x++) { float fogdist = thread->scanline.W[x]; float fogfactor = std::exp2(uFogDensity * fogdist); // FragColor = vec4(uFogColor.rgb, 1.0 - fogfactor): uint32_t alpha = static_cast(clamp(1.0f - (1.0f / 255.0f), 0.0f, 1.0f) * 255.0f); fragcolor[x] = fogcolor | alpha; } } static void EffectBurn(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; int tex2Width = thread->textures[1].width; int tex2Height = thread->textures[1].height; const void* tex2Pixels = thread->textures[1].pixels; bool tex2Bgra = thread->textures[1].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t frag_r = thread->scanline.vColorR[x]; uint32_t frag_g = thread->scanline.vColorG[x]; uint32_t frag_b = thread->scanline.vColorB[x]; uint32_t frag_a = thread->scanline.vColorA[x]; frag_r += frag_r >> 7; // 255 -> 256 frag_g += frag_g >> 7; // 255 -> 256 frag_b += frag_b >> 7; // 255 -> 256 frag_a += frag_a >> 7; // 255 -> 256 uint32_t t1 = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); uint32_t t2 = SampleTexture(u[x], 0xffff - v[x], tex2Pixels, tex2Width, tex2Height, tex2Bgra); uint32_t r = (frag_r * RPART(t1)) >> 8; uint32_t g = (frag_g * GPART(t1)) >> 8; uint32_t b = (frag_b * BPART(t1)) >> 8; uint32_t a = (frag_a * APART(t2)) >> 8; fragcolor[x] = MAKEARGB(a, r, g, b); } } static void EffectStencil(int x0, int x1, PolyTriangleThreadData* thread) { /*for (int x = x0; x < x1; x++) { fragcolor[x] = 0x00ffffff; }*/ } static void FuncPaletted(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; const uint32_t* lut = (const uint32_t*)thread->textures[1].pixels; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { fragcolor[x] = lut[RPART(SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra))] | 0xff000000; } } static void FuncNoTexture(int x0, int x1, PolyTriangleThreadData* thread) { auto& streamdata = thread->mainVertexShader.Data; uint32_t a = (int)(streamdata.uObjectColor.a * 255.0f); uint32_t r = (int)(streamdata.uObjectColor.r * 255.0f); uint32_t g = (int)(streamdata.uObjectColor.g * 255.0f); uint32_t b = (int)(streamdata.uObjectColor.b * 255.0f); uint32_t texel = MAKEARGB(a, r, g, b); if (streamdata.uDesaturationFactor > 0.0f) { uint32_t t = (int)(streamdata.uDesaturationFactor * 256.0f); uint32_t inv_t = 256 - t; uint32_t gray = (RPART(texel) * 77 + GPART(texel) * 143 + BPART(texel) * 37) >> 8; texel = MAKEARGB( APART(texel), (RPART(texel) * inv_t + gray * t + 127) >> 8, (GPART(texel) * inv_t + gray * t + 127) >> 8, (BPART(texel) * inv_t + gray * t + 127) >> 8); } uint32_t* fragcolor = thread->scanline.FragColor; for (int x = x0; x < x1; x++) { fragcolor[x] = texel; } } static void FuncNormal(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t texel = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); fragcolor[x] = texel; } } static void FuncNormal_Stencil(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t texel = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); fragcolor[x] = texel | 0x00ffffff; } } static void FuncNormal_Opaque(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t texel = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); fragcolor[x] = texel | 0xff000000; } } static void FuncNormal_Inverse(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t texel = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); fragcolor[x] = MAKEARGB(APART(texel), 0xff - RPART(texel), 0xff - BPART(texel), 0xff - GPART(texel)); } } static void FuncNormal_AlphaTexture(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t texel = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); uint32_t gray = (RPART(texel) * 77 + GPART(texel) * 143 + BPART(texel) * 37) >> 8; uint32_t alpha = APART(texel); alpha += alpha >> 7; alpha = (alpha * gray + 127) >> 8; texel = (alpha << 24) | 0x00ffffff; fragcolor[x] = texel; } } static void FuncNormal_ClampY(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { fragcolor[x] = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); if (v[x] < 0.0 || v[x] > 1.0) fragcolor[x] &= 0x00ffffff; } } static void FuncNormal_InvertOpaque(int x0, int x1, PolyTriangleThreadData* thread) { int texWidth = thread->textures[0].width; int texHeight = thread->textures[0].height; const void* texPixels = thread->textures[0].pixels; bool texBgra = thread->textures[0].bgra; uint32_t* fragcolor = thread->scanline.FragColor; uint16_t* u = thread->scanline.U; uint16_t* v = thread->scanline.V; for (int x = x0; x < x1; x++) { uint32_t texel = SampleTexture(u[x], v[x], texPixels, texWidth, texHeight, texBgra); fragcolor[x] = MAKEARGB(0xff, 0xff - RPART(texel), 0xff - BPART(texel), 0xff - GPART(texel)); } } static void FuncNormal_AddColor(int x0, int x1, PolyTriangleThreadData* thread) { auto& streamdata = thread->mainVertexShader.Data; uint32_t r = (int)(streamdata.uAddColor.r * 255.0f); uint32_t g = (int)(streamdata.uAddColor.g * 255.0f); uint32_t b = (int)(streamdata.uAddColor.b * 255.0f); uint32_t* fragcolor = thread->scanline.FragColor; for (int x = x0; x < x1; x++) { uint32_t texel = fragcolor[x]; fragcolor[x] = MAKEARGB( APART(texel), min(r + RPART(texel), (uint32_t)255), min(g + GPART(texel), (uint32_t)255), min(b + BPART(texel), (uint32_t)255)); } } static void FuncNormal_AddObjectColor(int x0, int x1, PolyTriangleThreadData* thread) { auto& streamdata = thread->mainVertexShader.Data; uint32_t r = (int)(streamdata.uObjectColor.r * 256.0f); uint32_t g = (int)(streamdata.uObjectColor.g * 256.0f); uint32_t b = (int)(streamdata.uObjectColor.b * 256.0f); uint32_t* fragcolor = thread->scanline.FragColor; for (int x = x0; x < x1; x++) { uint32_t texel = fragcolor[x]; fragcolor[x] = MAKEARGB( APART(texel), min((r * RPART(texel)) >> 8, (uint32_t)255), min((g * GPART(texel)) >> 8, (uint32_t)255), min((b * BPART(texel)) >> 8, (uint32_t)255)); } } static void FuncNormal_AddObjectColor2(int x0, int x1, PolyTriangleThreadData* thread) { auto& streamdata = thread->mainVertexShader.Data; float* gradientdistZ = thread->scanline.GradientdistZ; uint32_t* fragcolor = thread->scanline.FragColor; for (int x = x0; x < x1; x++) { float t = gradientdistZ[x]; float inv_t = 1.0f - t; uint32_t r = (int)((streamdata.uObjectColor.r * inv_t + streamdata.uObjectColor2.r * t) * 256.0f); uint32_t g = (int)((streamdata.uObjectColor.g * inv_t + streamdata.uObjectColor2.g * t) * 256.0f); uint32_t b = (int)((streamdata.uObjectColor.b * inv_t + streamdata.uObjectColor2.b * t) * 256.0f); uint32_t texel = fragcolor[x]; fragcolor[x] = MAKEARGB( APART(texel), min((r * RPART(texel)) >> 8, (uint32_t)255), min((g * GPART(texel)) >> 8, (uint32_t)255), min((b * BPART(texel)) >> 8, (uint32_t)255)); } } static void FuncNormal_DesaturationFactor(int x0, int x1, PolyTriangleThreadData* thread) { auto& streamdata = thread->mainVertexShader.Data; uint32_t* fragcolor = thread->scanline.FragColor; uint32_t t = (int)(streamdata.uDesaturationFactor * 256.0f); uint32_t inv_t = 256 - t; for (int x = x0; x < x1; x++) { uint32_t texel = fragcolor[x]; uint32_t gray = (RPART(texel) * 77 + GPART(texel) * 143 + BPART(texel) * 37) >> 8; fragcolor[x] = MAKEARGB( APART(texel), (RPART(texel) * inv_t + gray * t + 127) >> 8, (GPART(texel) * inv_t + gray * t + 127) >> 8, (BPART(texel) * inv_t + gray * t + 127) >> 8); } } static void RunAlphaTest(int x0, int x1, PolyTriangleThreadData* thread) { uint32_t alphaThreshold = thread->AlphaThreshold; uint32_t* fragcolor = thread->scanline.FragColor; uint8_t* discard = thread->scanline.discard; for (int x = x0; x < x1; x++) { discard[x] = fragcolor[x] <= alphaThreshold; } } static void ProcessMaterial(int x0, int x1, PolyTriangleThreadData* thread) { if (thread->EffectState == SHADER_Paletted) // func_paletted { FuncPaletted(x0, x1, thread); } else if (thread->EffectState == SHADER_NoTexture) // func_notexture { FuncNoTexture(x0, x1, thread); } else // func_normal { auto constants = thread->PushConstants; switch (constants->uTextureMode) { default: case TM_NORMAL: case TM_FOGLAYER: FuncNormal(x0, x1, thread); break; case TM_STENCIL: FuncNormal_Stencil(x0, x1, thread); break; case TM_OPAQUE: FuncNormal_Opaque(x0, x1, thread); break; case TM_INVERSE: FuncNormal_Inverse(x0, x1, thread); break; case TM_ALPHATEXTURE: FuncNormal_AlphaTexture(x0, x1, thread); break; case TM_CLAMPY: FuncNormal_ClampY(x0, x1, thread); break; case TM_INVERTOPAQUE: FuncNormal_InvertOpaque(x0, x1, thread); break; } if (constants->uTextureMode != TM_FOGLAYER) { auto& streamdata = thread->mainVertexShader.Data; if (streamdata.uAddColor.r != 0.0f || streamdata.uAddColor.g != 0.0f || streamdata.uAddColor.b != 0.0f) { FuncNormal_AddColor(x0, x1, thread); } if (streamdata.uObjectColor2.a == 0.0f) { if (streamdata.uObjectColor.r != 1.0f || streamdata.uObjectColor.g != 1.0f || streamdata.uObjectColor.b != 1.0f) { FuncNormal_AddObjectColor(x0, x1, thread); } } else { FuncNormal_AddObjectColor2(x0, x1, thread); } if (streamdata.uDesaturationFactor > 0.0f) { FuncNormal_DesaturationFactor(x0, x1, thread); } } } } static void GetLightColor(int x0, int x1, PolyTriangleThreadData* thread) { uint32_t* fragcolor = thread->scanline.FragColor; uint32_t* lightarray = thread->scanline.lightarray; if (thread->PushConstants->uFogEnabled >= 0) { for (int x = x0; x < x1; x++) { uint32_t fg = fragcolor[x]; uint32_t lightshade = lightarray[x]; uint32_t mulA = APART(lightshade); uint32_t mulR = RPART(lightshade); uint32_t mulG = GPART(lightshade); uint32_t mulB = BPART(lightshade); mulA += mulA >> 7; mulR += mulR >> 7; mulG += mulG >> 7; mulB += mulB >> 7; uint32_t a = (APART(fg) * mulA + 127) >> 8; uint32_t r = (RPART(fg) * mulR + 127) >> 8; uint32_t g = (GPART(fg) * mulG + 127) >> 8; uint32_t b = (BPART(fg) * mulB + 127) >> 8; fragcolor[x] = MAKEARGB(a, r, g, b); } } else { uint32_t fogR = (int)((thread->mainVertexShader.Data.uFogColor.r) * 255.0f); uint32_t fogG = (int)((thread->mainVertexShader.Data.uFogColor.g) * 255.0f); uint32_t fogB = (int)((thread->mainVertexShader.Data.uFogColor.b) * 255.0f); float uFogDensity = thread->PushConstants->uFogDensity; float* w = thread->scanline.W; for (int x = x0; x < x1; x++) { uint32_t fg = fragcolor[x]; uint32_t lightshade = lightarray[x]; uint32_t mulA = APART(lightshade); uint32_t mulR = RPART(lightshade); uint32_t mulG = GPART(lightshade); uint32_t mulB = BPART(lightshade); mulA += mulA >> 7; mulR += mulR >> 7; mulG += mulG >> 7; mulB += mulB >> 7; float fogdist = max(16.0f, w[x]); float fogfactor = std::exp2(uFogDensity * fogdist); uint32_t a = (APART(fg) * mulA + 127) >> 8; uint32_t r = (RPART(fg) * mulR + 127) >> 8; uint32_t g = (GPART(fg) * mulG + 127) >> 8; uint32_t b = (BPART(fg) * mulB + 127) >> 8; uint32_t t = (int)(fogfactor * 256.0f); uint32_t inv_t = 256 - t; r = (fogR * inv_t + r * t + 127) >> 8; g = (fogG * inv_t + g * t + 127) >> 8; b = (fogB * inv_t + b * t + 127) >> 8; fragcolor[x] = MAKEARGB(a, r, g, b); } } } static void MainFP(int x0, int x1, PolyTriangleThreadData* thread) { ProcessMaterial(x0, x1, thread); if (thread->AlphaTest) RunAlphaTest(x0, x1, thread); auto