/* ** Softpoly backend ** Copyright (c) 2016-2020 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 "polyrenderer/backend/poly_renderstate.h" #include "polyrenderer/backend/poly_framebuffer.h" #include "polyrenderer/backend/poly_hwtexture.h" #include "hw_skydome.h" #include "hw_viewpointuniforms.h" #include "hw_lightbuffer.h" #include "hw_cvars.h" #include "hw_clock.h" #include "flatvertices.h" #include "hwrenderer/data/hw_viewpointbuffer.h" #include "hwrenderer/data/shaderuniforms.h" static PolyDrawMode dtToDrawMode[] = { PolyDrawMode::Points, PolyDrawMode::Lines, PolyDrawMode::Triangles, PolyDrawMode::TriangleFan, PolyDrawMode::TriangleStrip, }; PolyRenderState::PolyRenderState() { mIdentityMatrix.loadIdentity(); Reset(); } void PolyRenderState::ClearScreen() { screen->mViewpoints->Set2D(*this, SCREENWIDTH, SCREENHEIGHT); SetColor(0, 0, 0); Draw(DT_TriangleStrip, FFlatVertexBuffer::FULLSCREEN_INDEX, 4, true); } void PolyRenderState::Draw(int dt, int index, int count, bool apply) { if (apply || mNeedApply) Apply(); mDrawCommands->Draw(index, count, dtToDrawMode[dt]); } void PolyRenderState::DrawIndexed(int dt, int index, int count, bool apply) { if (apply || mNeedApply) Apply(); mDrawCommands->DrawIndexed(index, count, dtToDrawMode[dt]); } bool PolyRenderState::SetDepthClamp(bool on) { bool lastValue = mDepthClamp; mDepthClamp = on; mNeedApply = true; return lastValue; } void PolyRenderState::SetDepthMask(bool on) { mDepthMask = on; mNeedApply = true; } void PolyRenderState::SetDepthFunc(int func) { mDepthFunc = func; mNeedApply = true; } void PolyRenderState::SetDepthRange(float min, float max) { mDepthRangeMin = min; mDepthRangeMax = max; mNeedApply = true; } void PolyRenderState::SetColorMask(bool r, bool g, bool b, bool a) { mColorMask[0] = r; mColorMask[1] = g; mColorMask[2] = b; mColorMask[3] = a; mNeedApply = true; } void PolyRenderState::SetStencil(int offs, int op, int flags) { mStencilValue = screen->stencilValue + offs; mStencilOp = op; mNeedApply = true; if (flags != -1) { bool cmon = !(flags & SF_ColorMaskOff); SetColorMask(cmon, cmon, cmon, cmon); // don't write to the graphics buffer SetDepthMask(!(flags & SF_DepthMaskOff)); } } void PolyRenderState::SetCulling(int mode) { mCulling = mode; mNeedApply = true; } void PolyRenderState::EnableClipDistance(int num, bool state) { } void PolyRenderState::Clear(int targets) { if (mNeedApply) Apply(); //if (targets & CT_Color) // mDrawCommands->ClearColor(); if (targets & CT_Depth) mDrawCommands->ClearDepth(65535.0f); if (targets & CT_Stencil) mDrawCommands->ClearStencil(0); } void PolyRenderState::EnableStencil(bool on) { mStencilEnabled = on; mNeedApply = true; } void PolyRenderState::SetScissor(int x, int y, int w, int h) { if (w < 0) { x = 0; y = 0; w = mRenderTarget.Canvas->GetWidth(); h = mRenderTarget.Canvas->GetHeight(); } mScissor.x = x; mScissor.y = mRenderTarget.Canvas->GetHeight() - y - h; mScissor.width = w; mScissor.height = h; mNeedApply = true; } void PolyRenderState::SetViewport(int x, int y, int w, int h) { auto fb = GetPolyFrameBuffer(); if (w < 0) { x = 0; y = 0; w = mRenderTarget.Canvas->GetWidth(); h = mRenderTarget.Canvas->GetHeight(); } mViewport.x = x; mViewport.y = mRenderTarget.Canvas->GetHeight() - y - h; mViewport.width = w; mViewport.height = h; mNeedApply = true; } void PolyRenderState::EnableDepthTest(bool on) { mDepthTest = on; mNeedApply = true; } void