/*============================================================================== Copyright(c) 2017 Intel Corporation Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files(the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and / or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. ============================================================================*/ #include "Internal/Common/GmmLibInc.h" ///////////////////////////////////////////////////////////////////////////////////// /// Allocates the 2D mip layout for surface state programming. /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// @param[in] pRestrictions: ptr to surface alignment and size restrictions /// /// @return ::GMM_STATUS ///////////////////////////////////////////////////////////////////////////////////// GMM_STATUS GMM_STDCALL GmmLib::GmmGen7TextureCalc::FillTex2D(GMM_TEXTURE_INFO * pTexInfo, __GMM_BUFFER_TYPE *pRestrictions) { uint32_t Width, Height, BitsPerPixel; uint32_t HAlign, VAlign; uint32_t CompressHeight, CompressWidth, CompressDepth; uint32_t AlignedWidth, BlockHeight, ExpandedArraySize, Pitch; uint8_t Compress = 0; GMM_STATUS Status; __GMM_ASSERTPTR(pTexInfo, GMM_ERROR); __GMM_ASSERTPTR(pRestrictions, GMM_ERROR); GMM_DPF_ENTER; const GMM_PLATFORM_INFO *pPlatform = GMM_OVERRIDE_PLATFORM_INFO(pTexInfo, pGmmLibContext); BitsPerPixel = pTexInfo->BitsPerPixel; Height = pTexInfo->BaseHeight; Width = GFX_ULONG_CAST(pTexInfo->BaseWidth); pTexInfo->MSAA.NumSamples = GFX_MAX(pTexInfo->MSAA.NumSamples, 1); ExpandedArraySize = GFX_MAX(pTexInfo->ArraySize, 1) * ((pTexInfo->Type == RESOURCE_CUBE) ? 6 : 1) * // Cubemaps simply 6-element, 2D arrays. ((pTexInfo->Flags.Gpu.Depth || pTexInfo->Flags.Gpu.SeparateStencil) ? 1 : pTexInfo->MSAA.NumSamples); // Gen7 MSAA (non-Depth/Stencil) RT samples stored as array planes. // // Check for color separation // if(pTexInfo->Flags.Gpu.ColorSeparation || pTexInfo->Flags.Gpu.ColorSeparationRGBX) { bool csRestrictionsMet = (((ExpandedArraySize <= 2) && (ExpandedArraySize == pTexInfo->ArraySize) && ((pTexInfo->Format == GMM_FORMAT_R8G8B8A8_UNORM) || (pTexInfo->Format == GMM_FORMAT_R8G8B8A8_UNORM_SRGB) || (pTexInfo->Format == GMM_FORMAT_B8G8R8A8_UNORM) || (pTexInfo->Format == GMM_FORMAT_B8G8R8A8_UNORM_SRGB) || (pTexInfo->Format == GMM_FORMAT_B8G8R8X8_UNORM) || (pTexInfo->Format == GMM_FORMAT_B8G8R8X8_UNORM_SRGB)) && ((pTexInfo->Flags.Gpu.ColorSeparation && (Width % 16) == 0) || (pTexInfo->Flags.Gpu.ColorSeparationRGBX && (Width % 12) == 0)))); if(csRestrictionsMet) { ExpandedArraySize = GMM_COLOR_SEPARATION_ARRAY_SIZE; } else { pTexInfo->Flags.Gpu.ColorSeparation = 0; pTexInfo->Flags.Gpu.ColorSeparationRGBX = 0; } } HAlign = pTexInfo->Alignment.HAlign; VAlign = pTexInfo->Alignment.VAlign; GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); Compress = GmmIsCompressed(pGmmLibContext, pTexInfo->Format); ///////////////////////////////// // Calculate Block Surface Height ///////////////////////////////// // Adjust total height for arrayed 2D textures if(ExpandedArraySize > 1) { uint32_t Height0, Height1; Height0 = __GMM_EXPAND_HEIGHT(this, Height, VAlign, pTexInfo); // If not ARYSPC_LOD0-eligible... if((pTexInfo->MaxLod > 0) || pTexInfo->Flags.Gpu.Depth || // Depth/HiZ/Stencil buffers not ARYSPC_LOD0-compatible. pTexInfo->Flags.Gpu.HiZ || pTexInfo->Flags.Gpu.SeparateStencil) { Height1 = __GMM_EXPAND_HEIGHT(this, Height >> 1, VAlign, pTexInfo); // QPitch = (h0 + h1 + 12j) * pitch BlockHeight = Height0 + Height1 + 12 * VAlign; } else // SURFACE_STATE: Surface Array Spacing: ARYSPC_LOD0 { // QPitch = h0 * pitch BlockHeight = Height0; pTexInfo->Alignment.ArraySpacingSingleLod = true; } if(Compress) { BlockHeight /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { BlockHeight /= 2; } // Compute total array height BlockHeight *= ExpandedArraySize; } else { BlockHeight = Get2DMipMapHeight(pTexInfo); } /////////////////////////////////// // Calculate Pitch /////////////////////////////////// AlignedWidth = __GMM_EXPAND_WIDTH(this, Width, HAlign, pTexInfo); // Calculate special pitch case of small dimensions where LOD1 + LOD2 widths are greater // than LOD0. e.g. dimensions 4x4 and MinPitch == 1 if(pTexInfo->MaxLod >= 2) { uint32_t AlignedWidthLod1, AlignedWidthLod2; AlignedWidthLod1 = __GMM_EXPAND_WIDTH(this, Width >> 1, HAlign, pTexInfo); AlignedWidthLod2 = __GMM_EXPAND_WIDTH(this, Width >> 2, HAlign, pTexInfo); AlignedWidth = GFX_MAX(AlignedWidth, AlignedWidthLod1 + AlignedWidthLod2); } if(Compress) { AlignedWidth /= CompressWidth; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { AlignedWidth *= 2; } else if(pTexInfo->Flags.Gpu.ColorSeparation) { AlignedWidth *= pTexInfo->ArraySize; __GMM_ASSERT(0 == (AlignedWidth % GMM_COLOR_SEPARATION_WIDTH_DIVISION)); AlignedWidth /= GMM_COLOR_SEPARATION_WIDTH_DIVISION; } else if(pTexInfo->Flags.Gpu.ColorSeparationRGBX) { AlignedWidth *= pTexInfo->ArraySize; __GMM_ASSERT(0 == (AlignedWidth % GMM_COLOR_SEPARATION_RGBX_WIDTH_DIVISION)); AlignedWidth /= GMM_COLOR_SEPARATION_RGBX_WIDTH_DIVISION; } // Default pitch Pitch = AlignedWidth * BitsPerPixel >> 3; // Make sure the pitch satisfy linear min pitch requirment Pitch = GFX_MAX(Pitch, pRestrictions->MinPitch); // Make sure pitch satisfy alignment restriction Pitch = GFX_ALIGN(Pitch, pRestrictions->PitchAlignment); //////////////////// // Adjust for Tiling //////////////////// if(GMM_IS_TILED(pPlatform->TileInfo[pTexInfo->TileMode])) { Pitch = GFX_ALIGN(Pitch, pPlatform->TileInfo[pTexInfo->TileMode].LogicalTileWidth); BlockHeight = GFX_ALIGN(BlockHeight, pPlatform->TileInfo[pTexInfo->TileMode].LogicalTileHeight); // If Tiled Resource or Undefined64KBSwizzle resource, align to 64KB tile size if((pTexInfo->Flags.Gpu.TiledResource || pTexInfo->Flags.Info.Undefined64KBSwizzle) && (pTexInfo->Flags.Info.TiledY)) { uint32_t ColFactor = 0, RowFactor = 0; uint32_t TRTileWidth = 0, TRTileHeight = 0; GmmGetD3DToHwTileConversion(pTexInfo, &ColFactor, &RowFactor); TRTileWidth = pPlatform->TileInfo[pTexInfo->TileMode].LogicalTileWidth * ColFactor; TRTileHeight = pPlatform->TileInfo[pTexInfo->TileMode].LogicalTileHeight * RowFactor; Pitch = GFX_ALIGN(Pitch, TRTileWidth); BlockHeight = GFX_ALIGN(BlockHeight, TRTileHeight); } } GMM_ASSERTDPF(pTexInfo->Flags.Info.LayoutBelow || !pTexInfo->Flags.Info.LayoutRight, "MIPLAYOUT_RIGHT not supported after Gen6!"); pTexInfo->Flags.Info.LayoutBelow = 1; pTexInfo->Flags.Info.LayoutRight = 0; // If a texture is YUV packed, 96, or 48 bpp then one row plus 16 bytes of // padding needs to be added. Since this will create a none pitch aligned // surface the padding is aligned to the next row if(GmmIsYUVPacked(pTexInfo->Format) || (pTexInfo->BitsPerPixel == GMM_BITS(96)) || (pTexInfo->BitsPerPixel == GMM_BITS(48))) { BlockHeight += GMM_SCANLINES(1) + GFX_CEIL_DIV(GMM_BYTES(16), Pitch); } // Align height to even row to cover for HW over - fetch BlockHeight = GFX_ALIGN(BlockHeight, __GMM_EVEN_ROW); if((Status = // <-- Note assignment. FillTexPitchAndSize( pTexInfo, Pitch, BlockHeight, pRestrictions)) == GMM_SUCCESS) { Fill2DTexOffsetAddress(pTexInfo); // Init to no-packed mips. It'll be initialized when app calls to get packed // mips. Calculate packed mips here if there's a chance apps won't call to // get packed mips. pTexInfo->Alignment.PackedMipStartLod = GMM_TILED_RESOURCE_NO_PACKED_MIPS; } GMM_DPF_EXIT; return (Status); } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates the mip offset of given LOD in 2D mip layout /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// /// @return offset value in bytes ///////////////////////////////////////////////////////////////////////////////////// GMM_GFX_SIZE_T GmmLib::GmmGen7TextureCalc::Get2DTexOffsetAddressPerMip(GMM_TEXTURE_INFO *pTexInfo, uint32_t MipLevel) { GMM_GFX_SIZE_T MipOffset; uint32_t AlignedMipHeight, i, MipHeight, OffsetHeight; uint32_t HAlign, VAlign; uint32_t CompressHeight, CompressWidth, CompressDepth; uint8_t Compress; __GMM_ASSERTPTR(pTexInfo, GMM_ERROR); GMM_DPF_ENTER; const GMM_PLATFORM_INFO *pPlatform = GMM_OVERRIDE_PLATFORM_INFO(pTexInfo, pGmmLibContext); HAlign = pTexInfo->Alignment.HAlign; VAlign = pTexInfo->Alignment.VAlign; GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); Compress = GmmIsCompressed(pGmmLibContext, pTexInfo->Format); MipHeight = pTexInfo->BaseHeight; OffsetHeight = 0; // Mips 0 and 1 are on the left edge... if(MipLevel < 2) { MipOffset = 0; } else // Mip2 and beyond are to the right of Mip1... { uint32_t Mip1Width = GFX_ULONG_CAST(pTexInfo->BaseWidth) >> 1; Mip1Width = __GMM_EXPAND_WIDTH(this, Mip1Width, HAlign, pTexInfo); if(Compress) { Mip1Width /= CompressWidth; if((pGmmLibContext->GetWaTable().WaAstcCorruptionForOddCompressedBlockSizeX || pTexInfo->Flags.Wa.CHVAstcSkipVirtualMips) && pPlatform->FormatTable[pTexInfo->Format].ASTC && CompressWidth == 5) { uint32_t Width1 = (pTexInfo->BaseWidth == 1) ? 