// Copyright 2015 Dolphin Emulator Project // SPDX-License-Identifier: GPL-2.0-or-later #include "VideoCommon/UberShaderPixel.h" #include "Common/Assert.h" #include "VideoCommon/BPMemory.h" #include "VideoCommon/DriverDetails.h" #include "VideoCommon/NativeVertexFormat.h" #include "VideoCommon/PixelShaderGen.h" #include "VideoCommon/ShaderGenCommon.h" #include "VideoCommon/UberShaderCommon.h" #include "VideoCommon/VideoCommon.h" #include "VideoCommon/VideoConfig.h" #include "VideoCommon/XFMemory.h" namespace UberShader { namespace { void WriteCustomShaderStructImpl(ShaderCode* out, u32 num_texgen, bool per_pixel_lighting) { out->Write("\tCustomShaderData custom_data;\n"); if (per_pixel_lighting) { out->Write("\tcustom_data.position = WorldPos;\n"); out->Write("\tcustom_data.normal = Normal;\n"); } else { out->Write("\tcustom_data.position = float3(0, 0, 0);\n"); out->Write("\tcustom_data.normal = float3(0, 0, 0);\n"); } if (num_texgen == 0) [[unlikely]] { out->Write("\tcustom_data.texcoord[0] = float3(0, 0, 0);\n"); } else { for (u32 i = 0; i < num_texgen; ++i) { out->Write("\tif (tex{0}.z == 0.0)\n", i); out->Write("\t{{\n"); out->Write("\t\tcustom_data.texcoord[{0}] = tex{0};\n", i); out->Write("\t}}\n"); out->Write("\telse {{\n"); out->Write("\t\tcustom_data.texcoord[{0}] = float3(tex{0}.xy / tex{0}.z, 0);\n", i); out->Write("\t}}\n"); } } out->Write("\tcustom_data.texcoord_count = {};\n", num_texgen); for (u32 i = 0; i < 8; i++) { // Shader compilation complains if every index isn't initialized out->Write("\tcustom_data.texmap_to_texcoord_index[{0}] = {0};\n", i); } for (u32 i = 0; i < NUM_XF_COLOR_CHANNELS; i++) { out->Write("\tcustom_data.base_material[{}] = vec4(0, 0, 0, 1);\n", i); out->Write("\tcustom_data.ambient_lighting[{}] = vec4(0, 0, 0, 1);\n", i); // Shader compilation errors can throw if not everything is initialized for (u32 light_count_index = 0; light_count_index < 8; light_count_index++) { // Color out->Write("\tcustom_data.lights_chan{}_color[{}].direction = float3(0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_color[{}].position = float3(0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_color[{}].color = float3(0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_color[{}].cosatt = float4(0, 0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_color[{}].distatt = float4(0, 0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_color[{}].attenuation_type = 0;\n", i, light_count_index); // Alpha out->Write("\tcustom_data.lights_chan{}_alpha[{}].direction = float3(0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_alpha[{}].position = float3(0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_alpha[{}].color = float3(0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_alpha[{}].cosatt = float4(0, 0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_alpha[{}].distatt = float4(0, 0, 0, 0);\n", i, light_count_index); out->Write("\tcustom_data.lights_chan{}_alpha[{}].attenuation_type = 0;\n", i, light_count_index); } out->Write("\tcustom_data.light_chan{}_color_count = 0;\n", i); out->Write("\tcustom_data.light_chan{}_alpha_count = 0;\n", i); } if (num_texgen > 0) [[likely]] { out->Write("\n"); out->Write("\tfor(uint stage = 0u; stage <= num_stages; stage++)\n"); out->Write("\t{{\n"); out->Write("\t\tStageState ss;\n"); out->Write("\t\tss.order = bpmem_tevorder(stage>>1);\n"); out->Write("\t\tif ((stage & 1u) == 1u)\n"); out->Write("\t\t\tss.order = ss.order >> {};\n\n", int(TwoTevStageOrders().enable_tex_odd.StartBit() - TwoTevStageOrders().enable_tex_even.StartBit())); out->Write("\t\tuint texmap = {};\n", BitfieldExtract<&TwoTevStageOrders::texcoord_even>("ss.order")); // Shader compilation is weird, shader arrays can't use indexing by variable // to set values unless the variable is an index in a for loop. // So instead we have to do this if check nonsense for (u32 i = 0; i < 8; i++) { out->Write("\t\tif (texmap == {})\n", i); out->Write("\t\t{{\n"); out->Write("\t\t\tcustom_data.texmap_to_texcoord_index[{}] = selectTexCoordIndex(texmap);\n", i); out->Write("\t\t}}\n"); } out->Write("\t}}\n"); } if (per_pixel_lighting) { out->Write("\tuint light_count = 0;\n"); out->Write("\tfor (uint chan = 0u; chan < {}u; chan++)\n", NUM_XF_COLOR_CHANNELS); out->Write("\t{{\n"); out->Write("\t\tuint colorreg = xfmem_color(chan);\n"); out->Write("\t\tuint alphareg = xfmem_alpha(chan);\n"); for (const auto& color_type : std::array{"colorreg", "alphareg"}) { if (color_type == "colorreg") { out->Write("\t\tcustom_data.base_material[0] = " I_MATERIALS "[2u] / 255.0; \n"); out->Write("\t\tif ({} != 0u)\n", BitfieldExtract<&LitChannel::enablelighting>(color_type)); out->Write("\t\t\tcustom_data.base_material[0] = colors_0; \n"); } else { out->Write("custom_data.base_material[1].w = " I_MATERIALS "[3u].w / 255.0; \n"); out->Write("\t\tif ({} != 0u)\n", BitfieldExtract<&LitChannel::enablelighting>(color_type)); out->Write("\t\t\tcustom_data.base_material[1].w = colors_1.w; \n"); } out->Write("\t\tif ({} != 0u)\n", BitfieldExtract<&LitChannel::enablelighting>(color_type)); out->Write("\t\t{{\n"); out->Write("\t\t\tuint light_mask = {} | ({} << 4u);\n", BitfieldExtract<&LitChannel::lightMask0_3>(color_type), BitfieldExtract<&LitChannel::lightMask4_7>(color_type)); out->Write("\t\t\tuint attnfunc = {};\n", BitfieldExtract<&LitChannel::attnfunc>(color_type)); out->Write("\t\t\tfor (uint light_index = 0u; light_index < 8u; light_index++)\n"); out->Write("\t\t\t{{\n"); out->Write("\t\t\t\tif ((light_mask & (1u << light_index)) != 0u)\n"); out->Write("\t\t\t\t{{\n"); // Shader compilation is weird, shader arrays can't use indexing by variable // to set values unless the variable is an index in a for loop. // So instead we have to do this if check nonsense for (u32 light_count_index = 0; light_count_index < 8; light_count_index++) { out->Write("\t\t\t\t\tif (light_index == {})\n", light_count_index); out->Write("\t\t\t\t\t{{\n"); if (color_type == "colorreg") { for (u32 channel_index = 0; channel_index < NUM_XF_COLOR_CHANNELS; channel_index++) { out->Write("\t\t\t\t\t\tif (chan == {})\n", channel_index); out->Write("\t\t\t\t\t\t{{\n"); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_color[{}].direction = " I_LIGHTS "[light_index].dir.xyz;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_color[{}].position = " I_LIGHTS "[light_index].pos.xyz;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_color[{}].cosatt = " I_LIGHTS "[light_index].cosatt;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_color[{}].distatt = " I_LIGHTS "[light_index].distatt;\n", channel_index, light_count_index); out->Write( "\t\t\t\t\t\t\tcustom_data.lights_chan{}_color[{}].attenuation_type = attnfunc;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_color[{}].color = " I_LIGHTS "[light_index].color.rgb / float3(255.0, 255.0, 255.0);\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.light_chan{}_color_count += 1;\n", channel_index); out->Write("\t\t\t\t\t\t}}\n"); } } else { for (u32 channel_index = 0; channel_index < NUM_XF_COLOR_CHANNELS; channel_index++) { out->Write("\t\t\t\t\t\tif (chan == {})\n", channel_index); out->Write("\t\t\t\t\t\t{{\n"); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_alpha[{}].direction = " I_LIGHTS "[light_index].dir.xyz;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_alpha[{}].position = " I_LIGHTS "[light_index].pos.xyz;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_alpha[{}].cosatt = " I_LIGHTS "[light_index].cosatt;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_alpha[{}].distatt = " I_LIGHTS "[light_index].distatt;\n", channel_index, light_count_index); out->Write( "\t\t\t\t\t\t\tcustom_data.lights_chan{}_alpha[{}].attenuation_type = attnfunc;\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.lights_chan{}_alpha[{}].color = float3(" I_LIGHTS "[light_index].color.a) / float3(255.0, 255.0, 255.0);\n", channel_index, light_count_index); out->Write("\t\t\t\t\t\t\tcustom_data.light_chan{}_alpha_count += 1;\n", channel_index); out->Write("\t\t\t\t\t\t}}\n"); } } out->Write("\t\t\t\t\t}}\n"); } out->Write("\t\t\t\t}}\n"); out->Write("\t\t\t}}\n"); out->Write("\t\t}}\n"); } out->Write("\t}}\n"); } for (u32 i = 0; i < 16; i++) { // Shader compilation complains if every struct isn't initialized // Color Input for (u32 j = 0; j < 4; j++) { out->Write("\tcustom_data.tev_stages[{}].input_color[{}].input_type = " "CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_UNUSED;\n", i, j); out->Write("\tcustom_data.tev_stages[{}].input_color[{}].value = " "float3(0, 0, 0);\n", i, j); } // Alpha Input for (u32 j = 0; j < 4; j++) { out->Write("\tcustom_data.tev_stages[{}].input_alpha[{}].input_type = " "CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_UNUSED;\n", i, j); out->Write("\tcustom_data.tev_stages[{}].input_alpha[{}].value = " "float(0);\n", i, j); } // Texmap out->Write("\tcustom_data.tev_stages[{}].texmap = 0u;\n", i); // Output out->Write("\tcustom_data.tev_stages[{}].output_color = " "float4(0, 0, 0, 0);\n", i); } // Actual data will be filled out in the tev stage code, just set the // stage count for now out->Write("\tcustom_data.tev_stage_count = num_stages;\n"); // Time out->Write("\tcustom_data.time_ms = time_ms;\n"); } } // namespace PixelShaderUid GetPixelShaderUid() { PixelShaderUid out; pixel_ubershader_uid_data* const uid_data = out.GetUidData(); uid_data->num_texgens = xfmem.numTexGen.numTexGens; uid_data->early_depth = bpmem.GetEmulatedZ() == EmulatedZ::Early && (g_ActiveConfig.bFastDepthCalc || bpmem.alpha_test.TestResult() == AlphaTestResult::Undetermined) && !(bpmem.zmode.testenable && bpmem.genMode.zfreeze); uid_data->per_pixel_depth = (bpmem.ztex2.op != ZTexOp::Disabled && bpmem.GetEmulatedZ() == EmulatedZ::Late) || (!g_ActiveConfig.bFastDepthCalc && bpmem.zmode.testenable && !uid_data->early_depth) || (bpmem.zmode.testenable && bpmem.genMode.zfreeze); uid_data->uint_output = bpmem.blendmode.UseLogicOp(); return out; } void ClearUnusedPixelShaderUidBits(APIType api_type, const ShaderHostConfig& host_config, PixelShaderUid* uid) { pixel_ubershader_uid_data* const uid_data = uid->GetUidData(); // With fbfetch, ubershaders always blend using that and don't use dual src if (host_config.backend_shader_framebuffer_fetch || !host_config.backend_dual_source_blend) uid_data->no_dual_src = 1; // Dual source is always enabled in the shader if this bug is not present else if (!DriverDetails::HasBug(DriverDetails::BUG_BROKEN_DUAL_SOURCE_BLENDING)) uid_data->no_dual_src = 0; // OpenGL and Vulkan convert implicitly normalized color outputs to their uint representation. // Therefore, it is not necessary to use a uint output on these backends. We also disable the // uint output when logic op is not supported (i.e. driver/device does not support D3D11.1). if (api_type != APIType::D3D || !host_config.backend_logic_op) uid_data->uint_output = 0; } ShaderCode GenPixelShader(APIType api_type, const ShaderHostConfig& host_config, const pixel_ubershader_uid_data* uid_data, const CustomPixelShaderContents& custom_details) { const bool per_pixel_lighting = host_config.per_pixel_lighting; const bool msaa = host_config.msaa; const bool ssaa = host_config.ssaa; const bool stereo = host_config.stereo; const bool use_framebuffer_fetch = host_config.backend_shader_framebuffer_fetch; const bool use_dual_source = host_config.backend_dual_source_blend && !uid_data->no_dual_src; const bool early_depth = uid_data->early_depth != 0; const bool per_pixel_depth = uid_data->per_pixel_depth != 0; const bool bounding_box = host_config.bounding_box; const u32 numTexgen = uid_data->num_texgens; ShaderCode out; ASSERT_MSG(VIDEO, !(use_dual_source && use_framebuffer_fetch), "If you're using framebuffer fetch, you shouldn't need dual source blend!"); out.Write("// {}\n", *uid_data); WriteBitfieldExtractHeader(out, api_type, host_config); WritePixelShaderCommonHeader(out, api_type, host_config, bounding_box, custom_details); WriteCustomShaderStructDef(&out, numTexgen); for (std::size_t i = 0; i < custom_details.shaders.size(); i++) { const auto& shader_details = custom_details.shaders[i]; out.Write(fmt::runtime(shader_details.custom_shader), i); } if (per_pixel_lighting) WriteLightingFunction(out); #ifdef __APPLE__ // Framebuffer fetch is only supported by Metal, so ensure that we're running Vulkan (MoltenVK) // if we want to use it. if (api_type == APIType::Vulkan || api_type == APIType::Metal) { if (use_dual_source) { out.Write("FRAGMENT_OUTPUT_LOCATION_INDEXED(0, 0) out vec4 ocol0;\n" "FRAGMENT_OUTPUT_LOCATION_INDEXED(0, 1) out vec4 ocol1;\n"); } else { // Metal doesn't support a single unified variable for both input and output, // so when using framebuffer fetch, we declare the input separately below. out.Write("FRAGMENT_OUTPUT_LOCATION(0) out vec4 {};\n", use_framebuffer_fetch ? "real_ocol0" : "ocol0"); } if (use_framebuffer_fetch) { // Subpass inputs will be converted to framebuffer fetch by SPIRV-Cross. out.Write("INPUT_ATTACHMENT_BINDING(0, 0, 0) uniform subpassInput in_ocol0;\n"); } } else #endif { if (use_framebuffer_fetch) { out.Write("FRAGMENT_OUTPUT_LOCATION(0) FRAGMENT_INOUT vec4 real_ocol0;\n"); } else { out.Write("FRAGMENT_OUTPUT_LOCATION_INDEXED(0, 0) out {} ocol0;\n", uid_data->uint_output ? "uvec4" : "vec4"); } if (use_dual_source) { out.Write("{} out {} ocol1;\n", "FRAGMENT_OUTPUT_LOCATION_INDEXED(0, 1)", uid_data->uint_output ? "uvec4" : "vec4"); } } if (per_pixel_depth) out.Write("#define depth gl_FragDepth\n"); if (host_config.backend_geometry_shaders) { out.Write("VARYING_LOCATION(0) in VertexData {{\n"); GenerateVSOutputMembers(out, api_type, numTexgen, host_config, GetInterpolationQualifier(msaa, ssaa, true, true), ShaderStage::Pixel); out.Write("}};\n\n"); if (stereo && !host_config.backend_gl_layer_in_fs) out.Write("flat in int layer;"); } else { // Let's set up attributes u32 counter = 0; out.Write("VARYING_LOCATION({}) {} in float4 colors_0;\n", counter++, GetInterpolationQualifier(msaa, ssaa)); out.Write("VARYING_LOCATION({}) {} in float4 colors_1;\n", counter++, GetInterpolationQualifier(msaa, ssaa)); for (u32 i = 0; i < numTexgen; ++i) { out.Write("VARYING_LOCATION({}) {} in float3 tex{};\n", counter++, GetInterpolationQualifier(msaa, ssaa), i); } if (!host_config.fast_depth_calc) { out.Write("VARYING_LOCATION({}) {} in float4 clipPos;\n", counter++, GetInterpolationQualifier(msaa, ssaa)); } if (per_pixel_lighting) { out.Write("VARYING_LOCATION({}) {} in float3 