// Copyright (c) 2013- PPSSPP Project. // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, version 2.0 or later versions. // 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 2.0 for more details. // A copy of the GPL 2.0 should have been included with the program. // If not, see http://www.gnu.org/licenses/ // Official git repository and contact information can be found at // https://github.com/hrydgard/ppsspp and http://www.ppsspp.org/. #include #include #include "Common/Data/Convert/ColorConv.h" #include "Common/Profiler/Profiler.h" #include "Common/LogReporting.h" #include "Common/Math/lin/matrix4x4.h" #include "Core/Config.h" #include "GPU/Common/DrawEngineCommon.h" #include "GPU/Common/SplineCommon.h" #include "GPU/Common/VertexDecoderCommon.h" #include "GPU/ge_constants.h" #include "GPU/GPUState.h" #define QUAD_INDICES_MAX 65536 enum { TRANSFORMED_VERTEX_BUFFER_SIZE = VERTEX_BUFFER_MAX * sizeof(TransformedVertex) }; DrawEngineCommon::DrawEngineCommon() : decoderMap_(16) { if (g_Config.bVertexDecoderJit && (g_Config.iCpuCore == (int)CPUCore::JIT || g_Config.iCpuCore == (int)CPUCore::JIT_IR)) { decJitCache_ = new VertexDecoderJitCache(); } transformed_ = (TransformedVertex *)AllocateMemoryPages(TRANSFORMED_VERTEX_BUFFER_SIZE, MEM_PROT_READ | MEM_PROT_WRITE); transformedExpanded_ = (TransformedVertex *)AllocateMemoryPages(3 * TRANSFORMED_VERTEX_BUFFER_SIZE, MEM_PROT_READ | MEM_PROT_WRITE); decoded_ = (u8 *)AllocateMemoryPages(DECODED_VERTEX_BUFFER_SIZE, MEM_PROT_READ | MEM_PROT_WRITE); decIndex_ = (u16 *)AllocateMemoryPages(DECODED_INDEX_BUFFER_SIZE, MEM_PROT_READ | MEM_PROT_WRITE); } DrawEngineCommon::~DrawEngineCommon() { FreeMemoryPages(decoded_, DECODED_VERTEX_BUFFER_SIZE); FreeMemoryPages(decIndex_, DECODED_INDEX_BUFFER_SIZE); FreeMemoryPages(transformed_, TRANSFORMED_VERTEX_BUFFER_SIZE); FreeMemoryPages(transformedExpanded_, 3 * TRANSFORMED_VERTEX_BUFFER_SIZE); delete decJitCache_; decoderMap_.Iterate([&](const uint32_t vtype, VertexDecoder *decoder) { delete decoder; }); ClearSplineBezierWeights(); } void DrawEngineCommon::Init() { NotifyConfigChanged(); } VertexDecoder *DrawEngineCommon::GetVertexDecoder(u32 vtype) { VertexDecoder *dec; if (decoderMap_.Get(vtype, &dec)) return dec; dec = new VertexDecoder(); _assert_(dec); dec->SetVertexType(vtype, decOptions_, decJitCache_); decoderMap_.Insert(vtype, dec); return dec; } std::vector DrawEngineCommon::DebugGetVertexLoaderIDs() { std::vector ids; decoderMap_.Iterate([&](const uint32_t vtype, VertexDecoder *decoder) { std::string id; id.resize(sizeof(vtype)); memcpy(&id[0], &vtype, sizeof(vtype)); ids.push_back(id); }); return ids; } std::string DrawEngineCommon::DebugGetVertexLoaderString(std::string id, DebugShaderStringType stringType) { u32 mapId; memcpy(&mapId, &id[0], sizeof(mapId)); VertexDecoder *dec; if (decoderMap_.Get(mapId, &dec)) { return dec->GetString(stringType); } else { return "N/A"; } } static Vec3f ClipToScreen(const Vec4f& coords) { float xScale = gstate.getViewportXScale(); float xCenter = gstate.getViewportXCenter(); float yScale = gstate.getViewportYScale(); float yCenter = gstate.getViewportYCenter(); float zScale = gstate.getViewportZScale(); float zCenter = gstate.getViewportZCenter(); float x = coords.x * xScale / coords.w + xCenter; float y = coords.y * yScale / coords.w + yCenter; float z = coords.z * zScale / coords.w + zCenter; // 16 = 0xFFFF / 4095.9375 return Vec3f(x * 16 - gstate.getOffsetX16(), y * 16 - gstate.getOffsetY16(), z); } static Vec3f ScreenToDrawing(const Vec3f& coords) { Vec3f ret; ret.x = coords.x * (1.0f / 16.0f); ret.y = coords.y * (1.0f / 16.0f); ret.z = coords.z; return