1 : (GFX_ULONG_CAST(pTexInfo->BaseWidth) >> 1); uint32_t Modulo10 = Width1 % 10; if(Modulo10 >= 1 && Modulo10 <= CompressWidth) { Mip1Width += 3; } } } else if(pTexInfo->Flags.Gpu.SeparateStencil) { Mip1Width *= 2; } MipOffset = (GMM_GFX_SIZE_T)Mip1Width * pTexInfo->BitsPerPixel >> 3; } for(i = 1; i <= MipLevel; i++) { AlignedMipHeight = GFX_ULONG_CAST(__GMM_EXPAND_HEIGHT(this, MipHeight, VAlign, pTexInfo)); if(Compress) { AlignedMipHeight /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { AlignedMipHeight /= 2; } OffsetHeight += ((i != 2) ? AlignedMipHeight : 0); MipHeight >>= 1; } MipOffset += OffsetHeight * GFX_ULONG_CAST(pTexInfo->Pitch); GMM_DPF_EXIT; return (MipOffset); } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates height of the 2D mip layout /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// /// @return Height of 2D mip layout ///////////////////////////////////////////////////////////////////////////////////// uint32_t GmmLib::GmmGen7TextureCalc::Get2DMipMapHeight(GMM_TEXTURE_INFO *pTexInfo) { uint32_t Height, BlockHeight, NumLevels; // Final height for 2D surface uint32_t HeightLines, HeightLinesLevel0, HeightLinesLevel1, HeightLinesLevel2; uint32_t VAlign, CompressHeight, CompressWidth, CompressDepth; uint32_t i; uint8_t Compress; GMM_DPF_ENTER; const GMM_PLATFORM_INFO *pPlatform = GMM_OVERRIDE_PLATFORM_INFO(pTexInfo, pGmmLibContext); // Mip 0 height is needed later Height = pTexInfo->BaseHeight; Compress = GmmIsCompressed(pGmmLibContext, pTexInfo->Format); NumLevels = pTexInfo->MaxLod; HeightLines = Height; VAlign = pTexInfo->Alignment.VAlign; GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); HeightLinesLevel0 = __GMM_EXPAND_HEIGHT(this, HeightLines, VAlign, pTexInfo); if(Compress) { HeightLinesLevel0 /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { HeightLinesLevel0 /= 2; } // Start out with mip0 BlockHeight = HeightLinesLevel0; // Height of mip1 and height of all others mips(2,3,4,5,,) needed later HeightLinesLevel1 = HeightLinesLevel2 = 0; for(i = 1; i <= NumLevels; i++) { uint32_t AlignedHeightLines; HeightLines >>= 1; AlignedHeightLines = __GMM_EXPAND_HEIGHT(this, HeightLines, VAlign, pTexInfo); if(Compress) { AlignedHeightLines /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { AlignedHeightLines /= 2; } if(i == 1) { HeightLinesLevel1 = AlignedHeightLines; } else { HeightLinesLevel2 += AlignedHeightLines; } } // If mip1 height covers all others then that is all we need if(HeightLinesLevel1 >= HeightLinesLevel2) { BlockHeight += GFX_ALIGN_NP2(HeightLinesLevel1, VAlign); } else { BlockHeight += GFX_ALIGN_NP2(HeightLinesLevel2, VAlign); } GMM_DPF_EXIT; return (BlockHeight); } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates the address offset for each mip map of 2D texture and store them /// into the GMM_TEXTURE_INFO for surf state programming. /// /// @param[in] pTexInfo: pointer to ::GMM_TEXTURE_INFO /// ///////////////////////////////////////////////////////////////////////////////////// void GmmLib::GmmGen7TextureCalc::Fill2DTexOffsetAddress(GMM_TEXTURE_INFO *pTexInfo) { uint32_t i; __GMM_ASSERTPTR(pTexInfo, VOIDRETURN); GMM_DPF_ENTER; // QPitch: Array Element-to-Element, or Cube Face-to-Face Pitch... // ------------------------------------------------------------------------- // Note: Gen7 MSAA RT samples stored as contiguous array planes-- // e.g. MSAA-4X'ed array elements A and B stored: A0 A1 A2 A3 B0 B1 B2 B3. // However, for GMM's purposes QPitch is still the distance between // elements--not the distance between samples. // ------------------------------------------------------------------------- if((pTexInfo->ArraySize <= 1) && (pTexInfo->Type != RESOURCE_CUBE) && !