Normal;\n", counter++, GetInterpolationQualifier(msaa, ssaa)); out.Write("VARYING_LOCATION({}) {} in float3 WorldPos;\n", counter++, GetInterpolationQualifier(msaa, ssaa)); } } // Uniform index -> texture coordinates // Quirk: when the tex coord is not less than the number of tex gens (i.e. the tex coord does // not exist), then tex coord 0 is used (though sometimes glitchy effects happen on console). // This affects the Mario portrait in Luigi's Mansion, where the developers forgot to set // the number of tex gens to 2 (bug 11462). if (numTexgen > 0) { out.Write("int2 selectTexCoord(uint index"); for (u32 i = 0; i < numTexgen; i++) out.Write(", int2 fixpoint_uv{}", i); out.Write(") {{\n"); if (api_type == APIType::D3D) { out.Write(" switch (index) {{\n"); for (u32 i = 0; i < numTexgen; i++) { out.Write(" case {}u:\n" " return fixpoint_uv{};\n", i, i); } out.Write(" default:\n" " return fixpoint_uv0;\n" " }}\n"); } else { out.Write(" if (index >= {}u) {{\n", numTexgen); out.Write(" return fixpoint_uv0;\n" " }}\n"); if (numTexgen > 4) out.Write(" if (index < 4u) {{\n"); if (numTexgen > 2) out.Write(" if (index < 2u) {{\n"); if (numTexgen > 1) out.Write(" return (index == 0u) ? fixpoint_uv0 : fixpoint_uv1;\n"); else out.Write(" return fixpoint_uv0;\n"); if (numTexgen > 2) { out.Write(" }} else {{\n"); // >= 2 < min(4, numTexgen) if (numTexgen > 3) out.Write(" return (index == 2u) ? fixpoint_uv2 : fixpoint_uv3;\n"); else out.Write(" return fixpoint_uv2;\n"); out.Write(" }}\n"); } if (numTexgen > 4) { out.Write(" }} else {{\n"); // >= 4 < min(8, numTexgen) if (numTexgen > 6) out.Write(" if (index < 6u) {{\n"); if (numTexgen > 5) out.Write(" return (index == 4u) ? fixpoint_uv4 : fixpoint_uv5;\n"); else out.Write(" return fixpoint_uv4;\n"); if (numTexgen > 6) { out.Write(" }} else {{\n"); // >= 6 < min(8, numTexgen) if (numTexgen > 7) out.Write(" return (index == 6u) ? fixpoint_uv6 : fixpoint_uv7;\n"); else out.Write(" return fixpoint_uv6;\n"); out.Write(" }}\n"); } out.Write(" }}\n"); } } out.Write("}}\n\n"); out.Write("uint selectTexCoordIndex(uint texmap)"); out.Write("{{\n"); if (api_type == APIType::D3D) { out.Write(" switch (texmap) {{\n"); for (u32 i = 0; i < numTexgen; i++) { out.Write(" case {}u:\n" " return {}u;\n", i, i); } out.Write(" default:\n" " return 0u;\n" " }}\n"); } else { out.Write(" if (texmap >= {}u) {{\n", numTexgen); out.Write(" return 0u;\n" " }}\n"); if (numTexgen > 4) out.Write(" if (texmap < 4u) {{\n"); if (numTexgen > 2) out.Write(" if (texmap < 2u) {{\n"); if (numTexgen > 1) out.Write(" return (texmap == 0u) ? 0u : 1u;\n"); else out.Write(" return 0u;\n"); if (numTexgen > 2) { out.Write(" }} else {{\n"); // >= 2 < min(4, numTexgen) if (numTexgen > 3) out.Write(" return (texmap == 2u) ? 2u : 3u;\n"); else out.Write(" return 2u;\n"); out.Write(" }}\n"); } if (numTexgen > 4) { out.Write(" }} else {{\n"); // >= 4 < min(8, numTexgen) if (numTexgen > 6) out.Write(" if (texmap < 6u) {{\n"); if (numTexgen > 5) out.Write(" return (texmap == 4u) ? 4u : 5u;\n"); else out.Write(" return 4u;\n"); if (numTexgen > 6) { out.Write(" }} else {{\n"); // >= 6 < min(8, numTexgen) if (numTexgen > 7) out.Write(" return (texmap == 6u) ? 6u : 7u;\n"); else out.Write(" return 6u;\n"); out.Write(" }}\n"); } out.Write(" }}\n"); } } out.Write("}}\n\n"); } // ===================== // Texture Sampling // ===================== if (host_config.backend_dynamic_sampler_indexing) { // Doesn't look like DirectX supports this. Oh well the code path is here just in case it // supports this in the future. out.Write("int4 sampleTextureWrapper(uint texmap, int2 uv, int layer) {{\n"); out.Write(" return sampleTexture(texmap, samp[texmap], uv, layer);\n"); out.Write("}}\n\n"); } else { out.Write("int4 sampleTextureWrapper(uint sampler_num, int2 uv, int layer) {{\n" " // This is messy, but DirectX, OpenGL 3.3, and OpenGL ES 3.0 don't support " "dynamic indexing of the sampler array\n" " // With any luck the shader compiler will optimise this if the hardware supports " "dynamic indexing.\n" " switch(sampler_num) {{\n"); for (int i = 0; i < 8; i++) { out.Write(" case {0}u: return sampleTexture({0}u, samp[{0}u], uv, layer);\n", i); } out.Write(" }}\n" "}}\n\n"); } // ====================== // Arbitrary Swizzling // ====================== out.Write("int4 Swizzle(uint s, int4 color) {{\n" " // AKA: Color Channel Swapping\n" "\n" " int4 ret;\n"); out.Write(" ret.r = color[{}];\n", BitfieldExtract<&TevKSel::swap_rb>("bpmem_tevksel(s * 2u)")); out.Write(" ret.g = color[{}];\n", BitfieldExtract<&TevKSel::swap_ga>("bpmem_tevksel(s * 2u)")); out.Write(" ret.b = color[{}];\n", BitfieldExtract<&TevKSel::swap_rb>("bpmem_tevksel(s * 2u + 1u)")); out.Write(" ret.a = color[{}];\n", BitfieldExtract<&TevKSel::swap_ga>("bpmem_tevksel(s * 2u + 1u)")); out.Write(" return ret;\n" "}}\n\n"); // ====================== // Indirect Wrapping // ====================== out.Write("int Wrap(int coord, uint mode) {{\n" " if (mode == 0u) // ITW_OFF\n" " return coord;\n" " else if (mode < 6u) // ITW_256 to ITW_16\n" " return coord & (0xfffe >> mode);\n" " else // ITW_0\n" " return 0;\n" "}}\n\n"); // ====================== // Indirect Lookup // ====================== const auto LookupIndirectTexture = [&out](std::string_view out_var_name, std::string_view in_index_name) { // in_index_name is the indirect stage, not the tev stage // bpmem_iref is packed differently from RAS1_IREF // This function assumes bpmem_iref is nonzero (i.e. matrix is not off, and the // indirect texture stage is enabled). out.Write("{{\n" " uint iref = bpmem_iref({});\n" " uint texcoord = bitfieldExtract(iref, 0, 3);\n" " uint texmap = bitfieldExtract(iref, 8, 3);\n" " int2 fixedPoint_uv = getTexCoord(texcoord);\n" "\n" " if (({} & 1u) == 0u)\n" " fixedPoint_uv = fixedPoint_uv >> " I_INDTEXSCALE "[{} >> 1].xy;\n" " else\n" " fixedPoint_uv = fixedPoint_uv >> " I_INDTEXSCALE "[{} >> 1].zw;\n" "\n" " {} = sampleTextureWrapper(texmap, fixedPoint_uv, layer).abg;\n" "}}\n", in_index_name, in_index_name, in_index_name, in_index_name, out_var_name); }; // ====================== // TEV's Special Lerp // ====================== const auto WriteTevLerp = [&out](std::string_view components) { out.Write("// TEV's Linear Interpolate, plus bias, add/subtract and scale\n" "int{0} tevLerp{0}(int{0} A, int{0} B, int{0} C, int{0} D, uint bias, bool op, " "uint scale) {{\n" " // Scale C from 0..255 to 0..256\n" " C += C >> 7;\n" "\n" " // Add bias to D\n" " if (bias == 1u) D += 128;\n" " else if (bias == 2u) D -= 128;\n" "\n" " int{0} lerp = (A << 8) + (B - A)*C;\n" " if (scale != 3u) {{\n" " lerp = lerp << scale;\n" " D = D << scale;\n" " }}\n" "\n" " // TODO: Is this rounding bias still added when the scale is divide by 2? " "Currently we " "do not apply it.\n" " if (scale != 3u)\n" " lerp = lerp + (op ? 