dolphin/Source/Core/VideoCommon/RenderState.cpp
Stenzek 396b7c2978 OGL: Invalidate tracked state when calling ResetAPIState()
Due to the current design, any of the GL state can be mutated after
calling this function, so we can't assume that the tracked state will
match if we call SetPipeline() after ResetAPIState().
2019-01-25 11:10:49 +10:00

291 lines
7.8 KiB
C++

// Copyright 2016 Dolphin Emulator Project
// Licensed under GPLv2+
// Refer to the license.txt file included.
#include "VideoCommon/RenderState.h"
#include <algorithm>
#include <array>
#include "VideoCommon/SamplerCommon.h"
void RasterizationState::Generate(const BPMemory& bp, PrimitiveType primitive_type)
{
cullmode = bp.genMode.cullmode;
primitive = primitive_type;
// Back-face culling should be disabled for points/lines.
if (primitive_type != PrimitiveType::Triangles && primitive_type != PrimitiveType::TriangleStrip)
cullmode = GenMode::CULL_NONE;
}
RasterizationState& RasterizationState::operator=(const RasterizationState& rhs)
{
hex = rhs.hex;
return *this;
}
void DepthState::Generate(const BPMemory& bp)
{
testenable = bp.zmode.testenable.Value();
updateenable = bp.zmode.updateenable.Value();
func = bp.zmode.func.Value();
}
DepthState& DepthState::operator=(const DepthState& rhs)
{
hex = rhs.hex;
return *this;
}
// If the framebuffer format has no alpha channel, it is assumed to
// ONE on blending. As the backends may emulate this framebuffer
// configuration with an alpha channel, we just drop all references
// to the destination alpha channel.
static BlendMode::BlendFactor RemoveDstAlphaUsage(BlendMode::BlendFactor factor)
{
switch (factor)
{
case BlendMode::DSTALPHA:
return BlendMode::ONE;
case BlendMode::INVDSTALPHA:
return BlendMode::ZERO;
default:
return factor;
}
}
// We separate the blending parameter for rgb and alpha. For blending
// the alpha component, CLR and ALPHA are indentical. So just always
// use ALPHA as this makes it easier for the backends to use the second
// alpha value of dual source blending.
static BlendMode::BlendFactor RemoveSrcColorUsage(BlendMode::BlendFactor factor)
{
switch (factor)
{
case BlendMode::SRCCLR:
return BlendMode::SRCALPHA;
case BlendMode::INVSRCCLR:
return BlendMode::INVSRCALPHA;
default:
return factor;
}
}
// Same as RemoveSrcColorUsage, but because of the overlapping enum,
// this must be written as another function.
static BlendMode::BlendFactor RemoveDstColorUsage(BlendMode::BlendFactor factor)
{
switch (factor)
{
case BlendMode::DSTCLR:
return BlendMode::DSTALPHA;
case BlendMode::INVDSTCLR:
return BlendMode::INVDSTALPHA;
default:
return factor;
}
}
void BlendingState::Generate(const BPMemory& bp)
{
// Start with everything disabled.
hex = 0;
bool target_has_alpha = bp.zcontrol.pixel_format == PEControl::RGBA6_Z24;
bool alpha_test_may_success = bp.alpha_test.TestResult() != AlphaTest::FAIL;
colorupdate = bp.blendmode.colorupdate && alpha_test_may_success;
alphaupdate = bp.blendmode.alphaupdate && target_has_alpha && alpha_test_may_success;
dstalpha = bp.dstalpha.enable && alphaupdate;
usedualsrc = true;
// The subtract bit has the highest priority
if (bp.blendmode.subtract)
{
blendenable = true;
subtractAlpha = subtract = true;
srcfactoralpha = srcfactor = BlendMode::ONE;
dstfactoralpha = dstfactor = BlendMode::ONE;
if (dstalpha)
{
subtractAlpha = false;
srcfactoralpha = BlendMode::ONE;
dstfactoralpha = BlendMode::ZERO;
}
}
// The blendenable bit has the middle priority
else if (bp.blendmode.blendenable)
{
blendenable = true;
srcfactor = bp.blendmode.srcfactor;
dstfactor = bp.blendmode.dstfactor;
if (!target_has_alpha)
{
// uses ONE instead of DSTALPHA
srcfactor = RemoveDstAlphaUsage(srcfactor);
dstfactor = RemoveDstAlphaUsage(dstfactor);
}
// replaces SRCCLR with SRCALPHA and DSTCLR with DSTALPHA, it is important to
// use the dst function for the src factor and vice versa
srcfactoralpha = RemoveDstColorUsage(srcfactor);
dstfactoralpha = RemoveSrcColorUsage(dstfactor);
if (dstalpha)
{
srcfactoralpha = BlendMode::ONE;
dstfactoralpha = BlendMode::ZERO;
}
}
// The logicop bit has the lowest priority
else if (bp.blendmode.logicopenable)
{
if (bp.blendmode.logicmode == BlendMode::NOOP)
{
// Fast path for Kirby's Return to Dreamland, they use it with dstAlpha.
colorupdate = false;
alphaupdate = alphaupdate && dstalpha;
}
else
{
logicopenable = true;
logicmode = bp.blendmode.logicmode;
if (dstalpha)
{
// TODO: Not supported by backends.