(pTexInfo->Flags.Gpu.ColorSeparation || pTexInfo->Flags.Gpu.ColorSeparationRGBX)) { pTexInfo->OffsetInfo.Texture2DOffsetInfo.ArrayQPitchRender = 0; pTexInfo->OffsetInfo.Texture2DOffsetInfo.ArrayQPitchLock = 0; } else { uint32_t Height, Height0, Height1, ArrayQPitch, VAlign; Height = pTexInfo->BaseHeight; VAlign = pTexInfo->Alignment.VAlign; Height0 = __GMM_EXPAND_HEIGHT(this, Height, VAlign, pTexInfo); Height1 = __GMM_EXPAND_HEIGHT(this, Height >> 1, VAlign, pTexInfo); if(!pTexInfo->Alignment.ArraySpacingSingleLod) { // QPitch = (h0 + h1 + 12j) * pitch ArrayQPitch = Height0 + Height1 + 12 * VAlign; } else // SURFACE_STATE: Surface Array Spacing: ARYSPC_LOD0 { // QPitch = h0 * pitch ArrayQPitch = Height0; } if(GmmIsCompressed(pGmmLibContext, pTexInfo->Format)) { uint32_t CompressHeight, CompressWidth, CompressDepth; GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); ArrayQPitch /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { ArrayQPitch /= 2; } if((pTexInfo->MSAA.NumSamples > 1) && !(pTexInfo->Flags.Gpu.Depth || pTexInfo->Flags.Gpu.SeparateStencil)) { // Gen7 MSAA (non-Depth/Stencil) RT samples stored as array planes; // QPitch still element-to-element, not sample-to-sample. ArrayQPitch *= pTexInfo->MSAA.NumSamples; } pTexInfo->OffsetInfo.Texture2DOffsetInfo.ArrayQPitchRender = ArrayQPitch * pTexInfo->Pitch; pTexInfo->OffsetInfo.Texture2DOffsetInfo.ArrayQPitchLock = ArrayQPitch * pTexInfo->Pitch; } for(i = 0; i <= pTexInfo->MaxLod; i++) { pTexInfo->OffsetInfo.Texture2DOffsetInfo.Offset[i] = Get2DTexOffsetAddressPerMip(pTexInfo, i); } GMM_DPF_EXIT; } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates total height of an arrayed 3D mip layout /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// /// @return height of arrayed 3D mip layout ///////////////////////////////////////////////////////////////////////////////////// uint32_t GmmLib::GmmGen7TextureCalc::GetTotal3DHeight(GMM_TEXTURE_INFO *pTexInfo) { uint32_t AlignedHeight, BlockHeight, Depth; uint8_t Compressed; uint32_t i, MipsInThisRow, MipLevel, MipRows; uint32_t Total3DHeight = 0, UnitAlignHeight; uint32_t CompressHeight, CompressWidth, CompressDepth; GMM_TEXTURE_CALC *pTextureCalc; GMM_DPF_ENTER; pTextureCalc = GMM_OVERRIDE_TEXTURE_CALC(pTexInfo, pGmmLibContext); BlockHeight = pTexInfo->BaseHeight; Depth = pTexInfo->Depth; MipLevel = pTexInfo->MaxLod; UnitAlignHeight = pTexInfo->Alignment.VAlign; Compressed = GmmIsCompressed(pGmmLibContext, pTexInfo->Format); pTextureCalc->GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); // All mip0s of all planes are stacked together, then mip1s and so on... for(i = 0; i <= MipLevel; i++) { BlockHeight = GFX_MAX(BlockHeight, UnitAlignHeight); AlignedHeight = GFX_ALIGN(BlockHeight, UnitAlignHeight); if(Compressed) { AlignedHeight /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { AlignedHeight /= 2; } else if(pTexInfo->Flags.Gpu.CCS) { if(pTexInfo->Flags.Gpu.