void BackendSingleSample(DRAW_CONTEXT* pDC,
uint32_t workerId,
uint32_t x,
uint32_t y,
SWR_TRIANGLE_DESC& work,
RenderOutputBuffers& renderBuffers)
{
RDTSC_BEGIN(BESingleSampleBackend, pDC->drawId);
RDTSC_BEGIN(BESetup, pDC->drawId);
void* pWorkerData = pDC->pContext->threadPool.pThreadData[workerId].pWorkerPrivateData;
const API_STATE& state = GetApiState(pDC);
BarycentricCoeffs coeffs;
SetupBarycentricCoeffs(&coeffs, work);
SWR_PS_CONTEXT psContext;
const SWR_MULTISAMPLE_POS& samplePos = state.rastState.samplePositions;
SetupPixelShaderContext<T>(&psContext, samplePos, work);
uint8_t *pDepthBuffer, *pStencilBuffer;
SetupRenderBuffers(psContext.pColorBuffer,
&pDepthBuffer,
&pStencilBuffer,
state.colorHottileEnable,
renderBuffers);
RDTSC_END(BESetup, 1);
psContext.vY.UL = _simd_add_ps(vULOffsetsY, _simd_set1_ps(static_cast<float>(y)));
psContext.vY.center = _simd_add_ps(vCenterOffsetsY, _simd_set1_ps(static_cast<float>(y)));
const simdscalar dy = _simd_set1_ps(static_cast<float>(SIMD_TILE_Y_DIM));
for (uint32_t yy = y; yy < y + KNOB_TILE_Y_DIM; yy += SIMD_TILE_Y_DIM)
{
psContext.vX.UL = _simd_add_ps(vULOffsetsX, _simd_set1_ps(static_cast<float>(x)));
psContext.vX.center = _simd_add_ps(vCenterOffsetsX, _simd_set1_ps(static_cast<float>(x)));
const simdscalar dx = _simd_set1_ps(static_cast<float>(SIMD_TILE_X_DIM));
for (uint32_t xx = x; xx < x + KNOB_TILE_X_DIM; xx += SIMD_TILE_X_DIM)
{
#if USE_8x2_TILE_BACKEND
const bool useAlternateOffset = ((xx & SIMD_TILE_X_DIM) != 0);
#endif
simdmask coverageMask = work.coverageMask[0] & MASK;
if (coverageMask)
{
if (state.depthHottileEnable && state.depthBoundsState.depthBoundsTestEnable)
{
static_assert(KNOB_DEPTH_HOT_TILE_FORMAT == R32_FLOAT,
"Unsupported depth hot tile format");
const simdscalar z =
_simd_load_ps(reinterpret_cast<const float*>(pDepthBuffer));
const float minz = state.depthBoundsState.depthBoundsTestMinValue;
const float maxz = state.depthBoundsState.depthBoundsTestMaxValue;
coverageMask &= CalcDepthBoundsAcceptMask(z, minz, maxz);
}
if (T::InputCoverage != SWR_INPUT_COVERAGE_NONE)
{
const uint64_t* pCoverageMask =
(T::InputCoverage == SWR_INPUT_COVERAGE_INNER_CONSERVATIVE)
? &work.innerCoverageMask
: &work.coverageMask[0];
generateInputCoverage<T, T::InputCoverage>(
pCoverageMask, psContext.inputMask, state.blendState.sampleMask);
}
RDTSC_BEGIN(BEBarycentric, pDC->drawId);
CalcPixelBarycentrics(coeffs, psContext);
CalcCentroid<T, true>(
&psContext, samplePos, coeffs, work.coverageMask, state.blendState.sampleMask);
// interpolate and quantize z
psContext.vZ = vplaneps(
coeffs.vZa, coeffs.vZb, coeffs.vZc, psContext.vI.center, psContext.vJ.center);
psContext.vZ = state.pfnQuantizeDepth(psContext.vZ);
RDTSC_END(BEBarycentric, 1);
// interpolate user clip distance if available
if (state.backendState.clipDistanceMask)
{
coverageMask &= ~ComputeUserClipMask(state.backendState.clipDistanceMask,
work.pUserClipBuffer,
psContext.vI.center,
psContext.vJ.center);
}
simdscalar vCoverageMask = _simd_vmask_ps(coverageMask);
simdscalar depthPassMask = vCoverageMask;
simdscalar stencilPassMask = vCoverageMask;
// Early-Z?