ret; } void DrawEngineCommon::NotifyConfigChanged() { if (decJitCache_) decJitCache_->Clear(); lastVType_ = -1; dec_ = nullptr; decoderMap_.Iterate([&](const uint32_t vtype, VertexDecoder *decoder) { delete decoder; }); decoderMap_.Clear(); ClearTrackedVertexArrays(); useHWTransform_ = g_Config.bHardwareTransform; useHWTessellation_ = UpdateUseHWTessellation(g_Config.bHardwareTessellation); decOptions_.applySkinInDecode = g_Config.bSoftwareSkinning; } u32 DrawEngineCommon::NormalizeVertices(u8 *outPtr, u8 *bufPtr, const u8 *inPtr, int lowerBound, int upperBound, u32 vertType, int *vertexSize) { const u32 vertTypeID = GetVertTypeID(vertType, gstate.getUVGenMode(), decOptions_.applySkinInDecode); VertexDecoder *dec = GetVertexDecoder(vertTypeID); if (vertexSize) *vertexSize = dec->VertexSize(); return DrawEngineCommon::NormalizeVertices(outPtr, bufPtr, inPtr, dec, lowerBound, upperBound, vertType); } void DrawEngineCommon::DispatchSubmitImm(GEPrimitiveType prim, TransformedVertex *buffer, int vertexCount, int cullMode, bool continuation) { // Instead of plumbing through properly (we'd need to inject these pretransformed vertices in the middle // of SoftwareTransform(), which would take a lot of refactoring), we'll cheat and just turn these into // through vertices. // Since the only known use is Thrillville and it only uses it to clear, we just use color and pos. struct ImmVertex { float uv[2]; uint32_t color; float xyz[3]; }; std::vector temp; temp.resize(vertexCount); uint32_t color1Used = 0; for (int i = 0; i < vertexCount; i++) { // Since we're sending through, scale back up to w/h. temp[i].uv[0] = buffer[i].u * gstate.getTextureWidth(0); temp[i].uv[1] = buffer[i].v * gstate.getTextureHeight(0); temp[i].color = buffer[i].color0_32; temp[i].xyz[0] = buffer[i].pos[0]; temp[i].xyz[1] = buffer[i].pos[1]; temp[i].xyz[2] = buffer[i].pos[2]; color1Used |= buffer[i].color1_32; } int vtype = GE_VTYPE_TC_FLOAT | GE_VTYPE_POS_FLOAT | GE_VTYPE_COL_8888 | GE_VTYPE_THROUGH; // TODO: Handle fog and secondary color somehow? if (gstate.isFogEnabled() && !gstate.isModeThrough()) { WARN_LOG_REPORT_ONCE(geimmfog, G3D, "Imm vertex used fog"); } if (color1Used != 0 && gstate.isUsingSecondaryColor() && !gstate.isModeThrough()) { WARN_LOG_REPORT_ONCE(geimmcolor1, G3D, "Imm vertex used secondary color"); } bool prevThrough = gstate.isModeThrough(); // Code checks this reg directly, not just the vtype ID. if (!prevThrough) { gstate.vertType |= GE_VTYPE_THROUGH; gstate_c.Dirty(DIRTY_VERTEXSHADER_STATE | DIRTY_FRAGMENTSHADER_STATE | DIRTY_RASTER_STATE | DIRTY_VIEWPORTSCISSOR_STATE | DIRTY_CULLRANGE); } int bytesRead; uint32_t vertTypeID = GetVertTypeID(vtype, 0, decOptions_.applySkinInDecode); bool clockwise = !gstate.isCullEnabled() || gstate.getCullMode() == cullMode; SubmitPrim(&temp[0], nullptr, prim, vertexCount, vertTypeID, clockwise, &bytesRead); DispatchFlush(); if (!prevThrough) { gstate.vertType &= ~GE_VTYPE_THROUGH; gstate_c.Dirty(DIRTY_VERTEXSHADER_STATE | DIRTY_FRAGMENTSHADER_STATE | DIRTY_RASTER_STATE | DIRTY_VIEWPORTSCISSOR_STATE | DIRTY_CULLRANGE); } } // Gated by DIRTY_CULL_PLANES void DrawEngineCommon::UpdatePlanes() { float world[16]; float view[16]; float worldview[16]; float worldviewproj[16]; ConvertMatrix4x3To4x4(world, gstate.worldMatrix); ConvertMatrix4x3To4x4(view, gstate.viewMatrix); // TODO: Create a Matrix4x3ByMatrix4x3, and Matrix4x4ByMatrix4x3? Matrix4ByMatrix4(worldview, world, view); Matrix4ByMatrix4(worldviewproj, worldview, gstate.projMatrix); // Next, we need to apply viewport, scissor, region, and even offset - but only for X/Y. // Note that the PSP does not clip against the