127 : 128);\n" "\n" " int{0} result = lerp >> 8;\n" "\n" " // Add/Subtract D\n" " if (op) // Subtract\n" " result = D - result;\n" " else // Add\n" " result = D + result;\n" "\n" " // Most of the Scale was moved inside the lerp for improved precision\n" " // But we still do the divide by 2 here\n" " if (scale == 3u)\n" " result = result >> 1;\n" " return result;\n" "}}\n\n", components); }; WriteTevLerp(""); // int WriteTevLerp("3"); // int3 // ======================= // TEV's Color Compare // ======================= out.Write( "// Implements operations 0-5 of TEV's compare mode,\n" "// which are common to both color and alpha channels\n" "bool tevCompare(uint op, int3 color_A, int3 color_B) {{\n" " switch (op) {{\n" " case 0u: // TevCompareMode::R8, TevComparison::GT\n" " return (color_A.r > color_B.r);\n" " case 1u: // TevCompareMode::R8, TevComparison::EQ\n" " return (color_A.r == color_B.r);\n" " case 2u: // TevCompareMode::GR16, TevComparison::GT\n" " int A_16 = (color_A.r | (color_A.g << 8));\n" " int B_16 = (color_B.r | (color_B.g << 8));\n" " return A_16 > B_16;\n" " case 3u: // TevCompareMode::GR16, TevComparison::EQ\n" " return (color_A.r == color_B.r && color_A.g == color_B.g);\n" " case 4u: // TevCompareMode::BGR24, TevComparison::GT\n" " int A_24 = (color_A.r | (color_A.g << 8) | (color_A.b << 16));\n" " int B_24 = (color_B.r | (color_B.g << 8) | (color_B.b << 16));\n" " return A_24 > B_24;\n" " case 5u: // TevCompareMode::BGR24, TevComparison::EQ\n" " return (color_A.r == color_B.r && color_A.g == color_B.g && color_A.b == color_B.b);\n" " default:\n" " return false;\n" " }}\n" "}}\n\n"); // ================= // Input Selects // ================= out.Write("struct State {{\n" " int4 Reg[4];\n" " int4 TexColor;\n" " int AlphaBump;\n" "}};\n" "struct StageState {{\n" " uint stage;\n" " uint order;\n" " uint cc;\n" " uint ac;\n" "}};\n" "\n" "int4 getRasColor(State s, StageState ss, float4 colors_0, float4 colors_1);\n" "int4 getKonstColor(State s, StageState ss);\n" "\n"); static constexpr Common::EnumMap tev_alpha_funcs_table{ "return false;", // CompareMode::Never "return a < b;", // CompareMode::Less "return a == b;", // CompareMode::Equal "return a <= b;", // CompareMode::LEqual "return a > b;", // CompareMode::Greater "return a != b;", // CompareMode::NEqual "return a >= b;", // CompareMode::GEqual "return true;" // CompareMode::Always }; static constexpr Common::EnumMap tev_c_input_table{ "return s.Reg[0].rgb;", // CPREV, "return s.Reg[0].aaa;", // APREV, "return s.Reg[1].rgb;", // C0, "return s.Reg[1].aaa;", // A0, "return s.Reg[2].rgb;", // C1, "return s.Reg[2].aaa;", // A1, "return s.Reg[3].rgb;", // C2, "return s.Reg[3].aaa;", // A2, "return s.TexColor.rgb;", // TEXC, "return s.TexColor.aaa;", // TEXA, "return getRasColor(s, ss, colors_0, colors_1).rgb;", // RASC, "return getRasColor(s, ss, colors_0, colors_1).aaa;", // RASA, "return int3(255, 255, 255);", // ONE "return int3(128, 128, 128);", // HALF "return getKonstColor(s, ss).rgb;", // KONST "return int3(0, 0, 0);", // ZERO }; static constexpr Common::EnumMap tev_c_input_type{ "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_PREV;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_PREV;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_TEX;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_TEX;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_RAS;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_RAS;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_NUMERIC;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_NUMERIC;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_KONST;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_NUMERIC;", }; static constexpr Common::EnumMap tev_a_input_table{ "return s.Reg[0].a;", // APREV, "return s.Reg[1].a;", // A0, "return s.Reg[2].a;", // A1, "return s.Reg[3].a;", // A2, "return s.TexColor.a;", // TEXA, "return getRasColor(s, ss, colors_0, colors_1).a;", // RASA, "return getKonstColor(s, ss).a;", // KONST, (hw1 had quarter) "return 0;", // ZERO }; static constexpr Common::EnumMap tev_a_input_type{ "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_PREV;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_COLOR;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_TEX;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_RAS;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_KONST;", "return CUSTOM_SHADER_TEV_STAGE_INPUT_TYPE_NUMERIC;", }; static constexpr Common::EnumMap tev_regs_lookup_table{ "return s.Reg[0];", "return s.Reg[1];", "return s.Reg[2];", "return s.Reg[3];", }; static constexpr Common::EnumMap tev_c_set_table{ "s.Reg[0].rgb = color;", "s.Reg[1].rgb = color;", "s.Reg[2].rgb = color;", "s.Reg[3].rgb = color;", }; static constexpr Common::EnumMap tev_a_set_table{ "s.Reg[0].a = alpha;", "s.Reg[1].a = alpha;", "s.Reg[2].a = alpha;", "s.Reg[3].a = alpha;", }; out.Write("// Helper function for Alpha Test\n" "bool alphaCompare(int a, int b, uint compare) {{\n"); WriteSwitch(out, api_type, "compare", tev_alpha_funcs_table, 2, false); out.Write("}}\n" "\n" "int3 selectColorInput(State s, StageState ss, float4 colors_0, float4 colors_1, " "uint index) {{\n"); WriteSwitch(out, api_type, "index", tev_c_input_table, 2, false); out.Write("}}\n" "\n" "int selectAlphaInput(State s, StageState ss, float4 colors_0, float4 colors_1, " "uint index) {{\n"); WriteSwitch(out, api_type, "index", tev_a_input_table, 2, false); out.Write("}}\n" "\n" "int4 getTevReg(in State s, uint index) {{\n"); WriteSwitch(out, api_type, "index", tev_regs_lookup_table, 2, false); out.Write("}}\n" "\n"); out.Write("// Helper function for Custom Shader Input Type\n" "uint getColorInputType(uint index) {{\n"); WriteSwitch(out, api_type, "index", tev_c_input_type, 2, false); out.Write("}}\n" "\n" "uint getAlphaInputType(uint index) {{\n"); WriteSwitch(out, api_type, "index", tev_a_input_type, 2, false); out.Write("}}\n" "\n"); // Since the fixed-point texture coodinate variables aren't global, we need to pass // them to the select function. This applies to all backends. if (numTexgen > 0) { out.Write("#define getTexCoord(index) selectTexCoord((index)"); for (u32 i = 0; i < numTexgen; i++) out.Write(", fixpoint_uv{}", i); out.Write(")\n\n"); } if (early_depth && host_config.backend_early_z) out.Write("FORCE_EARLY_Z;\n"); out.Write("void main()\n{{\n"); out.Write(" float4 rawpos = gl_FragCoord;\n"); out.Write(" uint num_stages = {};\n\n", BitfieldExtract<&GenMode::numtevstages>("bpmem_genmode")); bool has_custom_shader_details = false; if (std::any_of(custom_details.shaders.begin(), custom_details.shaders.end(), [](const std::optional& ps) { return ps.has_value(); })) { WriteCustomShaderStructImpl(&out, numTexgen, per_pixel_lighting); has_custom_shader_details = true; } if (use_framebuffer_fetch) { // Store off a copy of the initial framebuffer value. // // If FB_FETCH_VALUE isn't defined (i.e. no special keyword for fetching from the // framebuffer), we read from real_ocol0. out.Write("#ifdef FB_FETCH_VALUE\n" " float4 initial_ocol0 = FB_FETCH_VALUE;\n" "#else\n" " float4 initial_ocol0 = real_ocol0;\n" "#endif\n"); // QComm's Adreno driver doesn't seem to like using the framebuffer_fetch value as an // intermediate value with multiple reads & modifications, so we pull out the "real" output // value above and use a temporary for calculations, then set the output value once at the // end of the shader. out.Write(" float4 ocol0;\n" " float4 ocol1;\n"); } if (host_config.backend_geometry_shaders && stereo) { if (host_config.backend_gl_layer_in_fs) out.Write("\tint layer = gl_Layer;\n"); } else { out.Write("\tint layer = 0;\n"); } out.Write(" int3 tevcoord = int3(0, 0, 0);\n" " State s;\n" " s.TexColor = int4(0, 0, 0, 0);\n" " s.AlphaBump = 0;\n" "\n"); for (int i = 0; i < 4; i++) out.Write(" s.Reg[{}] = " I_COLORS "[{}];\n", i, i); const char* color_input_prefix = ""; if (per_pixel_lighting) { out.Write(" float4 lit_colors_0 = colors_0;\n" " float4 lit_colors_1 = colors_1;\n" " float3 lit_normal = normalize(Normal.xyz);\n" " float3 lit_pos = WorldPos.xyz;\n"); WriteVertexLighting(out, api_type, "lit_pos", "lit_normal", "colors_0", "colors_1", "lit_colors_0", "lit_colors_1"); color_input_prefix = "lit_"; out.Write(" // The number of colors available to TEV is determined by numColorChans.