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291 lines
9.2 KiB
C++
291 lines
9.2 KiB
C++
// Copyright 2019 Dolphin Emulator Project
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// Licensed under GPLv2+
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// Refer to the license.txt file included.
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#include "VideoCommon/TMEM.h"
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#include <array>
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#include "Common/ChunkFile.h"
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#include "VideoCommon/BPMemory.h"
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////////////////////////////////////////////////////////////////////////////////////////////////////
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//
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// TMEM emulation tracks which textures should be cached in TMEM on a real console.
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// There are two good reasons to do this:
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//
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// 1. Some games deliberately avoid invalidating a texture, overwrite it with an EFB copy,
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// and then expect the original texture to still be found in TMEM for another draw call.
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// Spyro: A Hero's Tail is known for using such overwritten textures.
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// However, other games like:
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// * Sonic Riders
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// * Metal Arms: Glitch in the System
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// * Godzilla: Destroy All Monsters Melee
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// * NHL Slapshot
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// * Tak and the Power of Juju
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// * Night at the Museum: Battle of the Smithsonian
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// * 428: Fūsa Sareta Shibuya de
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// are known to (accidentally or deliberately) avoid invalidating and then expect the pattern
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// of the draw and the fact that the whole texture doesn't fit in TMEM to self-invalidate the
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// texture. These are usually full-screen efb copies.
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// So we must track the size of the textures as an heuristic to see if they will self-invalidate
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// or not.
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//
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// 2. It actually improves Dolphin's performance in safer texture hashing modes, by reducing the
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// amount of times a texture needs to be hashed when reused in subsequent draws.
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//
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// As a side-effect, TMEM emulation also tracks if the texture unit configuration has changed at
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// all, which Dolphin's TextureCache takes advantage of.
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//
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////////////////////////////////////////////////////////////////////////////////////////////////////
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//
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// Checking if a texture fits in TMEM or not is complicated by the fact that Flipper's TMEM is quite
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// configurable.
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// Each of the eight texture units has two banks (even and odd) that can be pointed at any offset
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// and set to any size. It is completely valid to have overlapping banks, and performance can be
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// improved by overlapping the caches of texture units that are drawing the same textures.
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//
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// For trilinear textures, the even/odd banks contain the even/odd LODs of the texture. TMEM has two
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// banks of 512KB each, covering the upper and lower halves of TMEM's address space. The two banks
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// be accessed simultaneously, allowing a trilinear texture sample to be completed at the same cost
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// as a bilinear sample, assuming the even and odd banks are mapped onto different banks.
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//
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// 32bit textures are actually stored as two 16bit textures in separate banks, allowing a bilinear
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// sample of a 32bit texture at the same cost as a 16bit bilinear/trilinear sample. A trilinear
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// sample of a 32bit texture costs more.
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//
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// TODO: I'm not sure if it's valid for a texture unit's even and odd banks to overlap. There might
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// actually be a hard requirement for even and odd banks to live in different banks of TMEM.
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//
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// Note: This is still very much a heuristic.
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// Actually knowing if a texture is partially or fully cached within TMEM would require
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// extensive software rasterization, or sampler feedback from a hardware backend.
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//
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////////////////////////////////////////////////////////////////////////////////////////////////////
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namespace TMEM
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{
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struct TextureUnitState
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{
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enum class State
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{
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// Cache is invalid. Configuration has changed
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INVALID,
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// Valid, but not cached due to either being too big, or overlapping with another texture unit
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VALID,
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// Texture unit has cached all of the previous draw
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CACHED,
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};
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struct BankConfig
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{
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u32 width = 0;
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u32 height = 0;
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u32 base = 0;
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u32 size = 0;
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bool Overlaps(const BankConfig& other) const;
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};
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BankConfig even = {};
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BankConfig odd = {};
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State state = State::INVALID;
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bool Overlaps(const TextureUnitState& other) const;
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};
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static u32 CalculateUnitSize(TextureUnitState::BankConfig bank_config);
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static std::array<TextureUnitState, 8> s_unit;
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// On TMEM configuration changed:
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// 1. invalidate stage.
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void ConfigurationChanged(TexUnitAddress bp_addr, u32 config)
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{
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TextureUnitState& unit_state = s_unit[bp_addr.GetUnitID()];
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// If anything has changed, we can't assume existing state is still valid.