if (T::bCanEarlyZ)
{
RDTSC_BEGIN(BEEarlyDepthTest, pDC->drawId);
depthPassMask = DepthStencilTest(&state,
work.triFlags.frontFacing,
work.triFlags.viewportIndex,
psContext.vZ,
pDepthBuffer,
vCoverageMask,
pStencilBuffer,
&stencilPassMask);
AR_EVENT(EarlyDepthStencilInfoSingleSample(_simd_movemask_ps(depthPassMask),
_simd_movemask_ps(stencilPassMask),
_simd_movemask_ps(vCoverageMask)));
RDTSC_END(BEEarlyDepthTest, 0);
// early-exit if no pixels passed depth or earlyZ is forced on
if (state.psState.forceEarlyZ || !_simd_movemask_ps(depthPassMask))
{
DepthStencilWrite(&state.vp[work.triFlags.viewportIndex],
&state.depthStencilState,
work.triFlags.frontFacing,
psContext.vZ,
pDepthBuffer,
depthPassMask,
vCoverageMask,
pStencilBuffer,
stencilPassMask);
if (!_simd_movemask_ps(depthPassMask))
{
goto Endtile;
}
}
}
psContext.sampleIndex = 0;
psContext.activeMask = _simd_castps_si(vCoverageMask);
// execute pixel shader
RDTSC_BEGIN(BEPixelShader, pDC->drawId);
state.psState.pfnPixelShader(GetPrivateState(pDC), pWorkerData, &psContext);
RDTSC_END(BEPixelShader, 0);
// update stats
UPDATE_STAT_BE(PsInvocations, _mm_popcnt_u32(_simd_movemask_ps(vCoverageMask)));
AR_EVENT(PSStats(psContext.stats.numInstExecuted));
vCoverageMask = _simd_castsi_ps(psContext.activeMask);
// late-Z
if (!T::bCanEarlyZ)
{
RDTSC_BEGIN(BELateDepthTest, pDC->drawId);
depthPassMask = DepthStencilTest(&state,
work.triFlags.frontFacing,
work.triFlags.viewportIndex,
psContext.vZ,
pDepthBuffer,
vCoverageMask,
pStencilBuffer,
&stencilPassMask);
AR_EVENT(LateDepthStencilInfoSingleSample(_simd_movemask_ps(depthPassMask),
_simd_movemask_ps(stencilPassMask),
_simd_movemask_ps(vCoverageMask)));
RDTSC_END(BELateDepthTest, 0);
if (!_simd_movemask_ps(depthPassMask))
{
// need to call depth/stencil write for stencil write
DepthStencilWrite(&state.vp[work.triFlags.viewportIndex],
&state.depthStencilState,
work.triFlags.frontFacing,
psContext.vZ,
pDepthBuffer,
depthPassMask,
vCoverageMask,
pStencilBuffer,
stencilPassMask);
goto Endtile;
}
}
else
{
// for early z, consolidate discards from shader
// into depthPassMask
depthPassMask = _simd_and_ps(depthPassMask, vCoverageMask);
}
uint32_t statMask = _simd_movemask_ps(depthPassMask);
uint32_t statCount = _mm_popcnt_u32(statMask);
UPDATE_STAT_BE(DepthPassCount, statCount);
// output merger
RDTSC_BEGIN(BEOutputMerger, pDC->drawId);
#if USE_8x2_TILE_BACKEND
OutputMerger8x2(pDC,
psContext,
psContext.pColorBuffer,
0,
&state.blendState,
state.pfnBlendFunc,
vCoverageMask,
depthPassMask,
state.psState.renderTargetMask,
useAlternateOffset,
workerId);
#else
OutputMerger4x2(pDC,
psContext,