viewport. const Vec2f baseOffset = Vec2f(gstate.getOffsetX(), gstate.getOffsetY()); // Region1 (rate) is used as an X1/Y1 here, matching PSP behavior. minOffset_ = baseOffset + Vec2f(std::max(gstate.getRegionRateX() - 0x100, gstate.getScissorX1()), std::max(gstate.getRegionRateY() - 0x100, gstate.getScissorY1())) - Vec2f(1.0f, 1.0f); maxOffset_ = baseOffset + Vec2f(std::min(gstate.getRegionX2(), gstate.getScissorX2()), std::min(gstate.getRegionY2(), gstate.getScissorY2())) + Vec2f(1.0f, 1.0f); // Now let's apply the viewport to our scissor/region + offset range. Vec2f inverseViewportScale = Vec2f(1.0f / gstate.getViewportXScale(), 1.0f / gstate.getViewportYScale()); Vec2f minViewport = (minOffset_ - Vec2f(gstate.getViewportXCenter(), gstate.getViewportYCenter())) * inverseViewportScale; Vec2f maxViewport = (maxOffset_ - Vec2f(gstate.getViewportXCenter(), gstate.getViewportYCenter())) * inverseViewportScale; Vec2f viewportInvSize = Vec2f(1.0f / (maxViewport.x - minViewport.x), 1.0f / (maxViewport.y - minViewport.y)); Lin::Matrix4x4 applyViewport{}; // Scale to the viewport's size. applyViewport.xx = 2.0f * viewportInvSize.x; applyViewport.yy = 2.0f * viewportInvSize.y; applyViewport.zz = 1.0f; applyViewport.ww = 1.0f; // And offset to the viewport's centers. applyViewport.wx = -(maxViewport.x + minViewport.x) * viewportInvSize.x; applyViewport.wy = -(maxViewport.y + minViewport.y) * viewportInvSize.y; float mtx[16]; Matrix4ByMatrix4(mtx, worldviewproj, applyViewport.m); planes_[0].Set(mtx[3] - mtx[0], mtx[7] - mtx[4], mtx[11] - mtx[8], mtx[15] - mtx[12]); // Right planes_[1].Set(mtx[3] + mtx[0], mtx[7] + mtx[4], mtx[11] + mtx[8], mtx[15] + mtx[12]); // Left planes_[2].Set(mtx[3] + mtx[1], mtx[7] + mtx[5], mtx[11] + mtx[9], mtx[15] + mtx[13]); // Bottom planes_[3].Set(mtx[3] - mtx[1], mtx[7] - mtx[5], mtx[11] - mtx[9], mtx[15] - mtx[13]); // Top planes_[4].Set(mtx[3] + mtx[2], mtx[7] + mtx[6], mtx[11] + mtx[10], mtx[15] + mtx[14]); // Near planes_[5].Set(mtx[3] - mtx[2], mtx[7] - mtx[6], mtx[11] - mtx[10], mtx[15] - mtx[14]); // Far } // This code has plenty of potential for optimization. // // It does the simplest and safest test possible: If all points of a bbox is outside a single of // our clipping planes, we reject the box. Tighter bounds would be desirable but would take more calculations. // The name is a slight misnomer, because any bounding shape will work, not just boxes. // // Potential optimizations: // * SIMD-ify the plane culling, and also the vertex data conversion (could even group together xxxxyyyyzzzz for example) // * Compute min/max of the verts, and then compute a bounding sphere and check that against the planes. // - Less accurate, but.. // - Only requires six plane evaluations then. bool DrawEngineCommon::TestBoundingBox(const void *vdata, const void *inds, int vertexCount, u32 vertType) { // Grab temp buffer space from large offsets in decoded_. Not exactly safe for large draws. if (vertexCount > 1024) { return true; } SimpleVertex *corners = (SimpleVertex *)(decoded_ + 65536 * 12); float *verts = (float *)(decoded_ + 65536 * 18); int vertStride = 3; // Although this may lead to drawing that shouldn't happen, the viewport is more complex on VR. // Let's always say objects are within bounds. if (gstate_c.Use(GPU_USE_VIRTUAL_REALITY)) return true; // Due to world matrix updates per "thing", this isn't quite as effective as it could be if we did world transform // in here as well. Though, it still does cut down on a lot of updates in Tekken 6. if (gstate_c.IsDirty(DIRTY_CULL_PLANES)) { UpdatePlanes(); gpuStats.numPlaneUpdates++; gstate_c.Clean(DIRTY_CULL_PLANES); } // Try