__NonMsaaTileYCcs) { AlignedHeight /= 32; } else if(pTexInfo->Flags.Gpu.__NonMsaaTileXCcs) { AlignedHeight /= 16; } } // See how many mip can fit in one row MipsInThisRow = GFX_2_TO_POWER_OF(i); // calculate if the mips will spill over to multiple rows MipRows = GFX_CEIL_DIV(GFX_MAX(1, Depth >> i), MipsInThisRow); Total3DHeight += MipRows * AlignedHeight; // next level height BlockHeight >>= 1; } GMM_DPF_EXIT; return Total3DHeight; } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates the address offset for each mip map of 3D texture and store them /// into the GMM_TEXTURE_INFO for surf state programming. /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// ///////////////////////////////////////////////////////////////////////////////////// void GmmLib::GmmGen7TextureCalc::Fill3DTexOffsetAddress(GMM_TEXTURE_INFO *pTexInfo) { uint32_t AlignedMipHeight, AlignedMipWidth; uint32_t i, Depth; uint32_t MipsInThisRow, MipLevel, MipRows; uint32_t MipHeight, MipWidth; uint32_t UnitAlignHeight, UnitAlignWidth; uint32_t CompressHeight, CompressWidth, CompressDepth; uint32_t OffsetMipRows = 0; GMM_GFX_SIZE_T OffsetValue; uint8_t Compress; GMM_TEXTURE_CALC *pTextureCalc; __GMM_ASSERT(pTexInfo); pTextureCalc = GMM_OVERRIDE_TEXTURE_CALC(pTexInfo, pGmmLibContext); // Assign directly to unaligned MipMap dimension variables // There isn't a need to save original dimensions MipWidth = GFX_ULONG_CAST(pTexInfo->BaseWidth); MipHeight = pTexInfo->BaseHeight; // Align before we compress UnitAlignWidth = pTexInfo->Alignment.HAlign; UnitAlignHeight = pTexInfo->Alignment.VAlign; Compress = GmmIsCompressed(pGmmLibContext, pTexInfo->Format); pTextureCalc->GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); // Aligned MipMap Dimensions AlignedMipWidth = GFX_ALIGN(MipWidth, UnitAlignWidth); AlignedMipHeight = GFX_ALIGN(MipHeight, UnitAlignHeight); Depth = pTexInfo->Depth; MipLevel = pTexInfo->MaxLod; // Start with base offset OffsetValue = 0; // calculate the offset for each Mip level for(i = 0; i <= MipLevel; i++) { // store the value in blockdesc if(Compress) { // If there is compression, compress after the alignment at each level AlignedMipWidth /= CompressWidth; AlignedMipHeight /= CompressHeight; } else if(pTexInfo->Flags.Gpu.SeparateStencil) { AlignedMipWidth *= 2; AlignedMipHeight /= 2; } else if(pTexInfo->Flags.Gpu.CCS) { if(pTexInfo->Flags.Gpu.__NonMsaaTileYCcs) { switch(pTexInfo->BitsPerPixel) { case 32: AlignedMipWidth /= 8; break; case 64: AlignedMipWidth /= 4; break; case 128: AlignedMipWidth /= 2; break; default: __GMM_ASSERT(0); } AlignedMipHeight /= 32; } else if(pTexInfo->Flags.Gpu.