psContext.pColorBuffer,
0,
&state.blendState,
state.pfnBlendFunc,
vCoverageMask,
depthPassMask,
state.psState.renderTargetMask,
workerId,
workerId);
#endif
// do final depth write after all pixel kills
if (!state.psState.forceEarlyZ)
{
DepthStencilWrite(&state.vp[work.triFlags.viewportIndex],
&state.depthStencilState,
work.triFlags.frontFacing,
psContext.vZ,
pDepthBuffer,
depthPassMask,
vCoverageMask,
pStencilBuffer,
stencilPassMask);
}
RDTSC_END(BEOutputMerger, 0);
}
Endtile:
RDTSC_BEGIN(BEEndTile, pDC->drawId);
work.coverageMask[0] >>= (SIMD_TILE_Y_DIM * SIMD_TILE_X_DIM);
if (T::InputCoverage == SWR_INPUT_COVERAGE_INNER_CONSERVATIVE)
{
work.innerCoverageMask >>= (SIMD_TILE_Y_DIM * SIMD_TILE_X_DIM);
}
#if USE_8x2_TILE_BACKEND
if (useAlternateOffset)
{
DWORD rt;
uint32_t rtMask = state.colorHottileEnable;
while (_BitScanForward(&rt, rtMask))
{
rtMask &= ~(1 << rt);
psContext.pColorBuffer[rt] +=
(2 * KNOB_SIMD_WIDTH * FormatTraits<KNOB_COLOR_HOT_TILE_FORMAT>::bpp) / 8;
}
}
#else
DWORD rt;
uint32_t rtMask = state.colorHottileEnable;
while (_BitScanForward(&rt, rtMask))
{
rtMask &= ~(1 << rt);
psContext.pColorBuffer[rt] +=
(KNOB_SIMD_WIDTH * FormatTraits<KNOB_COLOR_HOT_TILE_FORMAT>::bpp) / 8;
}
#endif
pDepthBuffer += (KNOB_SIMD_WIDTH * FormatTraits<KNOB_DEPTH_HOT_TILE_FORMAT>::bpp) / 8;
pStencilBuffer +=
(KNOB_SIMD_WIDTH * FormatTraits<KNOB_STENCIL_HOT_TILE_FORMAT>::bpp) / 8;
RDTSC_END(BEEndTile, 0);
psContext.vX.UL = _simd_add_ps(psContext.vX.UL, dx);
psContext.vX.center = _simd_add_ps(psContext.vX.center, dx);
}
psContext.vY.UL = _simd_add_ps(psContext.vY.UL, dy);
psContext.vY.center = _simd_add_ps(psContext.vY.center, dy);
}
void BackendSampleRate(DRAW_CONTEXT *pDC, uint32_t workerId, uint32_t x, uint32_t y, SWR_TRIANGLE_DESC &work, RenderOutputBuffers &renderBuffers)
{
SWR_CONTEXT *pContext = pDC->pContext;
AR_BEGIN(BESampleRateBackend, pDC->drawId);
AR_BEGIN(BESetup, pDC->drawId);
const API_STATE &state = GetApiState(pDC);
BarycentricCoeffs coeffs;
SetupBarycentricCoeffs(&coeffs, work);
SWR_PS_CONTEXT psContext;
const SWR_MULTISAMPLE_POS& samplePos = state.rastState.samplePositions;
SetupPixelShaderContext<T>(&psContext, samplePos, work);
uint8_t *pDepthBuffer, *pStencilBuffer;
SetupRenderBuffers(psContext.pColorBuffer, &pDepthBuffer, &pStencilBuffer, state.colorHottileEnable, renderBuffers);
AR_END(BESetup, 0);
psContext.vY.UL = _simd_add_ps(vULOffsetsY, _simd_set1_ps(static_cast<float>(y)));
psContext.vY.center = _simd_add_ps(vCenterOffsetsY, _simd_set1_ps(static_cast<float>(y)));
const simdscalar dy = _simd_set1_ps(static_cast<float>(SIMD_TILE_Y_DIM));