to skip NormalizeVertices if it's pure positions. No need to bother with a vertex decoder // and a large vertex format. if ((vertType & 0xFFFFFF) == GE_VTYPE_POS_FLOAT && !inds) { verts = (float *)vdata; } else if ((vertType & 0xFFFFFF) == GE_VTYPE_POS_8BIT && !inds) { const s8 *vtx = (const s8 *)vdata; for (int i = 0; i < vertexCount * 3; i++) { verts[i] = vtx[i] * (1.0f / 128.0f); } } else if ((vertType & 0xFFFFFF) == GE_VTYPE_POS_16BIT && !inds) { const s16 *vtx = (const s16 *)vdata; for (int i = 0; i < vertexCount * 3; i++) { verts[i] = vtx[i] * (1.0f / 32768.0f); } } else { // Simplify away indices, bones, and morph before proceeding. u8 *temp_buffer = decoded_ + 65536 * 24; if ((inds || (vertType & (GE_VTYPE_WEIGHT_MASK | GE_VTYPE_MORPHCOUNT_MASK)))) { u16 indexLowerBound = 0; u16 indexUpperBound = (u16)vertexCount - 1; if (vertexCount > 0 && inds) { GetIndexBounds(inds, vertexCount, vertType, &indexLowerBound, &indexUpperBound); } // TODO: Avoid normalization if just plain skinning. // Force software skinning. bool wasApplyingSkinInDecode = decOptions_.applySkinInDecode; decOptions_.applySkinInDecode = true; NormalizeVertices((u8 *)corners, temp_buffer, (const u8 *)vdata, indexLowerBound, indexUpperBound, vertType); decOptions_.applySkinInDecode = wasApplyingSkinInDecode; IndexConverter conv(vertType, inds); for (int i = 0; i < vertexCount; i++) { verts[i * 3] = corners[conv(i)].pos.x; verts[i * 3 + 1] = corners[conv(i)].pos.y; verts[i * 3 + 2] = corners[conv(i)].pos.z; } } else { // Simple, most common case. VertexDecoder *dec = GetVertexDecoder(vertType); int stride = dec->VertexSize(); int offset = dec->posoff; switch (vertType & GE_VTYPE_POS_MASK) { case GE_VTYPE_POS_8BIT: for (int i = 0; i < vertexCount; i++) { const s8 *data = (const s8 *)vdata + i * stride + offset; for (int j = 0; j < 3; j++) { verts[i * 3 + j] = data[j] * (1.0f / 128.0f); } } break; case GE_VTYPE_POS_16BIT: for (int i = 0; i < vertexCount; i++) { const s16 *data = ((const s16 *)((const s8 *)vdata + i * stride + offset)); for (int j = 0; j < 3; j++) { verts[i * 3 + j] = data[j] * (1.0f / 32768.0f); } } break; case GE_VTYPE_POS_FLOAT: // No need to copy in this case, we can just read directly from the source format with a stride. verts = (float *)((uint8_t *)vdata + offset); vertStride = stride / 4; // Previous code: // for (int i = 0; i < vertexCount; i++) // memcpy(&verts[i * 3], (const u8 *)vdata + stride * i + offset, sizeof(float) * 3); break; } } } // Note: near/far are not checked without clamp/clip enabled, so we skip those planes. int totalPlanes = gstate.isDepthClampEnabled() ? 6 : 4; for (int plane = 0; plane < totalPlanes; plane++) { int inside = 0; int out = 0; for (int i = 0; i < vertexCount; i++) { // Test against the frustum planes, and count. // TODO: We should test 4 vertices at a time using SIMD. // I guess could also test one vertex against 4 planes at a time, though a lot of waste at the common case of 6. const float *pos = verts + i * vertStride; float value = planes_[plane].Test(pos); if (value <= -FLT_EPSILON) // Not sure why we use exactly this value. Probably '< 0' would do. out++; else inside++; } // No vertices inside this one plane? Don't need to draw. if (inside == 0) { // All out - but check for X and Y if the offset was near the cullbox edge. bool outsideEdge = false; switch (plane) { case 0: outsideEdge = maxOffset_.x >= 4096.0f; break; case 1: outsideEdge = minOffset_.x < 1.0f; break; case 2: outsideEdge = minOffset_.y < 1.0f; break; case 3: outsideEdge = maxOffset_.y >= 4096.0f; break; } // Only consider this outside if offset + scissor/region is fully inside the cullbox. if (!outsideEdge) return false; } // Any out. For testing that the planes are in the right locations. // if (out != 0) return false; } return true; } // TODO: This probably is not the best interface. bool DrawEngineCommon::GetCurrentSimpleVertices(int count, std::vector &vertices, std::vector &indices) { // This is always for the current vertices. u16 indexLowerBound = 0; u16 indexUpperBound = count - 1; if (!Memory::IsValidAddress(gstate_c.vertexAddr) || count == 0) return false; bool savedVertexFullAlpha = gstate_c.vertexFullAlpha; if ((gstate.vertType & GE_VTYPE_IDX_MASK) != GE_VTYPE_IDX_NONE) { const u8 *inds = Memory::GetPointer(gstate_c.indexAddr); const u16_le *inds16 = (const u16_le *)inds; const u32_le *inds32 = (const u32_le *)inds; if (inds) { GetIndexBounds(inds, count, gstate.vertType, &indexLowerBound, &indexUpperBound); indices.resize(count); switch (gstate.vertType & GE_VTYPE_IDX_MASK) { case GE_VTYPE_IDX_8BIT: for (int i = 0; i < count; ++i) { indices[i] = inds[i]; } break; case GE_VTYPE_IDX_16BIT: for (int i = 0; i < count; ++i) { indices[i] = inds16[i]; } break; case GE_VTYPE_IDX_32BIT: WARN_LOG_REPORT_ONCE(simpleIndexes32, G3D, "SimpleVertices: Decoding 32-bit indexes"); for (int i = 0; i < count; ++i) { // These aren't documented and should be rare. Let's bounds check each one. if (inds32[i] != (u16)inds32[i]) { ERROR_LOG_REPORT_ONCE(simpleIndexes32Bounds, G3D, "SimpleVertices: Index outside 16-bit range"); } indices[i] = (u16)inds32[i]; } break; } } else { indices.clear(); } } else { indices.clear(); } static std::vector temp_buffer; static std::vector simpleVertices; temp_buffer.resize(std::max((int)indexUpperBound, 8192) * 128 / sizeof(u32)); simpleVertices.resize(indexUpperBound + 1); NormalizeVertices((u8 *)(&simpleVertices[0]), (u8 *)(&temp_buffer[0]), Memory::GetPointerUnchecked(gstate_c.vertexAddr), indexLowerBound, indexUpperBound, gstate.vertType); float world[16]; float view[16]; float worldview[16]; float worldviewproj[16]; ConvertMatrix4x3To4x4(world, gstate.worldMatrix); ConvertMatrix4x3To4x4(view, gstate.viewMatrix); Matrix4ByMatrix4(worldview, world, view); Matrix4ByMatrix4(worldviewproj, worldview, gstate.projMatrix); vertices.resize(indexUpperBound + 1); uint32_t vertType = gstate.vertType; for (int i = indexLowerBound; i <= indexUpperBound; ++i) { const SimpleVertex &vert = simpleVertices[i]; if ((vertType & GE_VTYPE_THROUGH) != 0) { if (vertType & GE_VTYPE_TC_MASK) { vertices[i].u = vert.uv[0]; vertices[i].v = vert.uv[1]; } else { vertices[i].u = 0.0f; vertices[i].v = 0.0f; } vertices[i].x = vert.pos.x; vertices[i].y = vert.pos.y; vertices[i].z = vert.pos.z; if (vertType & GE_VTYPE_COL_MASK) { memcpy(vertices[i].c, vert.color, sizeof(vertices[i].c)); } else { memset(vertices[i].c, 0, sizeof(vertices[i].c)); } vertices[i].nx = 0; // No meaningful normals in through mode vertices[i].ny = 0; vertices[i].nz = 1.0f; } else { float clipPos[4]; Vec3ByMatrix44(clipPos, vert.pos.AsArray(), worldviewproj); Vec3f screenPos = ClipToScreen(clipPos); Vec3f drawPos = ScreenToDrawing(screenPos); if (vertType & GE_VTYPE_TC_MASK) { vertices[i].u = vert.uv[0] * (float)gstate.getTextureWidth(0); vertices[i].v = vert.uv[1] * (float)gstate.getTextureHeight(0); } else { vertices[i].u = 0.0f; vertices[i].v = 0.0f; } // Should really have separate coordinates for before and after transform. vertices[i].x = drawPos.x; vertices[i].y = drawPos.y; vertices[i].z = drawPos.z; if (vertType & GE_VTYPE_COL_MASK) { memcpy(vertices[i].c, vert.color, sizeof(vertices[i].c)); } else { memset(vertices[i].c, 0, sizeof(vertices[i].c)); } vertices[i].nx = vert.nrm.x; vertices[i].ny = vert.nrm.y; vertices[i].nz = vert.nrm.z; } } gstate_c.vertexFullAlpha = savedVertexFullAlpha; return true; } // This normalizes a set of vertices in any format to SimpleVertex format, by processing away morphing AND skinning. // The rest of the transform pipeline like lighting will go as normal, either hardware or software. // The implementation is initially a bit inefficient but shouldn't be a big deal. // An intermediate buffer of not-easy-to-predict size is stored at bufPtr. u32 DrawEngineCommon::NormalizeVertices(u8 *outPtr, u8 *bufPtr, const u8 *inPtr, VertexDecoder *dec, int lowerBound, int upperBound, u32 vertType) { // First, decode the vertices into a GPU compatible format. This step can be eliminated but will need a separate // implementation of the vertex decoder. dec->DecodeVerts(bufPtr, inPtr, &gstate_c.uv, lowerBound, upperBound); // OK, morphing eliminated but bones still remain to be taken care of. // Let's do a partial software transform where we only do skinning. VertexReader reader(bufPtr, dec->GetDecVtxFmt(), vertType); SimpleVertex *sverts = (SimpleVertex *)outPtr; const u8 defaultColor[4] = { (u8)gstate.getMaterialAmbientR(), (u8)gstate.getMaterialAmbientG(), (u8)gstate.getMaterialAmbientB(), (u8)gstate.getMaterialAmbientA(), }; // Let's have two separate loops, one for non skinning and one for skinning. if (!dec->skinInDecode && (vertType & GE_VTYPE_WEIGHT_MASK) != GE_VTYPE_WEIGHT_NONE) { int numBoneWeights = vertTypeGetNumBoneWeights(vertType); for (int i = lowerBound; i <= upperBound; i++) { reader.Goto(i - lowerBound); SimpleVertex &sv = sverts[i]; if (vertType & GE_VTYPE_TC_MASK) { reader.ReadUV(sv.uv); } if (vertType & GE_VTYPE_COL_MASK) { sv.color_32 = reader.ReadColor0_8888(); } else { memcpy(sv.color, defaultColor, 4); } float nrm[3], pos[3]; float bnrm[3], bpos[3]; if (vertType & GE_VTYPE_NRM_MASK) { // Normals are generated during tessellation anyway, not sure if any need to supply reader.ReadNrm(nrm); } else { nrm[0] = 0; nrm[1] = 0; nrm[2] = 1.0f; } reader.ReadPos(pos); // Apply skinning transform directly float weights[8]; reader.ReadWeights(weights); // Skinning Vec3Packedf psum(0, 0, 0); Vec3Packedf nsum(0, 0, 0); for (int w = 0; w < numBoneWeights; w++) { if (weights[w] != 0.0f) { Vec3ByMatrix43(bpos, pos, gstate.boneMatrix + w * 12); Vec3Packedf tpos(bpos); psum += tpos * weights[w]; Norm3ByMatrix43(bnrm, nrm, gstate.boneMatrix + w * 12); Vec3Packedf tnorm(bnrm); nsum += tnorm * weights[w]; } } sv.pos = psum; sv.nrm = nsum; } } else { for (int i = lowerBound; i <= upperBound; i++) { reader.Goto(i - lowerBound); SimpleVertex &sv = sverts[i]; if (vertType & GE_VTYPE_TC_MASK) { reader.ReadUV(sv.uv); } else { sv.uv[0] = 0.0f; // This will get filled in during tessellation sv.uv[1] = 0.0f; } if (vertType & GE_VTYPE_COL_MASK) { sv.color_32 = reader.ReadColor0_8888(); } else { memcpy(sv.color, defaultColor, 4); } if (vertType & GE_VTYPE_NRM_MASK) { // Normals are generated during tessellation anyway, not sure if any need to supply reader.ReadNrm((float *)&sv.nrm); } else { sv.nrm.x = 0.0f; sv.nrm.y = 0.0f; sv.nrm.z = 1.0f; } reader.ReadPos((float *)&sv.pos); } } // Okay, there we are! Return the new type (but keep the index bits) return GE_VTYPE_TC_FLOAT | GE_VTYPE_COL_8888 | GE_VTYPE_NRM_FLOAT | GE_VTYPE_POS_FLOAT | (vertType & (GE_VTYPE_IDX_MASK | GE_VTYPE_THROUGH)); } void DrawEngineCommon::ApplyFramebufferRead(FBOTexState *fboTexState) { if (gstate_c.Use(GPU_USE_FRAMEBUFFER_FETCH)) { *fboTexState = FBO_TEX_READ_FRAMEBUFFER; } else { gpuStats.numCopiesForShaderBlend++; *fboTexState = FBO_TEX_COPY_BIND_TEX; } gstate_c.Dirty(DIRTY_SHADERBLEND); } int