diff options
author | Tim Rowley <[email protected]> | 2017-02-21 11:20:38 -0800 |
---|---|---|
committer | Tim Rowley <[email protected]> | 2017-03-20 18:04:53 -0500 |
commit | a508c2c2ac5ebee7d8ee6b65733b7f78926ba355 (patch) | |
tree | 5ab77be191ac234f50e4550805df2dd9c6cf42ca | |
parent | 2cbac00221606fdda6af839afaf64ef649a73f83 (diff) |
swr: [rasterizer core] Implement double pumped SIMD16 TESS
Reviewed-by: Bruce Cherniak <[email protected]>
-rw-r--r-- | src/gallium/drivers/swr/rasterizer/core/frontend.cpp | 256 |
1 files changed, 177 insertions, 79 deletions
diff --git a/src/gallium/drivers/swr/rasterizer/core/frontend.cpp b/src/gallium/drivers/swr/rasterizer/core/frontend.cpp index 761e0445b2c..b2f46432fd7 100644 --- a/src/gallium/drivers/swr/rasterizer/core/frontend.cpp +++ b/src/gallium/drivers/swr/rasterizer/core/frontend.cpp @@ -575,6 +575,68 @@ static void StreamOut( AR_END(FEStreamout, 1); } +#if USE_SIMD16_FRONTEND +////////////////////////////////////////////////////////////////////////// +/// Is value an even number (a multiple of two) +/// +template <typename T> +INLINE static bool IsEven(T value) +{ + return (value & 1) == 0; +} + +////////////////////////////////////////////////////////////////////////// +/// Round up value to an even number (a multiple of two) +/// +template <typename T> +INLINE static T RoundUpEven(T value) +{ + return (value + 1) & ~1; +} + +////////////////////////////////////////////////////////////////////////// +/// Round down value to an even number (a multiple of two) +/// +template <typename T> +INLINE static T RoundDownEven(T value) +{ + return value & ~1; +} + +////////////////////////////////////////////////////////////////////////// +/// Pack pairs of simdvertexes into simd16vertexes, in-place +/// +/// vertexCount is in terms of the source simdvertexes and must be even +/// +/// attribCount will limit the vector copies to those attribs specified +/// +void PackPairsOfSimdVertexIntoSimd16VertexInPlace(simdvertex *vertex, uint32_t vertexCount, uint32_t attribCount) +{ + SWR_ASSERT(vertex); + SWR_ASSERT(IsEven(vertexCount)); + SWR_ASSERT(attribCount <= KNOB_NUM_ATTRIBUTES); + + simd16vertex temp; + + for (uint32_t i = 0; i < vertexCount; i += 2) + { + for (uint32_t j = 0; j < attribCount; j += 1) + { + for (uint32_t k = 0; k < 4; k += 1) + { + temp.attrib[j][k] = _simd16_insert_ps(_simd16_setzero_ps(), vertex[i].attrib[j][k], 0); + temp.attrib[j][k] = _simd16_insert_ps(temp.attrib[j][k], vertex[i + 1].attrib[j][k], 1); + } + } + + for (uint32_t j = 0; j < attribCount; j += 1) + { + reinterpret_cast<simd16vertex *>(vertex)[i >> 1].attrib[j] = temp.attrib[j]; + } + } +} + +#endif ////////////////////////////////////////////////////////////////////////// /// @brief Computes number of invocations. The current index represents /// the start of the SIMD. The max index represents how much work @@ -647,7 +709,7 @@ struct GsBufferInfo { #if USE_SIMD16_FRONTEND // TEMPORARY: pad up to multiple of two, to support in-place conversion from simdvertex to simd16vertex - const uint32_t vertexCount = (gsState.maxNumVerts + 1) & ~1; + const uint32_t vertexCount = RoundUpEven(gsState.maxNumVerts); #else const uint32_t vertexCount = gsState.maxNumVerts; #endif @@ -703,7 +765,7 @@ static void GeometryShaderStage( void* pStreamCutBuffer, uint32_t* pSoPrimData, #if USE_SIMD16_FRONTEND - uint32_t numPrims, + uint32_t numPrims_simd8, #endif simdscalari primID) { @@ -748,7 +810,7 @@ static