for (uint32_t yy = y; yy < y + KNOB_TILE_Y_DIM; yy += SIMD_TILE_Y_DIM)
{
psContext.vX.UL = _simd_add_ps(vULOffsetsX, _simd_set1_ps(static_cast<float>(x)));
psContext.vX.center = _simd_add_ps(vCenterOffsetsX, _simd_set1_ps(static_cast<float>(x)));
const simdscalar dx = _simd_set1_ps(static_cast<float>(SIMD_TILE_X_DIM));
for (uint32_t xx = x; xx < x + KNOB_TILE_X_DIM; xx += SIMD_TILE_X_DIM)
{
#if USE_8x2_TILE_BACKEND
const bool useAlternateOffset = ((xx & SIMD_TILE_X_DIM) != 0);
#endif
if (T::InputCoverage != SWR_INPUT_COVERAGE_NONE)
{
const uint64_t* pCoverageMask = (T::InputCoverage == SWR_INPUT_COVERAGE_INNER_CONSERVATIVE) ? &work.innerCoverageMask : &work.coverageMask[0];
generateInputCoverage<T, T::InputCoverage>(pCoverageMask, psContext.inputMask, state.blendState.sampleMask);
}
AR_BEGIN(BEBarycentric, pDC->drawId);
CalcPixelBarycentrics(coeffs, psContext);
CalcCentroid<T, false>(&psContext, samplePos, coeffs, work.coverageMask, state.blendState.sampleMask);
AR_END(BEBarycentric, 0);
for (uint32_t sample = 0; sample < T::MultisampleT::numSamples; sample++)
{
simdmask coverageMask = work.coverageMask[sample] & MASK;
if (coverageMask)
{
// offset depth/stencil buffers current sample
uint8_t *pDepthSample = pDepthBuffer + RasterTileDepthOffset(sample);
uint8_t *pStencilSample = pStencilBuffer + RasterTileStencilOffset(sample);
if (state.depthHottileEnable && state.depthBoundsState.depthBoundsTestEnable)
{
static_assert(KNOB_DEPTH_HOT_TILE_FORMAT == R32_FLOAT, "Unsupported depth hot tile format");
const simdscalar z = _simd_load_ps(reinterpret_cast<const float *>(pDepthSample));
const float minz = state.depthBoundsState.depthBoundsTestMinValue;
const float maxz = state.depthBoundsState.depthBoundsTestMaxValue;
coverageMask &= CalcDepthBoundsAcceptMask(z, minz, maxz);
}
AR_BEGIN(BEBarycentric, pDC->drawId);
// calculate per sample positions
psContext.vX.sample = _simd_add_ps(psContext.vX.UL, samplePos.vX(sample));
psContext.vY.sample = _simd_add_ps(psContext.vY.UL, samplePos.vY(sample));
CalcSampleBarycentrics(coeffs, psContext);
// interpolate and quantize z
psContext.vZ = vplaneps(coeffs.vZa, coeffs.vZb, coeffs.vZc, psContext.vI.sample, psContext.vJ.sample);
psContext.vZ = state.pfnQuantizeDepth(psContext.vZ);
AR_END(BEBarycentric, 0);
// interpolate user clip distance if available
if (state.backendState.clipDistanceMask)
{
coverageMask &= ~ComputeUserClipMask(state.backendState.clipDistanceMask, work.pUserClipBuffer, psContext.vI.sample, psContext.vJ.sample);
}
simdscalar vCoverageMask = _simd_vmask_ps(coverageMask);
simdscalar depthPassMask = vCoverageMask;
simdscalar stencilPassMask = vCoverageMask;
// Early-Z?