__NonMsaaTileXCcs) { switch(pTexInfo->BitsPerPixel) { case 32: AlignedMipWidth /= 16; break; case 64: AlignedMipWidth /= 8; break; case 128: AlignedMipWidth /= 4; break; default: __GMM_ASSERT(0); } AlignedMipHeight /= 16; } } pTexInfo->OffsetInfo.Texture3DOffsetInfo.Offset[i] = OffsetValue; // See how many mip can fit in one row MipsInThisRow = GFX_2_TO_POWER_OF(i); // Slice pitch for LOD0 if(MipsInThisRow == 1) { pTexInfo->OffsetInfo.Texture3DOffsetInfo.Mip0SlicePitch = AlignedMipHeight * pTexInfo->Pitch; } // calculate if the mips will spill over to multiple rows MipRows = GFX_CEIL_DIV(GFX_MAX(1, Depth >> i), MipsInThisRow); // Offset in terms of height OffsetMipRows += MipRows * AlignedMipHeight; // For a particular mip This is offset of a base slice (i.e. Slice 0) OffsetValue = OffsetMipRows * pTexInfo->Pitch; // next level height MipHeight >>= 1; // Clamp such that mip height is at least1 MipHeight = GFX_MAX(MipHeight, 1); AlignedMipHeight = GFX_ALIGN(MipHeight, UnitAlignHeight); MipWidth >>= 1; // Clamp such that mip width is at least 1 MipWidth = GFX_MAX(MipWidth, 1); AlignedMipWidth = GFX_ALIGN(MipWidth, UnitAlignWidth); } } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates the 3D offset and QPitch for surface state programming. /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// @param[in] pRestrictions: ptr to surface alignment and size restrictions /// /// @return ::GMM_STATUS ///////////////////////////////////////////////////////////////////////////////////// GMM_STATUS GMM_STDCALL GmmLib::GmmGen7TextureCalc::FillTex3D(GMM_TEXTURE_INFO * pTexInfo, __GMM_BUFFER_TYPE *pRestrictions) { uint32_t AlignedMipWidth; uint32_t BitsPerPixel; uint32_t Depth, Height, Width; uint32_t i, MipsInThisRow, MipWidth; uint32_t RenderPitch = 0, ThisRowPitch; uint32_t UnitAlignWidth; uint32_t Total3DHeight; uint32_t WidthBytesPhysical; uint8_t Compress; uint32_t CompressHeight, CompressWidth, CompressDepth; bool SeparateStencil; GMM_STATUS Status; GMM_DPF_ENTER; __GMM_ASSERTPTR(pTexInfo, GMM_ERROR); __GMM_ASSERTPTR(pRestrictions, GMM_ERROR); const __GMM_PLATFORM_RESOURCE *pPlatformResource = GMM_OVERRIDE_PLATFORM_INFO(pTexInfo, pGmmLibContext); BitsPerPixel = pTexInfo->BitsPerPixel; Height = pTexInfo->BaseHeight; Width = GFX_ULONG_CAST(pTexInfo->BaseWidth); Depth = pTexInfo->Depth; // Align before we compress UnitAlignWidth = pTexInfo->Alignment.HAlign; Compress = GmmIsCompressed(pGmmLibContext, pTexInfo->Format); GetCompressionBlockDimensions(pTexInfo->Format, &CompressWidth, &CompressHeight, &CompressDepth); SeparateStencil = pTexInfo->Flags.Gpu.SeparateStencil ? true : false; // Unaligned MipMap dimension variables MipWidth = Width; // Aligned MipMap dimension variables AlignedMipWidth = GFX_ALIGN(MipWidth, UnitAlignWidth); // Calculate the render pitch exactly the same way we do the // offset for each Mip level for(i = 0; i <= pTexInfo->MaxLod; i++) { if(Compress) { // If there is compression, compress after the alignment at each level AlignedMipWidth /= CompressWidth; } else if(SeparateStencil) { AlignedMipWidth *= 2; } else if(pTexInfo->Flags.Gpu.CCS) { if(pTexInfo->Flags.Gpu.__NonMsaaTileYCcs) { switch(BitsPerPixel) { case 32: AlignedMipWidth /= 8; break; case 64: AlignedMipWidth /= 4; break; case 128: AlignedMipWidth /= 2; break; default: __GMM_ASSERT(0); } } else if(pTexInfo->Flags.Gpu.