PolyRenderState::EnableMultisampling(bool on) { } void PolyRenderState::EnableLineSmooth(bool on) { } void PolyRenderState::EnableDrawBuffers(int count, bool apply) { } void PolyRenderState::SetColormapShader(bool enable) { mNeedApply = true; mColormapShader = enable; } void PolyRenderState::EndRenderPass() { mDrawCommands = nullptr; mNeedApply = true; mFirstMatrixApply = true; } void PolyRenderState::Apply() { drawcalls.Clock(); if (!mDrawCommands) { mDrawCommands = GetPolyFrameBuffer()->GetDrawCommands(); } if (mNeedApply) { mDrawCommands->SetViewport(mViewport.x, mViewport.y, mViewport.width, mViewport.height, mRenderTarget.Canvas, mRenderTarget.DepthStencil, mRenderTarget.TopDown); mDrawCommands->SetScissor(mScissor.x, mScissor.y, mScissor.width, mScissor.height); mDrawCommands->SetViewpointUniforms(mViewpointUniforms); mDrawCommands->SetDepthClamp(mDepthClamp); mDrawCommands->SetDepthMask(mDepthTest && mDepthMask); mDrawCommands->SetDepthFunc(mDepthTest ? mDepthFunc : DF_Always); mDrawCommands->SetDepthRange(mDepthRangeMin, mDepthRangeMax); mDrawCommands->SetStencil(mStencilValue, mStencilOp); mDrawCommands->EnableStencil(mStencilEnabled); mDrawCommands->SetCulling(mCulling); mDrawCommands->SetColorMask(mColorMask[0], mColorMask[1], mColorMask[2], mColorMask[3]); mNeedApply = false; } int fogset = 0; if (mFogEnabled) { if (mFogEnabled == 2) { fogset = -3; // 2D rendering with 'foggy' overlay. } else if ((GetFogColor() & 0xffffff) == 0) { fogset = gl_fogmode; } else { fogset = -gl_fogmode; } } ApplyMaterial(); if (mVertexBuffer) { mDrawCommands->SetVertexBuffer(mVertexBuffer->Memory(), mVertexOffsets[0], mVertexOffsets[1]); // [GEC] Add offset params } if (mIndexBuffer) mDrawCommands->SetIndexBuffer(mIndexBuffer->Memory()); mDrawCommands->SetInputAssembly(static_cast(mVertexBuffer)->VertexFormat); mDrawCommands->SetRenderStyle(mRenderStyle); if (mColormapShader) { mDrawCommands->SetShader(EFF_NONE, 0, false, true); } else if (mSpecialEffect > EFF_NONE) { mDrawCommands->SetShader(mSpecialEffect, 0, false, false); } else { int effectState = mMaterial.mOverrideShader >= 0 ? mMaterial.mOverrideShader : (mMaterial.mMaterial ? mMaterial.mMaterial->GetShaderIndex() : 0); mDrawCommands->SetShader(EFF_NONE, mTextureEnabled ? effectState : SHADER_NoTexture, mAlphaThreshold >= 0.f, false); } if (mMaterial.mMaterial && mMaterial.mMaterial->Source()) mStreamData.timer = static_cast((double)(screen->FrameTime - firstFrame) * (double)mMaterial.mMaterial->Source()->GetShaderSpeed() / 1000.); else mStreamData.timer = 0.0f; PolyPushConstants constants; constants.uFogEnabled = fogset; constants.uTextureMode = (mTextureMode == TM_NORMAL && mTempTM == TM_OPAQUE ? TM_OPAQUE : mTextureMode); constants.uLightDist = mLightParms[0]; constants.uLightFactor = mLightParms[1]; constants.uFogDensity = mLightParms[2]; constants.uLightLevel = mLightParms[3]; constants.uAlphaThreshold = mAlphaThreshold; constants.uClipSplit = { mClipSplit[0], mClipSplit[1] }; constants.uLightIndex = mLightIndex; constants.uDynLightColor = mStreamData.uDynLightColor; // [GEC] mDrawCommands->PushStreamData(mStreamData, constants); ApplyMatrices(); if (mBias.mChanged) { mDrawCommands->SetDepthBias(mBias.mUnits, mBias.mFactor); mBias.mChanged = false; } drawcalls.Unclock(); } void PolyRenderState::ApplyMaterial() { if (mMaterial.mChanged && mMaterial.mMaterial) { mTempTM = mMaterial.mMaterial->Source()->isHardwareCanvas() ? TM_OPAQUE : TM_NORMAL; if (mMaterial.mMaterial->Source()->isHardwareCanvas()) static_cast(mMaterial.mMaterial->Source()->GetTexture())->NeedUpdate(); MaterialLayerInfo* layer; auto base = static_cast(mMaterial.mMaterial->GetLayer(0, mMaterial.mTranslation, &layer)); if (base) { DCanvas *texcanvas = base->GetImage(layer->layerTexture, mMaterial.mTranslation, layer->scaleFlags); mDrawCommands->SetTexture(0, texcanvas->GetPixels(), texcanvas->GetWidth(), texcanvas->GetHeight(), texcanvas->IsBgra()); int numLayers = mMaterial.mMaterial->NumLayers(); for (int i = 1; i < numLayers; i++) { auto systex = static_cast(mMaterial.mMaterial->GetLayer(i, 0, &layer)); texcanvas = systex->GetImage(layer->layerTexture, 0, layer->scaleFlags); mDrawCommands->SetTexture(i, texcanvas->GetPixels(), texcanvas->GetWidth(), texcanvas->GetHeight(), texcanvas->IsBgra()); } } mMaterial.mChanged = false; } } template static void BufferedSet(bool &modified, T &dst, const T &src) { if (dst == src) return; dst = src; modified = true; } static void BufferedSet(bool &modified, VSMatrix &dst, const VSMatrix &src) { if (memcmp(dst.get(), src.get(), sizeof(FLOATTYPE) * 16) == 0) return; dst = src; modified = true; } void PolyRenderState::ApplyMatrices() { bool modified = mFirstMatrixApply; if (mTextureMatrixEnabled) { BufferedSet(modified, mMatrices.TextureMatrix, mTextureMatrix); } else { BufferedSet(modified, mMatrices.TextureMatrix, mIdentityMatrix); } if (mModelMatrixEnabled) { BufferedSet(modified, mMatrices.ModelMatrix, mModelMatrix); if (modified) mMatrices.NormalModelMatrix.computeNormalMatrix(mModelMatrix); } else { BufferedSet(modified, mMatrices.ModelMatrix, mIdentityMatrix); BufferedSet(modified, mMatrices.NormalModelMatrix, mIdentityMatrix); } if (modified) { mFirstMatrixApply = false; mDrawCommands->PushMatrices(mMatrices.ModelMatrix, mMatrices.NormalModelMatrix, mMatrices.TextureMatrix); } } void PolyRenderState::SetRenderTarget(DCanvas *canvas, PolyDepthStencil *depthStencil, bool topdown) { mRenderTarget.Canvas = canvas; mRenderTarget.DepthStencil = depthStencil; mRenderTarget.TopDown = topdown; } void PolyRenderState::Bind(PolyDataBuffer *buffer, uint32_t offset, uint32_t length) { if (buffer->bindingpoint == VIEWPOINT_BINDINGPOINT) { mViewpointUniforms = reinterpret_cast(static_cast(buffer->Memory()) + offset); mNeedApply = true; } } PolyVertexInputAssembly *PolyRenderState::GetVertexFormat(int numBindingPoints, int numAttributes, size_t stride, const FVertexBufferAttribute *attrs) { for (size_t i = 0; i < mVertexFormats.size(); i++) { auto f = mVertexFormats[i].get(); if (f->Attrs.size() == (size_t)numAttributes && f->NumBindingPoints == numBindingPoints && f->Stride == stride) { bool matches = true; for (int j = 0; j < numAttributes; j++) { if (memcmp(&f->Attrs[j], &attrs[j], sizeof(FVertexBufferAttribute)) != 0) { matches = false; break; } } if (matches) return f; } } auto fmt = std::make_unique(); fmt->NumBindingPoints = numBindingPoints; fmt->Stride = stride; fmt->UseVertexData = 0; for (int j = 0; j < numAttributes; j++) { if (attrs[j].location == VATTR_COLOR) fmt->UseVertexData |= 1; else if (attrs[j].location == VATTR_NORMAL) fmt->UseVertexData |= 2; fmt->Attrs.push_back(attrs[j]); } for (int j = 0; j < numAttributes; j++) { fmt->mOffsets[attrs[j].location] = attrs[j].offset; } fmt->mStride = stride; mVertexFormats.push_back(std::move(fmt)); return mVertexFormats.back().get(); }