\n" " // Normally this is performed in the vertex shader after lighting,\n" " // but with per-pixel lighting, we need to perform it here.\n" " // TODO: Actually implement this for ubershaders\n" " // if (xfmem_numColorChans == 0u)\n" " // o.colors_0 = float4(0.0, 0.0, 0.0, 0.0);\n" " // if (xfmem_numColorChans <= 1u)\n" " // o.colors_1 = float4(0.0, 0.0, 0.0, 0.0);\n"); } out.Write(" // Main tev loop\n"); out.Write(" for(uint stage = 0u; stage <= num_stages; stage++)\n" " {{\n" " StageState ss;\n" " ss.stage = stage;\n" " ss.cc = bpmem_combiners(stage).x;\n" " ss.ac = bpmem_combiners(stage).y;\n" " ss.order = bpmem_tevorder(stage>>1);\n" " if ((stage & 1u) == 1u)\n" " ss.order = ss.order >> {};\n\n", int(TwoTevStageOrders().enable_tex_odd.StartBit() - TwoTevStageOrders().enable_tex_even.StartBit())); // Disable texturing when there are no texgens (for now) if (numTexgen != 0) { for (u32 i = 0; i < numTexgen; i++) { out.Write(" int2 fixpoint_uv{} = int2(", i); out.Write("(tex{}.z == 0.0 ? tex{}.xy : tex{}.xy / tex{}.z)", i, i, i, i); out.Write(" * float2(" I_TEXDIMS "[{}].zw * 128));\n", i); // TODO: S24 overflows here? } out.Write("\n" " uint tex_coord = {};\n", BitfieldExtract<&TwoTevStageOrders::texcoord_even>("ss.order")); out.Write(" int2 fixedPoint_uv = getTexCoord(tex_coord);\n" "\n" " bool texture_enabled = (ss.order & {}u) != 0u;\n", 1 << TwoTevStageOrders().enable_tex_even.StartBit()); out.Write("\n" " // Indirect textures\n" " uint tevind = bpmem_tevind(stage);\n" " if (tevind != 0u)\n" " {{\n" " uint bs = {};\n", BitfieldExtract<&TevStageIndirect::bs>("tevind")); out.Write(" uint fmt = {};\n", BitfieldExtract<&TevStageIndirect::fmt>("tevind")); out.Write(" uint bias = {};\n", BitfieldExtract<&TevStageIndirect::bias>("tevind")); out.Write(" uint bt = {};\n", BitfieldExtract<&TevStageIndirect::bt>("tevind")); out.Write(" uint matrix_index = {};\n", BitfieldExtract<&TevStageIndirect::matrix_index>("tevind")); out.Write(" uint matrix_id = {};\n", BitfieldExtract<&TevStageIndirect::matrix_id>("tevind")); out.Write(" int2 indtevtrans = int2(0, 0);\n" "\n"); // There is always a bit set in bpmem_iref if the data is valid (matrix is not off, and the // indirect texture stage is enabled). If the matrix is off, the result doesn't matter; if the // indirect texture stage is disabled, the result is undefined (and produces a glitchy pattern // on hardware, different from this). // For the undefined case, we just skip applying the indirect operation, which is close // enough. Viewtiful Joe hits the undefined case (bug 12525). Wrapping and add to previous // still apply in this case (and when the stage is disabled). out.Write(" if (bpmem_iref(bt) != 0u) {{\n"); out.Write(" int3 indcoord;\n"); LookupIndirectTexture("indcoord", "bt"); out.Write(" if (bs != 0u)\n" " s.AlphaBump = indcoord[bs - 1u];\n" " switch(fmt)\n" " {{\n" " case {:s}:\n", IndTexFormat::ITF_8); out.Write(" indcoord.x = indcoord.x + ((bias & 1u) != 0u ? -128 : 0);\n" " indcoord.y = indcoord.y + ((bias & 2u) != 0u ? -128 : 0);\n" " indcoord.z = indcoord.z + ((bias & 4u) != 0u ? -128 : 0);\n" " s.AlphaBump = s.AlphaBump & 0xf8;\n" " break;\n" " case {:s}:\n", IndTexFormat::ITF_5); out.Write(" indcoord.x = (indcoord.x >> 3) + ((bias & 1u) != 0u ? 1 : 0);\n" " indcoord.y = (indcoord.y >> 3) + ((bias & 2u) != 0u ? 1 : 0);\n" " indcoord.z = (indcoord.z >> 3) + ((bias & 4u) != 0u ? 1 : 0);\n" " s.AlphaBump = s.AlphaBump << 5;\n" " break;\n" " case {:s}:\n", IndTexFormat::ITF_4); out.Write(" indcoord.x = (indcoord.x >> 4) + ((bias & 1u) != 0u ? 1 : 0);\n" " indcoord.y = (indcoord.y >> 4) + ((bias & 2u) != 0u ? 1 : 0);\n" " indcoord.z = (indcoord.z >> 4) + ((bias & 4u) != 0u ? 1 : 0);\n" " s.AlphaBump = s.AlphaBump << 4;\n" " break;\n" " case {:s}:\n", IndTexFormat::ITF_3); out.Write(" indcoord.x = (indcoord.x >> 5) + ((bias & 1u) != 0u ? 1 : 0);\n" " indcoord.y = (indcoord.y >> 5) + ((bias & 2u) != 0u ? 1 : 0);\n" " indcoord.z = (indcoord.z >> 5) + ((bias & 4u) != 0u ? 1 : 0);\n" " s.AlphaBump = s.AlphaBump << 3;\n" " break;\n" " }}\n" "\n" " // Matrix multiply\n" " if (matrix_index != 0u)\n" " {{\n" " uint mtxidx = 2u * (matrix_index - 1u);\n" " int shift = " I_INDTEXMTX "[mtxidx].w;\n" "\n" " switch (matrix_id)\n" " {{\n" " case 0u: // 3x2 S0.10 matrix\n" " indtevtrans = int2(idot(" I_INDTEXMTX "[mtxidx].xyz, indcoord), idot(" I_INDTEXMTX "[mtxidx + 1u].xyz, indcoord)) >> 3;\n" " break;\n" " case 1u: // S matrix, S17.7 format\n" " indtevtrans = (fixedPoint_uv * indcoord.xx) >> 8;\n" " break;\n" " case 2u: // T matrix, S17.7 format\n" " indtevtrans = (fixedPoint_uv * indcoord.yy) >> 8;\n" " break;\n" " }}\n" "\n" " if (shift >= 0)\n" " indtevtrans = indtevtrans >> shift;\n" " else\n" " indtevtrans = indtevtrans << ((-shift) & 31);\n" " }}\n" " }}\n" "\n" " // Wrapping\n" " uint sw = {};\n", BitfieldExtract<&TevStageIndirect::sw>("tevind")); out.Write(" uint tw = {}; \n", BitfieldExtract<&TevStageIndirect::tw>("tevind")); out.Write( " int2 wrapped_coord = int2(Wrap(fixedPoint_uv.x, sw), Wrap(fixedPoint_uv.y, tw));\n" "\n" " if ((tevind & {}u) != 0u) // add previous tevcoord\n", 1 << TevStageIndirect().fb_addprev.StartBit()); out.Write(" tevcoord.xy += wrapped_coord + indtevtrans;\n" " else\n" " tevcoord.xy = wrapped_coord + indtevtrans;\n" "\n" " // Emulate s24 overflows\n" " tevcoord.xy = (tevcoord.xy << 8) >> 8;\n" " }}\n" " else\n" " {{\n" " tevcoord.xy = fixedPoint_uv;\n" " }}\n" "\n" " // Sample texture for stage\n" " if (texture_enabled) {{\n" " uint sampler_num = {};\n", BitfieldExtract<&TwoTevStageOrders::texmap_even>("ss.order")); out.Write("\n" " int4 color = sampleTextureWrapper(sampler_num, tevcoord.xy, layer);\n" " uint swap = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::tswap>("ss.ac")); out.Write(" s.TexColor = Swizzle(swap, color);\n"); out.Write(" }} else {{\n" " // Texture is disabled\n" " s.TexColor = int4(255, 255, 255, 255);\n" " }}\n" "\n"); } out.Write(" // This is the Meat of TEV\n" " {{\n" " // Color Combiner\n"); out.Write(" uint color_a = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::a>("ss.cc")); out.Write(" uint color_b = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::b>("ss.cc")); out.Write(" uint color_c = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::c>("ss.cc")); out.Write(" uint color_d = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::d>("ss.cc")); out.Write(" uint color_bias = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::bias>("ss.cc")); out.Write(" bool color_op = bool({});\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::op>("ss.cc")); out.Write(" bool color_clamp = bool({});\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::clamp>("ss.cc")); out.Write(" uint color_scale = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::scale>("ss.cc")); out.Write(" uint color_dest = {};\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::dest>("ss.cc")); out.Write( " uint color_compare_op = color_scale << 1 | uint(color_op);\n" "\n" " int3 color_A = selectColorInput(s, ss, {0}colors_0, {0}colors_1, color_a) & " "int3(255, 255, 255);\n" " int3 color_B = selectColorInput(s, ss, {0}colors_0, {0}colors_1, color_b) & " "int3(255, 255, 255);\n" " int3 color_C = selectColorInput(s, ss, {0}colors_0, {0}colors_1, color_c) & " "int3(255, 255, 255);\n" " int3 color_D = selectColorInput(s, ss, {0}colors_0, {0}colors_1, color_d); // 10 " "bits + sign\n" "\n", // TODO: do we need to sign extend? color_input_prefix); out.Write( " int3 color;\n" " if (color_bias != 3u) {{ // Normal mode\n" " color = tevLerp3(color_A, color_B, color_C, color_D, color_bias, color_op, " "color_scale);\n" " }} else {{ // Compare mode\n" " // op 6 and 7 do a select per color channel\n" " if (color_compare_op == 6u) {{\n" " // TevCompareMode::RGB8, TevComparison::GT\n" " color.r = (color_A.r > color_B.r) ? color_C.r : 0;\n" " color.g = (color_A.g > color_B.g) ? color_C.g : 0;\n" " color.b = (color_A.b > color_B.b) ? color_C.b : 0;\n" " }} else if (color_compare_op == 7u) {{\n" " // TevCompareMode::RGB8, TevComparison::EQ\n" " color.r = (color_A.r == color_B.r) ? color_C.r : 0;\n" " color.g = (color_A.g == color_B.g) ? color_C.g : 0;\n" " color.b = (color_A.b == color_B.b) ? color_C.b : 0;\n" " }} else {{\n" " // The remaining ops do one compare which selects all 3 channels\n" " color = tevCompare(color_compare_op, color_A, color_B) ? color_C : int3(0, 0, " "0);\n" " }}\n" " color = color_D + color;\n" " }}\n" "\n" " // Clamp result\n" " if (color_clamp)\n" " color = clamp(color, 0, 255);\n" " else\n" " color = clamp(color, -1024, 1023);\n" "\n" " // Write result to the correct input register of the next stage\n"); WriteSwitch(out, api_type, "color_dest", tev_c_set_table, 6, true); out.Write("\n"); // Alpha combiner out.Write(" // Alpha Combiner\n"); out.Write(" uint alpha_a = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::a>("ss.ac")); out.Write(" uint alpha_b = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::b>("ss.ac")); out.Write(" uint alpha_c = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::c>("ss.ac")); out.Write(" uint alpha_d = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::d>("ss.ac")); out.Write(" uint alpha_bias = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::bias>("ss.ac")); out.Write(" bool alpha_op = bool({});\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::op>("ss.ac")); out.Write(" bool alpha_clamp = bool({});\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::clamp>("ss.ac")); out.Write(" uint alpha_scale = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::scale>("ss.ac")); out.Write(" uint alpha_dest = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::dest>("ss.ac")); out.Write( " uint alpha_compare_op = alpha_scale << 1 | uint(alpha_op);\n" "\n" " int alpha_A = 0;\n" " int alpha_B = 0;\n" " if (alpha_bias != 3u || alpha_compare_op > 5u) {{\n" " // Small optimisation here: alpha_A and alpha_B are unused by compare ops 0-5\n" " alpha_A = selectAlphaInput(s, ss, {0}colors_0, {0}colors_1, alpha_a) & 255;\n" " alpha_B = selectAlphaInput(s, ss, {0}colors_0, {0}colors_1, alpha_b) & 255;\n" " }};\n" " int alpha_C = selectAlphaInput(s, ss, {0}colors_0, {0}colors_1, alpha_c) & 255;\n" " int alpha_D = selectAlphaInput(s, ss, {0}colors_0, {0}colors_1, alpha_d); // 10 " "bits " "+ sign\n" "\n", // TODO: do we need to sign extend? color_input_prefix); out.Write("\n" " int alpha;\n" " if (alpha_bias != 3u) {{ // Normal mode\n" " alpha = tevLerp(alpha_A, alpha_B, alpha_C, alpha_D, alpha_bias, alpha_op, " "alpha_scale);\n" " }} else {{ // Compare mode\n" " if (alpha_compare_op == 6u) {{\n" " // TevCompareMode::A8, TevComparison::GT\n" " alpha = (alpha_A > alpha_B) ? alpha_C : 0;\n" " }} else if (alpha_compare_op == 7u) {{\n" " // TevCompareMode::A8, TevComparison::EQ\n" " alpha = (alpha_A == alpha_B) ? alpha_C : 0;\n" " }} else {{\n" " // All remaining alpha compare ops actually compare the color channels\n" " alpha = tevCompare(alpha_compare_op, color_A, color_B) ? alpha_C : 0;\n" " }}\n" " alpha = alpha_D + alpha;\n" " }}\n" "\n" " // Clamp result\n" " if (alpha_clamp)\n" " alpha = clamp(alpha, 0, 255);\n" " else\n" " alpha = clamp(alpha, -1024, 1023);\n" "\n" " // Write result to the correct input register of the next stage\n"); WriteSwitch(out, api_type, "alpha_dest", tev_a_set_table, 6, true); if (has_custom_shader_details) { for (u32 stage_index = 0; stage_index < 16; stage_index++) { out.Write("\tif (stage == {}u) {{\n", stage_index); // Color input out.Write("\t\tcustom_data.tev_stages[{}].input_color[0].value = color_A / float3(255.0, " "255.0, 255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[0].input_type = " "getColorInputType(color_a);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[1].value = color_B / float3(255.0, " "255.0, 255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[1].input_type = " "getColorInputType(color_b);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[2].value = color_C / float3(255.0, " "255.0, 255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[2].input_type = " "getColorInputType(color_c);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[3].value = color_D / float3(255.0, " "255.0, 255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_color[3].input_type = " "getColorInputType(color_c);\n", stage_index); // Alpha input out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[0].value = alpha_A / float(255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[0].input_type = " "getAlphaInputType(alpha_a);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[1].value = alpha_B / float(255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[1].input_type = " "getAlphaInputType(alpha_b);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[2].value = alpha_C / float(255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[2].input_type = " "getAlphaInputType(alpha_c);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[3].value = alpha_D / float(255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].input_alpha[3].input_type = " "getAlphaInputType(alpha_d);\n", stage_index); if (numTexgen != 0) { // Texmap out.Write("\t\tif (texture_enabled) {{\n"); out.Write("\t\t\tuint sampler_num = {};\n", BitfieldExtract<&TwoTevStageOrders::texmap_even>("ss.order")); out.Write("\t\tcustom_data.tev_stages[{}].texmap = sampler_num;\n", stage_index); out.Write("\t\t}}\n"); } // Output out.Write("\t\tcustom_data.tev_stages[{}].output_color.rgb = color / float3(255.0, 255.0, " "255.0);\n", stage_index); out.Write("\t\tcustom_data.tev_stages[{}].output_color.a = alpha / float(255.0);\n", stage_index); out.Write("\t}}\n"); } } out.Write(" }}\n"); out.Write(" }} // Main TEV loop\n"); out.Write("\n"); // Select the output color and alpha registers from the last stage. out.Write(" int4 TevResult;\n"); out.Write( " TevResult.xyz = getTevReg(s, {}).xyz;\n", BitfieldExtract<&TevStageCombiner::ColorCombiner::dest>("bpmem_combiners(num_stages).x")); out.Write( " TevResult.w = getTevReg(s, {}).w;\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::dest>("bpmem_combiners(num_stages).y")); out.Write(" TevResult &= 255;\n\n"); if (host_config.fast_depth_calc) { if (!host_config.backend_reversed_depth_range) out.Write(" int zCoord = int((1.0 - rawpos.z) * 16777216.0);\n"); else out.Write(" int zCoord = int(rawpos.z * 16777216.0);\n"); out.Write(" zCoord = clamp(zCoord, 0, 0xFFFFFF);\n" "\n"); } else { out.Write("\tint zCoord = " I_ZBIAS "[1].x + int((clipPos.z / clipPos.w) * float(" I_ZBIAS "[1].y));\n"); } // =========== // ZFreeze // =========== if (per_pixel_depth) { // Zfreeze forces early depth off out.Write(" // ZFreeze\n" " if ((bpmem_genmode & {}u) != 0u) {{\n", 1 << GenMode().zfreeze.StartBit()); out.Write(" float2 screenpos = rawpos.xy * " I_EFBSCALE ".xy;\n"); if (api_type == APIType::OpenGL) { out.Write(" // OpenGL has reversed vertical screenspace coordinates\n" " screenpos.y = 528.0 - screenpos.y;\n"); } out.Write(" zCoord = int(" I_ZSLOPE ".z + " I_ZSLOPE ".x * screenpos.x + " I_ZSLOPE ".y * screenpos.y);\n" " }}\n" "\n"); } // ================= // Depth Texture // ================= out.Write(" // Depth Texture\n" " int early_zCoord = zCoord;\n" " if (bpmem_ztex_op != 0u) {{\n" " int ztex = int(" I_ZBIAS "[1].w); // fixed bias\n" "\n" " // Whatever texture was in our last stage, it's now our depth texture\n" " ztex += idot(s.TexColor.xyzw, " I_ZBIAS "[0].xyzw);\n" " ztex += (bpmem_ztex_op == 1u) ? zCoord : 0;\n" " zCoord = ztex & 0xFFFFFF;\n" " }}\n" "\n"); if (per_pixel_depth) { out.Write(" // If early depth is enabled, write to zbuffer before depth textures\n" " // If early depth isn't enabled, we write to the zbuffer here\n" " int zbuffer_zCoord = bpmem_late_ztest ? zCoord : early_zCoord;\n"); if (!host_config.backend_reversed_depth_range) out.Write(" depth = 1.0 - float(zbuffer_zCoord) / 16777216.0;\n"); else out.Write(" depth = float(zbuffer_zCoord) / 16777216.0;\n"); } out.Write(" // Alpha Test\n"); if (early_depth && DriverDetails::HasBug(DriverDetails::BUG_BROKEN_DISCARD_WITH_EARLY_Z)) { // Instead of using discard, fetch the framebuffer's color value and use it as the output // for this fragment. out.Write(" #define discard_fragment {{ real_ocol0 = float4(initial_ocol0.xyz, 1.0); " "return; }}\n"); } else { out.Write(" #define discard_fragment discard\n"); } out.Write(" if (bpmem_alphaTest != 0u) {{\n" " bool comp0 = alphaCompare(TevResult.a, " I_ALPHA ".r, {});\n", BitfieldExtract<&AlphaTest::comp0>("bpmem_alphaTest")); out.Write(" bool comp1 = alphaCompare(TevResult.a, " I_ALPHA ".g, {});\n", BitfieldExtract<&AlphaTest::comp1>("bpmem_alphaTest")); out.Write("\n" " // These if statements are written weirdly to work around intel and Qualcomm " "bugs with handling booleans.\n" " switch ({}) {{\n", BitfieldExtract<&AlphaTest::logic>("bpmem_alphaTest")); out.Write(" case 0u: // AND\n" " if (comp0 && comp1) break; else discard_fragment; break;\n" " case 1u: // OR\n" " if (comp0 || comp1) break; else discard_fragment; break;\n" " case 2u: // XOR\n" " if (comp0 != comp1) break; else discard_fragment; break;\n" " case 3u: // XNOR\n" " if (comp0 == comp1) break; else discard_fragment; break;\n" " }}\n" " }}\n" "\n"); out.Write(" // Hardware testing indicates that an alpha of 1 can pass an alpha test,\n" " // but doesn't do anything in blending\n" " if (TevResult.a == 1) TevResult.a = 0;\n"); // ========= // Dithering // ========= out.Write(" if (bpmem_dither) {{\n" " // Flipper uses a standard 2x2 Bayer Matrix for 6 bit dithering\n" " // Here the matrix is encoded into the two factor constants\n" " int2 dither = int2(rawpos.xy) & 1;\n" " TevResult.rgb = (TevResult.rgb - (TevResult.rgb >> 6)) + abs(dither.y * 3 - " "dither.x * 2);\n" " }}\n\n"); // ========= // Fog // ========= // FIXME: Fog is implemented the same as ShaderGen, but ShaderGen's fog is all hacks. // Should be fixed point, and should not make guesses about Range-Based adjustments. out.Write(" // Fog\n" " uint fog_function = {};\n", BitfieldExtract<&FogParam3::fsel>("bpmem_fogParam3")); out.Write(" if (fog_function != {:s}) {{\n", FogType::Off); out.Write(" // TODO: This all needs to be converted from float to fixed point\n" " float ze;\n" " if ({} == 0u) {{\n", BitfieldExtract<&FogParam3::proj>("bpmem_fogParam3")); out.Write(" // perspective\n" " // ze = A/(B - (Zs >> B_SHF)\n" " ze = (" I_FOGF ".x * 16777216.0) / float(" I_FOGI ".y - (zCoord >> " I_FOGI ".w));\n" " }} else {{\n" " // orthographic\n" " // ze = a*Zs (here, no B_SHF)\n" " ze = " I_FOGF ".x * float(zCoord) / 16777216.0;\n" " }}\n" "\n" " if (bool({})) {{\n", BitfieldExtract<&FogRangeParams::RangeBase::Enabled>("bpmem_fogRangeBase")); out.Write(" // x_adjust = sqrt((x-center)^2 + k^2)/k\n" " // ze *= x_adjust\n" " float offset = (2.0 * (rawpos.x / " I_FOGF ".w)) - 1.0 - " I_FOGF ".z;\n" " float floatindex = clamp(9.0 - abs(offset) * 9.0, 0.0, 9.0);\n" " uint indexlower = uint(floatindex);\n" " uint indexupper = indexlower + 1u;\n" " float klower = " I_FOGRANGE "[indexlower >> 2u][indexlower & 3u];\n" " float kupper = " I_FOGRANGE "[indexupper >> 2u][indexupper & 3u];\n" " float k = lerp(klower, kupper, frac(floatindex));\n" " float x_adjust = sqrt(offset * offset + k * k) / k;\n" " ze *= x_adjust;\n" " }}\n" "\n" " float fog = clamp(ze - " I_FOGF ".y, 0.0, 1.0);\n" "\n"); out.Write(" if (fog_function >= {:s}) {{\n", FogType::Exp); out.Write(" switch (fog_function) {{\n" " case {:s}:\n" " fog = 1.0 - exp2(-8.0 * fog);\n" " break;\n", FogType::Exp); out.Write(" case {:s}:\n" " fog = 1.0 - exp2(-8.0 * fog * fog);\n" " break;\n", FogType::ExpSq); out.Write(" case {:s}:\n" " fog = exp2(-8.0 * (1.0 - fog));\n" " break;\n", FogType::BackwardsExp); out.Write(" case {:s}:\n" " fog = 1.0 - fog;\n" " fog = exp2(-8.0 * fog * fog);\n" " break;\n", FogType::BackwardsExpSq); out.Write(" }}\n" " }}\n" "\n" " int ifog = iround(fog * 256.0);\n" " TevResult.rgb = (TevResult.rgb * (256 - ifog) + " I_FOGCOLOR ".rgb * ifog) >> 8;\n" " }}\n" "\n"); for (std::size_t i = 0; i < custom_details.shaders.size(); i++) { const auto& shader_details = custom_details.shaders[i]; if (!shader_details.custom_shader.empty()) { out.Write("\t{{\n"); out.Write("\t\tcustom_data.final_color = float4(TevResult.r / 255.0, TevResult.g / 255.0, " "TevResult.b / 255.0, TevResult.a / 255.0);\n"); out.Write("\t\tCustomShaderOutput custom_output = {}_{}(custom_data);\n", CUSTOM_PIXELSHADER_COLOR_FUNC, i); out.Write( "\t\tTevResult = int4(custom_output.main_rt.r * 255, custom_output.main_rt.g * 255, " "custom_output.main_rt.b * 255, custom_output.main_rt.a * 255);\n"); out.Write("\t}}\n\n"); } } if (use_framebuffer_fetch) { static constexpr std::array logic_op_mode{ "int4(0, 0, 0, 0)", // CLEAR "TevResult & fb_value", // AND "TevResult & ~fb_value", // AND_REVERSE "TevResult", // COPY "~TevResult & fb_value", // AND_INVERTED "fb_value", // NOOP "TevResult ^ fb_value", // XOR "TevResult | fb_value", // OR "~(TevResult | fb_value)", // NOR "~(TevResult ^ fb_value)", // EQUIV "~fb_value", // INVERT "TevResult | ~fb_value", // OR_REVERSE "~TevResult", // COPY_INVERTED "~TevResult | fb_value", // OR_INVERTED "~(TevResult & fb_value)", // NAND "int4(255, 255, 255, 255)", // SET }; out.Write(" // Logic Ops\n" " if (logic_op_enable) {{\n" " int4 fb_value = iround(initial_ocol0 * 255.0);" " switch (logic_op_mode) {{\n"); for (size_t i = 0; i < logic_op_mode.size(); i++) { out.Write(" case {}u: TevResult = {}; break;\n", i, logic_op_mode[i]); } out.Write(" }}\n" " TevResult &= 0xff;\n" " }}\n"); } else if (!host_config.backend_logic_op) { out.Write(" // Helpers for logic op blending approximations\n" " if (logic_op_enable) {{\n" " switch (logic_op_mode) {{\n"); out.Write(" case {}: // Clear\n", static_cast(LogicOp::Clear)); out.Write(" TevResult = int4(0, 0, 0, 0);\n" " break;\n"); out.Write(" case {}: // Copy Inverted\n", static_cast(LogicOp::CopyInverted)); out.Write(" TevResult ^= 0xff;\n" " break;\n"); out.Write(" case {}: // Set\n", static_cast(LogicOp::Set)); out.Write(" case {}: // Invert\n", static_cast(LogicOp::Invert)); out.Write(" TevResult = int4(255, 255, 255, 255);\n" " break;\n"); out.Write(" default:\n" " break;\n" " }}\n" " }}\n"); } // Some backends require that the shader outputs be uint when writing to a uint render target // for logic op. if (uid_data->uint_output) { out.Write(" if (bpmem_rgba6_format)\n" " ocol0 = uint4(TevResult & 0xFC);\n" " else\n" " ocol0 = uint4(TevResult);\n" "\n"); } else { out.Write(" if (bpmem_rgba6_format)\n" " ocol0.rgb = float3(TevResult.rgb >> 2) / 63.0;\n" " else\n" " ocol0.rgb = float3(TevResult.rgb) / 255.0;\n" "\n" " if (bpmem_dstalpha != 0u)\n"); out.Write(" ocol0.a = float({} >> 2) / 63.0;\n", BitfieldExtract<&ConstantAlpha::alpha>("bpmem_dstalpha")); out.Write(" else\n" " ocol0.a = float(TevResult.a >> 2) / 63.0;\n" " \n"); if (use_dual_source || use_framebuffer_fetch) { out.Write(" // Dest alpha override (dual source blending)\n" " // Colors will be blended against the alpha from ocol1 and\n" " // the alpha from ocol0 will be written to the framebuffer.\n" " ocol1 = float4(0.0, 0.0, 0.0, float(TevResult.a) / 255.0);\n"); } } if (bounding_box) { out.Write(" if (bpmem_bounding_box) {{\n" " UpdateBoundingBox(rawpos.xy);\n" " }}\n"); } if (use_framebuffer_fetch) { using Common::EnumMap; static constexpr EnumMap blendSrcFactor{ "blend_src.rgb = float3(0,0,0);", // ZERO "blend_src.rgb = float3(1,1,1);", // ONE "blend_src.rgb = initial_ocol0.rgb;", // DSTCLR "blend_src.rgb = float3(1,1,1) - initial_ocol0.rgb;", // INVDSTCLR "blend_src.rgb = src_color.aaa;", // SRCALPHA "blend_src.rgb = float3(1,1,1) - src_color.aaa;", // INVSRCALPHA "blend_src.rgb = initial_ocol0.aaa;", // DSTALPHA "blend_src.rgb = float3(1,1,1) - initial_ocol0.aaa;", // INVDSTALPHA }; static constexpr EnumMap blendSrcFactorAlpha{ "blend_src.a = 0.0;", // ZERO "blend_src.a = 1.0;", // ONE "blend_src.a = initial_ocol0.a;", // DSTCLR "blend_src.a = 1.0 - initial_ocol0.a;", // INVDSTCLR "blend_src.a = src_color.a;", // SRCALPHA "blend_src.a = 1.0 - src_color.a;", // INVSRCALPHA "blend_src.a = initial_ocol0.a;", // DSTALPHA "blend_src.a = 1.0 - initial_ocol0.a;", // INVDSTALPHA }; static constexpr EnumMap blendDstFactor{ "blend_dst.rgb = float3(0,0,0);", // ZERO "blend_dst.rgb = float3(1,1,1);", // ONE "blend_dst.rgb = ocol0.rgb;", // SRCCLR "blend_dst.rgb = float3(1,1,1) - ocol0.rgb;", // INVSRCCLR "blend_dst.rgb = src_color.aaa;", // SRCALHA "blend_dst.rgb = float3(1,1,1) - src_color.aaa;", // INVSRCALPHA "blend_dst.rgb = initial_ocol0.aaa;", // DSTALPHA "blend_dst.rgb = float3(1,1,1) - initial_ocol0.aaa;", // INVDSTALPHA }; static constexpr EnumMap blendDstFactorAlpha{ "blend_dst.a = 0.0;", // ZERO "blend_dst.a = 1.0;", // ONE "blend_dst.a = ocol0.a;", // SRCCLR "blend_dst.a = 1.0 - ocol0.a;", // INVSRCCLR "blend_dst.a = src_color.a;", // SRCALPHA "blend_dst.a = 1.0 - src_color.a;", // INVSRCALPHA "blend_dst.a = initial_ocol0.a;", // DSTALPHA "blend_dst.a = 1.0 - initial_ocol0.a;", // INVDSTALPHA }; out.Write(" if (blend_enable) {{\n" " float4 src_color;\n" " if (bpmem_dstalpha != 0u) {{\n" " src_color = ocol1;\n" " }} else {{\n" " src_color = ocol0;\n" " }}" " float4 blend_src;\n"); WriteSwitch(out, api_type, "blend_src_factor", blendSrcFactor, 4, true); WriteSwitch(out, api_type, "blend_src_factor_alpha", blendSrcFactorAlpha, 4, true); out.Write(" float4 blend_dst;\n"); WriteSwitch(out, api_type, "blend_dst_factor", blendDstFactor, 4, true); WriteSwitch(out, api_type, "blend_dst_factor_alpha", blendDstFactorAlpha, 4, true); out.Write(" float4 blend_result;\n" " if (blend_subtract)\n" " blend_result.rgb = initial_ocol0.rgb * blend_dst.rgb - ocol0.rgb * " "blend_src.rgb;\n" " else\n" " blend_result.rgb = initial_ocol0.rgb * blend_dst.rgb + ocol0.rgb * " "blend_src.rgb;\n"); out.Write(" if (blend_subtract_alpha)\n" " blend_result.a = initial_ocol0.a * blend_dst.a - ocol0.a * blend_src.a;\n" " else\n" " blend_result.a = initial_ocol0.a * blend_dst.a + ocol0.a * blend_src.a;\n"); out.Write(" real_ocol0 = blend_result;\n"); out.Write(" }} else {{\n" " real_ocol0 = ocol0;\n" " }}\n"); } out.Write("}}\n" "\n" "int4 getRasColor(State s, StageState ss, float4 colors_0, float4 colors_1) {{\n" " // Select Ras for stage\n" " uint ras = {};\n", BitfieldExtract<&TwoTevStageOrders::colorchan_even>("ss.order")); out.Write(" if (ras < 2u) {{ // Lighting Channel 0 or 1\n" " int4 color = iround(((ras == 0u) ? colors_0 : colors_1) * 255.0);\n" " uint swap = {};\n", BitfieldExtract<&TevStageCombiner::AlphaCombiner::rswap>("ss.ac")); out.Write(" return Swizzle(swap, color);\n"); out.Write(" }} else if (ras == 5u) {{ // Alpha Bump\n" " return int4(s.AlphaBump, s.AlphaBump, s.AlphaBump, s.AlphaBump);\n" " }} else if (ras == 6u) {{ // Normalzied Alpha Bump\n" " int normalized = s.AlphaBump | s.AlphaBump >> 5;\n" " return int4(normalized, normalized, normalized, normalized);\n" " }} else {{\n" " return int4(0, 0, 0, 0);\n" " }}\n" "}}\n" "\n" "int4 getKonstColor(State s, StageState ss) {{\n" " // Select Konst for stage\n" " // TODO: a switch case might be better here than an dynamically" " // indexed uniform lookup\n" " uint tevksel = bpmem_tevksel(ss.stage>>1);\n" " if ((ss.stage & 1u) == 0u)\n" " return int4(konstLookup[{}].rgb, konstLookup[{}].a);\n", BitfieldExtract<&TevKSel::kcsel_even>("tevksel"), BitfieldExtract<&TevKSel::kasel_even>("tevksel")); out.Write(" else\n" " return int4(konstLookup[{}].rgb, konstLookup[{}].a);\n", BitfieldExtract<&TevKSel::kcsel_odd>("tevksel"), BitfieldExtract<&TevKSel::kasel_odd>("tevksel")); out.Write("}}\n"); return out; } void EnumeratePixelShaderUids(const std::function& callback) { PixelShaderUid uid; for (u32 texgens = 0; texgens <= 8; texgens++) { pixel_ubershader_uid_data* const puid = uid.GetUidData(); puid->num_texgens = texgens; for (u32 early_depth = 0; early_depth < 2; early_depth++) { puid->early_depth = early_depth != 0; for (u32 per_pixel_depth = 0; per_pixel_depth < 2; per_pixel_depth++) { // Don't generate shaders where we have early depth tests enabled, and write gl_FragDepth. if (early_depth && per_pixel_depth) continue; puid->per_pixel_depth = per_pixel_depth != 0; for (u32 uint_output = 0; uint_output < 2; uint_output++) { puid->uint_output = uint_output; for (u32 no_dual_src = 0; no_dual_src < 2; no_dual_src++) { puid->no_dual_src = no_dual_src; callback(uid); } } } } } } } // namespace UberShader