__NonMsaaTileXCcs) { switch(BitsPerPixel) { case 32: AlignedMipWidth /= 16; break; case 64: AlignedMipWidth /= 8; break; case 128: AlignedMipWidth /= 4; break; default: __GMM_ASSERT(0); } } } // See how many mip can fit in one row MipsInThisRow = GFX_2_TO_POWER_OF(i); // LOD planes may be less than MipsInThisRow, take the smaller value for pitch MipsInThisRow = GFX_MIN(GFX_MAX(1, (Depth >> i)), MipsInThisRow); ThisRowPitch = AlignedMipWidth * MipsInThisRow; // Default pitch WidthBytesPhysical = ThisRowPitch * BitsPerPixel >> 3; if(RenderPitch < WidthBytesPhysical) { RenderPitch = WidthBytesPhysical; } MipWidth >>= 1; // Clamp such that mip width is at least 1 MipWidth = GFX_MAX(MipWidth, 1); AlignedMipWidth = GFX_ALIGN(MipWidth, UnitAlignWidth); } WidthBytesPhysical = RenderPitch; // Make sure the pitch satisfy linear min pitch requirment WidthBytesPhysical = GFX_MAX(WidthBytesPhysical, pRestrictions->MinPitch); // Make sure pitch satisfy alignment restriction WidthBytesPhysical = GFX_ALIGN(WidthBytesPhysical, pRestrictions->PitchAlignment); // Get Total height for the entire 3D texture Total3DHeight = GetTotal3DHeight(pTexInfo); if(GMM_IS_TILED(pPlatformResource->TileInfo[pTexInfo->TileMode])) { // Align to tile boundary Total3DHeight = GFX_ALIGN(Total3DHeight, pPlatformResource->TileInfo[pTexInfo->TileMode].LogicalTileHeight); WidthBytesPhysical = GFX_ALIGN(WidthBytesPhysical, pPlatformResource->TileInfo[pTexInfo->TileMode].LogicalTileWidth); } // If a texture is YUV packed, 96, or 48 bpp then one row plus 16 bytes of // padding needs to be added. Since this will create a none pitch aligned // surface the padding is aligned to the next row if(GmmIsYUVPacked(pTexInfo->Format) || (pTexInfo->BitsPerPixel == GMM_BITS(96)) || (pTexInfo->BitsPerPixel == GMM_BITS(48))) { Total3DHeight += GMM_SCANLINES(1) + GFX_CEIL_DIV(GMM_BYTES(16), WidthBytesPhysical); } Total3DHeight = GFX_ALIGN(Total3DHeight, __GMM_EVEN_ROW); if((Status = // <-- Note assignment. FillTexPitchAndSize( pTexInfo, WidthBytesPhysical, Total3DHeight, pRestrictions)) == GMM_SUCCESS) { Fill3DTexOffsetAddress(pTexInfo); } GMM_DPF_EXIT; return (Status); } ///////////////////////////////////////////////////////////////////////////////////// /// Allocates the 1D mip layout for surface state programming. /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// @param[in] pRestrictions: ptr to surface alignment and size restrictions /// /// @return ::GMM_STATUS ///////////////////////////////////////////////////////////////////////////////////// GMM_STATUS GMM_STDCALL GmmLib::GmmGen7TextureCalc::FillTex1D(GMM_TEXTURE_INFO * pTexInfo, __GMM_BUFFER_TYPE *pRestrictions) { return FillTex2D(pTexInfo, pRestrictions); } ///////////////////////////////////////////////////////////////////////////////////// /// Calculates the cube layout for surface state programming. /// /// @param[in] pTexInfo: ptr to ::GMM_TEXTURE_INFO, /// @param[in] pRestrictions: ptr to surface alignment and size restrictions /// /// @return ::GMM_STATUS ///////////////////////////////////////////////////////////////////////////////////// GMM_STATUS GMM_STDCALL GmmLib::GmmGen7TextureCalc::FillTexCube(GMM_TEXTURE_INFO * pTexInfo, __GMM_BUFFER_TYPE *pRestrictions) { return FillTex2D(pTexInfo, pRestrictions); }