DrawEngineCommon::ComputeNumVertsToDecode() const { int sum = 0; for (int i = 0; i < numDrawVerts_; i++) { sum += drawVerts_[i].indexUpperBound + 1 - drawVerts_[i].indexLowerBound; } return sum; } int DrawEngineCommon::ExtendNonIndexedPrim(const uint32_t *cmd, const uint32_t *stall, u32 vertTypeID, bool clockwise, int *bytesRead, bool isTriangle) { const uint32_t *start = cmd; int prevDrawVerts = numDrawVerts_ - 1; DeferredVerts &dv = drawVerts_[prevDrawVerts]; int offset = dv.vertexCount; _dbg_assert_(numDrawInds_ <= MAX_DEFERRED_DRAW_INDS); // if it's equal, the check below will take care of it before any action is taken. _dbg_assert_(numDrawVerts_ > 0); while (cmd != stall) { uint32_t data = *cmd; if ((data & 0xFFF80000) != 0x04000000) { break; } GEPrimitiveType newPrim = static_cast((data >> 16) & 7); if (IsTrianglePrim(newPrim) != isTriangle) break; int vertexCount = data & 0xFFFF; if (numDrawInds_ >= MAX_DEFERRED_DRAW_INDS || vertexCountInDrawCalls_ + offset + vertexCount > VERTEX_BUFFER_MAX) { break; } DeferredInds &di = drawInds_[numDrawInds_++]; di.indexType = 0; di.prim = newPrim; di.clockwise = clockwise; di.vertexCount = vertexCount; di.vertDecodeIndex = prevDrawVerts; di.offset = offset; offset += vertexCount; cmd++; } int totalCount = offset - dv.vertexCount; dv.vertexCount = offset; dv.indexUpperBound = dv.vertexCount - 1; vertexCountInDrawCalls_ += totalCount; *bytesRead = totalCount * dec_->VertexSize(); return cmd - start; } // vertTypeID is the vertex type but with the UVGen mode smashed into the top bits. bool DrawEngineCommon::SubmitPrim(const void *verts, const void *inds, GEPrimitiveType prim, int vertexCount, u32 vertTypeID, bool clockwise, int *bytesRead) { if (!indexGen.PrimCompatible(prevPrim_, prim) || numDrawVerts_ >= MAX_DEFERRED_DRAW_VERTS || numDrawInds_ >= MAX_DEFERRED_DRAW_INDS || vertexCountInDrawCalls_ + vertexCount > VERTEX_BUFFER_MAX) { DispatchFlush(); } _dbg_assert_(numDrawVerts_ < MAX_DEFERRED_DRAW_VERTS); _dbg_assert_(numDrawInds_ < MAX_DEFERRED_DRAW_INDS); // This isn't exactly right, if we flushed, since prims can straddle previous calls. // But it generally works for common usage. if (prim == GE_PRIM_KEEP_PREVIOUS) { // Has to be set to something, let's assume POINTS (0) if no previous. if (prevPrim_ == GE_PRIM_INVALID) prevPrim_ = GE_PRIM_POINTS; prim = prevPrim_; } else { prevPrim_ = prim; } // If vtype has changed, setup the vertex decoder. Don't need to nullcheck dec_ since we set lastVType_ to an invalid value whenever we null it. if (vertTypeID != lastVType_) { dec_ = GetVertexDecoder(vertTypeID); lastVType_ = vertTypeID; } *bytesRead = vertexCount * dec_->VertexSize(); // Check that we have enough vertices to form the requested primitive. if (vertexCount < 3 && ((vertexCount < 2 && prim > 0) || (prim > GE_PRIM_LINE_STRIP && prim != GE_PRIM_RECTANGLES))) return false; bool applySkin = (vertTypeID & GE_VTYPE_WEIGHT_MASK) && decOptions_.applySkinInDecode; DeferredInds &di = drawInds_[numDrawInds_++]; di.inds = inds; di.indexType = (vertTypeID & GE_VTYPE_IDX_MASK) >> GE_VTYPE_IDX_SHIFT; di.prim = prim; di.clockwise = clockwise; di.vertexCount = vertexCount; di.vertDecodeIndex = numDrawVerts_; di.offset = 0; _dbg_assert_(numDrawVerts_ <= MAX_DEFERRED_DRAW_VERTS); _dbg_assert_(numDrawInds_ <= MAX_DEFERRED_DRAW_INDS); if (inds && numDrawVerts_ > decodeVertsCounter_ && drawVerts_[numDrawVerts_ - 1].verts == verts && !applySkin) { // Same vertex pointer as a previous un-decoded draw call - let's just extend the decode! di.vertDecodeIndex = numDrawVerts_ - 1; DeferredVerts &dv = drawVerts_[numDrawVerts_ - 1]; u16 lb; u16 ub; GetIndexBounds(inds, vertexCount, vertTypeID, &lb, &ub); if (lb < dv.indexLowerBound) dv.indexLowerBound = lb; if (ub > dv.indexUpperBound) dv.indexUpperBound = ub; } else { // Record a new draw, and a new index gen. DeferredVerts &dv = drawVerts_[numDrawVerts_++]; dv.verts = verts; dv.vertexCount = vertexCount; dv.uvScale = gstate_c.uv; if (inds) { GetIndexBounds(inds, vertexCount, vertTypeID, &dv.indexLowerBound, &dv.indexUpperBound); } else { dv.indexLowerBound = 0; dv.indexUpperBound = vertexCount - 1; } } vertexCountInDrawCalls_ += vertexCount; if (prim == GE_PRIM_RECTANGLES && (gstate.getTextureAddress(0) & 0x3FFFFFFF) == (gstate.getFrameBufAddress() & 0x3FFFFFFF)) { // This prevents issues with consecutive self-renders in Ridge Racer. gstate_c.Dirty(DIRTY_TEXTURE_PARAMS); DispatchFlush(); } return true; } void DrawEngineCommon::DecodeVerts(u8 *dest) { int i = decodeVertsCounter_; int stride = (int)dec_->GetDecVtxFmt().stride; for (; i < numDrawVerts_; i++) { DeferredVerts &dv = drawVerts_[i]; int indexLowerBound = dv.indexLowerBound; drawVertexOffsets_[i] = decodedVerts_ - indexLowerBound; int indexUpperBound = dv.indexUpperBound; // Decode the verts (and at the same time apply morphing/skinning). Simple. dec_->DecodeVerts(dest + decodedVerts_ * stride, dv.verts, &dv.uvScale, indexLowerBound, indexUpperBound); decodedVerts_ += indexUpperBound - indexLowerBound + 1; } decodeVertsCounter_ = i; } void DrawEngineCommon::DecodeInds() { int i = decodeIndsCounter_; for (; i < numDrawInds_; i++) { const DeferredInds &di = drawInds_[i]; int indexOffset = drawVertexOffsets_[di.vertDecodeIndex] + di.offset; bool clockwise = di.clockwise; // We've already collapsed subsequent draws with the same vertex pointer, so no tricky logic here anymore. // 2. Loop through the drawcalls, translating indices as we go. switch (di.indexType) { case GE_VTYPE_IDX_NONE >> GE_VTYPE_IDX_SHIFT: indexGen.AddPrim(di.prim, di.vertexCount, indexOffset, clockwise); break; case GE_VTYPE_IDX_8BIT >> GE_VTYPE_IDX_SHIFT: indexGen.TranslatePrim(di.prim, di.vertexCount, (const u8 *)di.inds, indexOffset, clockwise); break; case GE_VTYPE_IDX_16BIT >> GE_VTYPE_IDX_SHIFT: indexGen.TranslatePrim(di.prim, di.vertexCount, (const u16_le *)di.inds, indexOffset, clockwise); break; case GE_VTYPE_IDX_32BIT >> GE_VTYPE_IDX_SHIFT: indexGen.TranslatePrim(di.prim, di.vertexCount, (const u32_le *)di.inds, indexOffset, clockwise); break; } } decodeIndsCounter_ = i; // Sanity check if (indexGen.Prim() < 0) { ERROR_LOG_REPORT(G3D, "DecodeVerts: Failed to deduce prim: %i", indexGen.Prim()); // Force to points (0) indexGen.AddPrim(GE_PRIM_POINTS, 0, 0, true); } } bool DrawEngineCommon::CanUseHardwareTransform(int prim) { if (!useHWTransform_) return false; return !gstate.isModeThrough() && prim != GE_PRIM_RECTANGLES && prim > GE_PRIM_LINE_STRIP; } bool DrawEngineCommon::CanUseHardwareTessellation(GEPatchPrimType prim) { if (useHWTessellation_) { return CanUseHardwareTransform(PatchPrimToPrim(prim)); } return false; } void TessellationDataTransfer::CopyControlPoints(float *pos, float *tex, float *col, int posStride, int texStride, int colStride, const SimpleVertex *const *points, int size, u32 vertType) { bool hasColor = (vertType & GE_VTYPE_COL_MASK) != 0; bool hasTexCoord = (vertType & GE_VTYPE_TC_MASK) != 0; for (int i = 0; i < size; ++i) { memcpy(pos, points[i]->pos.AsArray(), 3 * sizeof(float)); pos += posStride; } if (hasTexCoord) { for (int i = 0; i < size; ++i) { memcpy(tex, points[i]->uv, 2 * sizeof(float)); tex += texStride; } } if (hasColor) { for (int i = 0; i < size; ++i) { memcpy(col, Vec4f::FromRGBA(points[i]->color_32).AsArray(), 4 * sizeof(float)); col += colStride; } } }