if (T::bCanEarlyZ)
{
AR_BEGIN(BEEarlyDepthTest, pDC->drawId);
depthPassMask = DepthStencilTest(&state, work.triFlags.frontFacing, work.triFlags.viewportIndex,
psContext.vZ, pDepthSample, vCoverageMask, pStencilSample, &stencilPassMask);
AR_EVENT(EarlyDepthStencilInfoSampleRate(_simd_movemask_ps(depthPassMask), _simd_movemask_ps(stencilPassMask), _simd_movemask_ps(vCoverageMask)));
AR_END(BEEarlyDepthTest, 0);
// early-exit if no samples passed depth or earlyZ is forced on.
if (state.psState.forceEarlyZ || !_simd_movemask_ps(depthPassMask))
{
DepthStencilWrite(&state.vp[work.triFlags.viewportIndex], &state.depthStencilState, work.triFlags.frontFacing, psContext.vZ,
pDepthSample, depthPassMask, vCoverageMask, pStencilSample, stencilPassMask);
if (!_simd_movemask_ps(depthPassMask))
{
work.coverageMask[sample] >>= (SIMD_TILE_Y_DIM * SIMD_TILE_X_DIM);
continue;
}
}
}
psContext.sampleIndex = sample;
psContext.activeMask = _simd_castps_si(vCoverageMask);
// execute pixel shader
AR_BEGIN(BEPixelShader, pDC->drawId);
UPDATE_STAT_BE(PsInvocations, _mm_popcnt_u32(_simd_movemask_ps(vCoverageMask)));
state.psState.pfnPixelShader(GetPrivateState(pDC), &psContext);
AR_END(BEPixelShader, 0);
vCoverageMask = _simd_castsi_ps(psContext.activeMask);
// late-Z
if (!T::bCanEarlyZ)
{
AR_BEGIN(BELateDepthTest, pDC->drawId);
depthPassMask = DepthStencilTest(&state, work.triFlags.frontFacing, work.triFlags.viewportIndex,
psContext.vZ, pDepthSample, vCoverageMask, pStencilSample, &stencilPassMask);
AR_EVENT(LateDepthStencilInfoSampleRate(_simd_movemask_ps(depthPassMask), _simd_movemask_ps(stencilPassMask), _simd_movemask_ps(vCoverageMask)));
AR_END(BELateDepthTest, 0);
if (!_simd_movemask_ps(depthPassMask))
{
// need to call depth/stencil write for stencil write
DepthStencilWrite(&state.vp[work.triFlags.viewportIndex], &state.depthStencilState, work.triFlags.frontFacing, psContext.vZ,
pDepthSample, depthPassMask, vCoverageMask, pStencilSample, stencilPassMask);
work.coverageMask[sample] >>= (SIMD_TILE_Y_DIM * SIMD_TILE_X_DIM);
continue;
}
}
uint32_t statMask = _simd_movemask_ps(depthPassMask);
uint32_t statCount = _mm_popcnt_u32(statMask);
UPDATE_STAT_BE(DepthPassCount, statCount);
// output merger
AR_BEGIN(BEOutputMerger, pDC->drawId);
#if USE_8x2_TILE_BACKEND
OutputMerger8x2(psContext, psContext.pColorBuffer, sample, &state.blendState, state.pfnBlendFunc, vCoverageMask, depthPassMask, state.psState.renderTargetMask, useAlternateOffset);
#else
OutputMerger4x2(psContext, psContext.pColorBuffer, sample, &state.blendState, state.pfnBlendFunc, vCoverageMask, depthPassMask, state.psState.renderTargetMask);
#endif
// do final depth write after all pixel kills
if (!state.psState.forceEarlyZ)
{
DepthStencilWrite(&state.vp[work.triFlags.viewportIndex], &state.depthStencilState, work.triFlags.frontFacing, psContext.vZ,
pDepthSample, depthPassMask, vCoverageMask, pStencilSample, stencilPassMask);
}
AR_END(BEOutputMerger, 0);
}