void GeometryShaderStage( // record valid prims from the frontend to avoid over binning the newly generated // prims from the GS #if USE_SIMD16_FRONTEND - uint32_t numInputPrims = numPrims; + uint32_t numInputPrims = numPrims_simd8; #else uint32_t numInputPrims = pa.NumPrims(); #endif @@ -834,61 +896,12 @@ static void GeometryShaderStage( #if USE_SIMD16_FRONTEND // TEMPORARY: GS outputs simdvertex, PA inputs simd16vertex, so convert simdvertex to simd16vertex, in-place - { - const simdvertex * source = reinterpret_cast<simdvertex *>(pBase); - simd16vertex * dest = reinterpret_cast<simd16vertex *>(pBase); - simd16vertex temp; - - const uint32_t numEmitted = numEmittedVerts & ~1; // round down to multiple of two - - for (uint32_t i = 0; i < numEmitted; i += 2) // do two at a time.. - { - const uint32_t numAttribs = VERTEX_ATTRIB_START_SLOT + pState->numInputAttribs; - - for (uint32_t j = 0; j < numAttribs; j += 1) - { - for (uint32_t k = 0; k < 4; k += 1) - { - temp.attrib[j][k] = _simd16_insert_ps(_simd16_setzero_ps(), source[i].attrib[j][k], 0); // lo - temp.attrib[j][k] = _simd16_insert_ps(temp.attrib[j][k], source[i + 1].attrib[j][k], 1); // hi - } - } + const uint32_t attribCount = VERTEX_ATTRIB_START_SLOT + pState->numInputAttribs; -#if 1 - - for (uint32_t j = 0; j < numAttribs; j += 1) - { - dest[i >> 1].attrib[j] = temp.attrib[j]; - } -#else - - dest[i >> 1]= temp; -#endif - } - - if (numEmittedVerts & 1) // do the odd last one - { - const uint32_t numAttribs = VERTEX_ATTRIB_START_SLOT + pState->numInputAttribs; - - for (uint32_t j = 0; j < numAttribs; j += 1) - { - for (uint32_t k = 0; k < 4; k += 1) - { - temp.attrib[j][k] = _simd16_insert_ps(_simd16_setzero_ps(), source[numEmittedVerts - 1].attrib[j][k], 0); // lo - } - } - -#if 1 - - for (uint32_t j = 0; j < numAttribs; j += 1) - { - dest[numEmittedVerts >> 1].attrib[j] = temp.attrib[j]; - } -#else - dest[numEmittedVerts >> 1] = temp; -#endif - } - } + PackPairsOfSimdVertexIntoSimd16VertexInPlace( + reinterpret_cast<simdvertex *>(pBase), + RoundUpEven(numEmittedVerts), // simd8 -> simd16 + attribCount); #endif #if USE_SIMD16_FRONTEND @@ -903,7 +916,7 @@ static void GeometryShaderStage( do { #if USE_SIMD16_FRONTEND - simd16vector attrib_simd16[3]; // MAX_ATTRIBUTES ?? + simd16vector attrib_simd16[3]; bool assemble = gsPa.Assemble_simd16(VERTEX_POSITION_SLOT, attrib_simd16); @@ -1131,6 +1144,9 @@ static void TessellationStages( void* pCutBuffer, void* pCutStreamBuffer, uint32_t* pSoPrimData, +#if USE_SIMD16_FRONTEND + uint32_t numPrims_simd8, +#endif simdscalari primID) { SWR_CONTEXT *pContext = pDC->pContext; @@ -1193,7 +1209,11 @@ static void TessellationStages( memset(hsContext.pCPout, 0x90, sizeof(ScalarPatch) * KNOB_SIMD_WIDTH); #endif +#if USE_SIMD16_FRONTEND + uint32_t numPrims = numPrims_simd8; +#else uint32_t numPrims = pa.NumPrims(); +#endif hsContext.mask = GenerateMask(numPrims); // Run the HS @@ -1223,12 +1243,20 @@ static void TessellationStages( // Allocate DS Output memory uint32_t requiredDSVectorInvocations = AlignUp(tsData.NumDomainPoints, KNOB_SIMD_WIDTH) / KNOB_SIMD_WIDTH; size_t requiredDSOutputVectors = requiredDSVectorInvocations * tsState.numDsOutputAttribs; +#if USE_SIMD16_FRONTEND + size_t requiredAllocSize = sizeof(simdvector) * RoundUpEven(requiredDSOutputVectors); // simd8 -> simd16, padding +#else size_t requiredAllocSize = sizeof(simdvector) * requiredDSOutputVectors; +#endif if (requiredDSOutputVectors > gt_pTessellationThreadData->numDSOutputVectors) { AlignedFree(gt_pTessellationThreadData->pDSOutput); gt_pTessellationThreadData->pDSOutput = (simdscalar*)AlignedMalloc(requiredAllocSize, 64); +#if USE_SIMD16_FRONTEND + gt_pTessellationThreadData->numDSOutputVectors = RoundUpEven(requiredDSOutputVectors); // simd8 -> simd16, padding +#else gt_pTessellationThreadData->numDSOutputVectors = requiredDSOutputVectors; +#endif } SWR_ASSERT(gt_pTessellationThreadData->pDSOutput); SWR_ASSERT(gt_pTessellationThreadData->numDSOutputVectors >= requiredDSOutputVectors); @@ -1260,10 +1288,24 @@ static void TessellationStages( } UPDATE_STAT_FE(DsInvocations, tsData.NumDomainPoints); +#if USE_SIMD16_FRONTEND + // TEMPORARY: DS outputs simdvertex, PA inputs simd16vertex, so convert simdvertex to simd16vertex, in-place + + PackPairsOfSimdVertexIntoSimd16VertexInPlace( + reinterpret_cast<simdvertex *>(dsContext.pOutputData), + RoundUpEven(dsContext.vectorStride), // simd8 -> simd16 + tsState.numDsOutputAttribs); + +#endif PA_TESS tessPa( pDC, +#if USE_SIMD16_FRONTEND + reinterpret_cast<const simd16scalar *>(dsContext.pOutputData), // simd8 -> simd16 + RoundUpEven(dsContext.vectorStride) / 2, // simd8 -> simd16 +#else dsContext.pOutputData, dsContext.vectorStride, +#endif tsState.numDsOutputAttribs, tsData.ppIndices, tsData.NumPrimitives, @@ -1271,11 +1313,36 @@ static void TessellationStages( while (tessPa.HasWork()) { +#if USE_SIMD16_FRONTEND + const uint32_t numPrims = tessPa.NumPrims(); + const uint32_t numPrims_lo = std::min<uint32_t>(numPrims, KNOB_SIMD_WIDTH); + const uint32_t numPrims_hi = std::max<uint32_t>(numPrims, KNOB_SIMD_WIDTH) - KNOB_SIMD_WIDTH; + + const uint32_t primMask = GenMask(numPrims); + const uint32_t primMask_lo = primMask & 255; + const uint32_t primMask_hi = (primMask >> 8) & 255; + + const simd16scalari primID = _simd16_set1_epi32(dsContext.PrimitiveID); + const simdscalari primID_lo = _simd16_extract_si(primID, 0); + const simdscalari primID_hi = _simd16_extract_si(primID, 1); + +#endif if (HasGeometryShaderT::value) { +#if USE_SIMD16_FRONTEND + tessPa.useAlternateOffset = false; + GeometryShaderStage<HasStreamOutT, HasRastT>(pDC, workerId, tessPa, pGsOut, pCutBuffer, pCutStreamBuffer, pSoPrimData, numPrims_lo, primID_lo); + + if (numPrims_hi) + { + tessPa.useAlternateOffset = true; + GeometryShaderStage<HasStreamOutT, HasRastT>(pDC, workerId, tessPa, pGsOut, pCutBuffer, pCutStreamBuffer, pSoPrimData, numPrims_hi, primID_hi); + } +#else GeometryShaderStage<HasStreamOutT, HasRastT>( pDC, workerId, tessPa, pGsOut, pCutBuffer, pCutStreamBuffer, pSoPrimData, _simd_set1_epi32(dsContext.PrimitiveID)); +#endif } else { @@ -1286,18 +1353,52 @@ static void TessellationStages( if (HasRastT::value) { - simdvector prim[3]; // Only deal with triangles, lines, or points + simdvector prim[3]; // Only deal with triangles, lines, or points +#if USE_SIMD16_FRONTEND + simd16vector prim_simd16[3]; +#endif AR_BEGIN(FEPAAssemble, pDC->drawId); #if SWR_ENABLE_ASSERTS bool assemble = #endif +#if USE_SIMD16_FRONTEND + tessPa.Assemble_simd16(VERTEX_POSITION_SLOT, prim_simd16); +#else tessPa.Assemble(VERTEX_POSITION_SLOT, prim); +#endif AR_END(FEPAAssemble, 1); SWR_ASSERT(assemble); SWR_ASSERT(pfnClipFunc); +#if USE_SIMD16_FRONTEND + for (uint32_t i = 0; i < 3; i += 1) + { + for (uint32_t j = 0; j < 4; j += 1) + { + prim[i][j] = _simd16_extract_ps(prim_simd16[i][j], 0); + } + } + + tessPa.useAlternateOffset = false; + pfnClipFunc(pDC, tessPa, workerId, prim, primMask_lo, primID_lo, _simd_set1_epi32(0)); + + if (primMask_hi) + { + for (uint32_t i = 0; i < 3; i += 1) + { + for (uint32_t j = 0; j < 4; j += 1) + { + prim[i][j] = _simd16_extract_ps(prim_simd16[i][j], 1); + } + } + + tessPa.useAlternateOffset = true; + pfnClipFunc(pDC, tessPa, workerId, prim, primMask_hi, primID_hi, _simd_set1_epi32(0)); + } +#else pfnClipFunc(pDC, tessPa, workerId, prim, GenMask(tessPa.NumPrims()), _simd_set1_epi32(dsContext.PrimitiveID), _simd_set1_epi32(0)); +#endif } } @@ -1467,8 +1568,8 @@ void ProcessDraw( { vIndex = _simd16_add_epi32(_simd16_set1_epi32(work.startVertexID), vScale); - fetchInfo_lo.pIndices = (const int32_t *)&vIndex.lo; - fetchInfo_hi.pIndices = (const int32_t *)&vIndex.hi; + fetchInfo_lo.pIndices = (const int32_t *)&vIndex; + fetchInfo_hi.pIndices = (const int32_t *)&vIndex + KNOB_SIMD_WIDTH; // 1/2 of KNOB_SIMD16_WIDTH } fetchInfo_lo.CurInstance = instanceNum; @@ -1544,7 +1645,7 @@ void ProcessDraw( { for (uint32_t j = 0; j < 4; j += 1) { - vout.attrib[i][j].lo = vout_lo.attrib[i][j]; + vout.attrib[i][j] = _simd16_insert_ps(_simd16_setzero_ps(), vout_lo.attrib[i][j], 0); } } } @@ -1561,7 +1662,7 @@ void ProcessDraw( { for (uint32_t j = 0; j < 4; j += 1) { - vout.attrib[i][j].hi = vout_hi.attrib[i][j]; + vout.attrib[i][j] = _simd16_insert_ps(vout.attrib[i][j], vout_hi.attrib[i][j], 1); } } } @@ -1605,32 +1706,29 @@ void ProcessDraw( const simdscalari primID_lo = _simd16_extract_si(primID, 0); const simdscalari primID_hi = _simd16_extract_si(primID, 1); -#if 1 - if (HasGeometryShaderT::value) + if (HasTessellationT::value) { pa.useAlternateOffset = false; - GeometryShaderStage<HasStreamOutT, HasRastT>(pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, numPrims_lo, primID_lo); + TessellationStages<HasGeometryShaderT, HasStreamOutT, HasRastT>(pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, numPrims_lo, primID_lo); if (numPrims_hi) { pa.useAlternateOffset = true; - GeometryShaderStage<HasStreamOutT, HasRastT>(pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, numPrims_hi, primID_hi); + TessellationStages<HasGeometryShaderT, HasStreamOutT, HasRastT>(pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, numPrims_hi, primID_hi); } } - else -#else - if (HasTessellationT::value) - { - TessellationStages<HasGeometryShaderT, HasStreamOutT, HasRastT>( - pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, pa.GetPrimID(work.startPrimID)); - } else if (HasGeometryShaderT::value) { - GeometryShaderStage<HasStreamOutT, HasRastT>( - pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, pa.GetPrimID(work.startPrimID)); + pa.useAlternateOffset = false; + GeometryShaderStage<HasStreamOutT, HasRastT>(pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, numPrims_lo, primID_lo); + + if (numPrims_hi) + { + pa.useAlternateOffset = true; + GeometryShaderStage<HasStreamOutT, HasRastT>(pDC, workerId, pa, pGsOut, pCutBuffer, pStreamCutBuffer, pSoPrimData, numPrims_hi, primID_hi); + } } else -#endif { // If streamout is enabled then stream vertices out to memory. if (HasStreamOutT::value) @@ -1649,7 +1747,7 @@ void ProcessDraw( { for (uint32_t j = 0; j < 4; j += 1) { - prim[i][j] = prim_simd16[i][j].lo; + prim[i][j] = _simd16_extract_ps(prim_simd16[i][j], 0); } } @@ -1662,7 +1760,7 @@ void ProcessDraw( { for (uint32_t j = 0; j < 4; j += 1) { - prim[i][j] = prim_simd16[i][j].hi; + prim[i][j] = _simd16_extract_ps(prim_simd16[i][j], 1); } } |