}
}
}
}
BlendingState& BlendingState::operator=(const BlendingState& rhs)
{
hex = rhs.hex;
return *this;
}
void SamplerState::Generate(const BPMemory& bp, u32 index)
{
const FourTexUnits& tex = bpmem.tex[index / 4];
const TexMode0& tm0 = tex.texMode0[index % 4];
const TexMode1& tm1 = tex.texMode1[index % 4];
// GX can configure the mip filter to none. However, D3D and Vulkan can't express this in their
// sampler states. Therefore, we set the min/max LOD to zero if this option is used.
min_filter = (tm0.min_filter & 4) != 0 ? Filter::Linear : Filter::Point;
mipmap_filter = (tm0.min_filter & 3) == TexMode0::TEXF_LINEAR ? Filter::Linear : Filter::Point;
mag_filter = tm0.mag_filter != 0 ? Filter::Linear : Filter::Point;
// If mipmaps are disabled, clamp min/max lod
max_lod = SamplerCommon::AreBpTexMode0MipmapsEnabled(tm0) ? tm1.max_lod : 0;
min_lod = std::min(max_lod.Value(), static_cast<u64>(tm1.min_lod));
lod_bias = SamplerCommon::AreBpTexMode0MipmapsEnabled(tm0) ? tm0.lod_bias * (256 / 32) : 0;
// Address modes
static constexpr std::array<AddressMode, 4> address_modes = {
{AddressMode::Clamp, AddressMode::Repeat, AddressMode::MirroredRepeat, AddressMode::Repeat}};
wrap_u = address_modes[tm0.wrap_s];
wrap_v = address_modes[tm0.wrap_t];
anisotropic_filtering = 0;
}
SamplerState& SamplerState::operator=(const SamplerState& rhs)
{
hex = rhs.hex;
return *this;
}
namespace RenderState
{
RasterizationState GetInvalidRasterizationState()
{
RasterizationState state;
state.hex = UINT32_C(0xFFFFFFFF);
return state;
}
RasterizationState GetNoCullRasterizationState()
{
RasterizationState state = {};
state.cullmode = GenMode::CULL_NONE;
return state;
}
DepthState GetInvalidDepthState()
{
DepthState state;
state.hex = UINT32_C(0xFFFFFFFF);
return state;
}
DepthState GetNoDepthTestingDepthStencilState()
{
DepthState state = {};
state.testenable = false;
state.updateenable = false;
state.func = ZMode::ALWAYS;
return state;
}
BlendingState GetInvalidBlendingState()
{
BlendingState state;
state.hex = UINT32_C(0xFFFFFFFF);
return state;
}
BlendingState GetNoBlendingBlendState()
{
BlendingState state = {};
state.usedualsrc = false;
state.blendenable = false;
state.srcfactor = BlendMode::ONE;
state.srcfactoralpha = BlendMode::ONE;
state.dstfactor = BlendMode::ZERO;
state.dstfactoralpha = BlendMode::ZERO;
state.logicopenable = false;
state.colorupdate = true;
state.alphaupdate = true;
return state;
}
SamplerState GetInvalidSamplerState()
{
SamplerState state;
state.hex = UINT64_C(0xFFFFFFFFFFFFFFFF);
return state;
}
SamplerState GetPointSamplerState()
{
SamplerState state = {};
state.min_filter = SamplerState::Filter::Point;
state.mag_filter = SamplerState::Filter::Point;
state.mipmap_filter = SamplerState::Filter::Point;
state.wrap_u = SamplerState::AddressMode::Clamp;
state.wrap_v = SamplerState::AddressMode::Clamp;
state.min_lod = 0;
state.max_lod = 255;
state.lod_bias = 0;
state.anisotropic_filtering = false;
return state;
}
SamplerState GetLinearSamplerState()
{
SamplerState state = {};
state.min_filter = SamplerState::Filter::Linear;
state.mag_filter = SamplerState::Filter::Linear;
state.mipmap_filter = SamplerState::Filter::Linear;
state.wrap_u = SamplerState::AddressMode::Clamp;
state.wrap_v = SamplerState::AddressMode::Clamp;
state.min_lod = 0;
state.max_lod = 255;
state.lod_bias = 0;
state.anisotropic_filtering = false;
return state;
}
}