constants = thread->PushConstants; if (constants->uFogEnabled != -3) { if (constants->uTextureMode != TM_FOGLAYER) { GetLightColor(x0, x1, thread); } else { /*float fogdist = 0.0f; float fogfactor = 0.0f; if (constants->uFogEnabled != 0) { fogdist = max(16.0f, w[x]); fogfactor = std::exp2(constants->uFogDensity * fogdist); } frag = vec4(uFogColor.rgb, (1.0 - fogfactor) * frag.a * 0.75 * vColor.a);*/ } } else // simple 2D (uses the fog color to add a color overlay) { uint32_t fogR = (int)((thread->mainVertexShader.Data.uFogColor.r) * 255.0f); uint32_t fogG = (int)((thread->mainVertexShader.Data.uFogColor.g) * 255.0f); uint32_t fogB = (int)((thread->mainVertexShader.Data.uFogColor.b) * 255.0f); auto vColorR = thread->scanline.vColorR; auto vColorG = thread->scanline.vColorG; auto vColorB = thread->scanline.vColorB; auto vColorA = thread->scanline.vColorA; uint32_t* fragcolor = thread->scanline.FragColor; if (constants->uTextureMode == TM_FIXEDCOLORMAP) { // float gray = grayscale(frag); // vec4 cm = (uObjectColor + gray * (uAddColor - uObjectColor)) * 2; // frag = vec4(clamp(cm.rgb, 0.0, 1.0), frag.a); // frag = frag * vColor; // frag.rgb = frag.rgb + uFogColor.rgb; // [GEC] I leave the default floating values. float startR = thread->mainVertexShader.Data.uObjectColor.r; float startG = thread->mainVertexShader.Data.uObjectColor.g; float startB = thread->mainVertexShader.Data.uObjectColor.b; float rangeR = thread->mainVertexShader.Data.uAddColor.r - startR; float rangeG = thread->mainVertexShader.Data.uAddColor.g - startG; float rangeB = thread->mainVertexShader.Data.uAddColor.b - startB; for (int x = x0; x < x1; x++) { uint32_t a = APART(fragcolor[x]); uint32_t r = RPART(fragcolor[x]); uint32_t g = GPART(fragcolor[x]); uint32_t b = BPART(fragcolor[x]); uint32_t gray = (r * 77 + g * 143 + b * 37) >> 8; gray += (gray >> 7); // gray*=256/255 // [GEC] I use the same method as in shaders using floating values. // This avoids errors in the invulneravility colormap in Doom and Heretic. float fgray = (float)(gray / 255.f); float fr = (startR + (fgray * rangeR)) * 2; float fg = (startG + (fgray * rangeG)) * 2; float fb = (startB + (fgray * rangeB)) * 2; fr = clamp(fr, 0.0f, 1.0f); fg = clamp(fg, 0.0f, 1.0f); fb = clamp(fb, 0.0f, 1.0f); r = (uint32_t)(fr * 255.f); g = (uint32_t)(fg * 255.f); b = (uint32_t)(fb * 255.f); fragcolor[x] = MAKEARGB(a, (uint8_t)r, (uint8_t)g, (uint8_t)b); } } else { for (int x = x0; x < x1; x++) { uint32_t a = vColorA[x]; uint32_t r = vColorR[x]; uint32_t g = vColorG[x]; uint32_t b = vColorB[x]; a += a >> 7; r += r >> 7; g += g >> 7; b += b >> 7; // frag = frag * vColor; a = (APART(fragcolor[x]) * a + 127) >> 8; r = (RPART(fragcolor[x]) * r + 127) >> 8; g = (GPART(fragcolor[x]) * g + 127) >> 8; b = (BPART(fragcolor[x]) * b + 127) >> 8; // frag.rgb = frag.rgb + uFogColor.rgb; r = min(r + fogR, (uint32_t)255); g = min(g + fogG, (uint32_t)255); b = min(b + fogB, (uint32_t)255); fragcolor[x] = MAKEARGB(a, r, g, b); } } } } void ColormapFP(int x0, int x1, PolyTriangleThreadData* thread) { // This is implemented in BlendColorColormap. } void SelectFragmentShader(PolyTriangleThreadData* thread) { void (*fragshader)(int x0, int x1, PolyTriangleThreadData * thread); if (thread->ColormapShader) { fragshader = &ColormapFP; } else if (thread->SpecialEffect == EFF_FOGBOUNDARY) // fogboundary.fp { fragshader = &EffectFogBoundary; } else if (thread->SpecialEffect == EFF_BURN) // burn.fp { fragshader = &EffectBurn; } else if (thread->SpecialEffect == EFF_STENCIL) // stencil.fp { fragshader = &EffectStencil; } else { fragshader = &MainFP; } thread->FragmentShader = fragshader; }