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unit_state.state = TextureUnitState::State::INVALID;
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// Note: BPStructs has already filtered out NOP changes before calling us
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switch (bp_addr.Reg)
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{
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case TexUnitAddress::Register::SETIMAGE1:
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{
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// Image Type and Even bank's Cache Height, Cache Width, TMEM Offset
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TexImage1 even = {.hex = config};
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unit_state.even = {even.cache_width, even.cache_height, even.tmem_even << 5, 0};
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break;
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}
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case TexUnitAddress::Register::SETIMAGE2:
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{
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// Odd bank's Cache Height, Cache Width, TMEM Offset
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TexImage2 odd = {.hex = config};
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unit_state.odd = {odd.cache_width, odd.cache_height, odd.tmem_odd << 5, 0};
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break;
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}
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default:
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// Something else has changed
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return;
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}
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}
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void InvalidateAll()
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{
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for (auto& unit : s_unit)
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{
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unit.state = TextureUnitState::State::INVALID;
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}
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}
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// On invalidate cache:
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// 1. invalidate all texture units.
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void Invalidate([[maybe_unused]] u32 param)
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{
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// The exact arguments of Invalidate commands is currently unknown.
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// It appears to contain the TMEM address and a size.
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// For simplicity, we will just invalidate everything
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InvalidateAll();
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}
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// On bind:
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// 1. use mipmapping/32bit status to calculate final sizes
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// 2. if texture size is small enough to fit in region mark as cached.
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// otherwise, mark as valid
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void Bind(u32 unit, int width, int height, bool is_mipmapped, bool is_32_bit)
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{
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TextureUnitState& unit_state = s_unit[unit];
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// All textures use the even bank.
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// It holds the level 0 mipmap (and other even mipmap LODs, if mipmapping is enabled)
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unit_state.even.size = CalculateUnitSize(unit_state.even);
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bool fits = (width * height * 32U) <= unit_state.even.size;
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if (is_mipmapped || is_32_bit)
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{
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// And the odd bank is enabled when either mipmapping is enabled or the texture is 32 bit
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// It holds the Alpha and Red channels of 32 bit textures or the odd layers of a mipmapped
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// texture
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unit_state.odd.size = CalculateUnitSize(unit_state.odd);
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fits = fits && (width * height * 32U) <= unit_state.odd.size;
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}
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else
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{
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unit_state.odd.size = 0;
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}
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if (is_mipmapped)
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{
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// TODO: This is what games appear to expect from hardware. But seems odd, as it doesn't line up
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// with how much extra memory is required for mipmapping, just 33% more.
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// Hardware testing is required to see exactly what gets used.
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// When mipmapping is enabled, the even bank is doubled in size
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// The extended region holds the remaining even mipmap layers
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unit_state.even.size *= 2;
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if (is_32_bit)
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{
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// When a 32bit texture is mipmapped, the odd bank is also doubled in size
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unit_state.odd.size *= 2;
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}
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}
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unit_state.state = fits ? TextureUnitState::State::CACHED : TextureUnitState::State::VALID;
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}
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static u32 CalculateUnitSize(TextureUnitState::BankConfig bank_config)
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{
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u32 width = bank_config.width;
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u32 height = bank_config.height;
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// These are the only cache sizes supported by the sdk
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if (width == height)
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{
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switch (width)
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{
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case 3: // 32KB
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return 32 * 1024;
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case 4: // 128KB
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return 128 * 1024;
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case 5: // 512KB
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return 512 * 1024;
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default:
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break;
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}
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}
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// However, the registers allow a much larger amount of configurablity.
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// Maybe other sizes are broken?
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// Until hardware tests are done, this is a guess at the size algorithm
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return 512 * (1 << width) * (1 << height);
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}
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bool TextureUnitState::BankConfig::Overlaps(const BankConfig& other) const
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{
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if (size == 0 || other.size == 0)
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return false;
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return (base <= other.base && (base + size) > other.base) ||
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(other.base <= base && (other.base + other.size) > base);
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}
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bool TextureUnitState::Overlaps(const TextureUnitState& other) const
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{
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if (state == TextureUnitState::State::INVALID || other.state == TextureUnitState::State::INVALID)
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return false;
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return even.Overlaps(other.even) || even.Overlaps(other.odd) || odd.Overlaps(other.even) ||
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odd.Overlaps(other.odd);
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}
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// Scans though active texture units checks for overlaps.
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void FinalizeBinds(BitSet32 used_textures)
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{
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for (u32 i : used_textures)
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{
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if (s_unit[i].even.Overlaps(s_unit[i].odd))
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{ // Self-overlap
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s_unit[i].state = TextureUnitState::State::VALID;
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}
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for (size_t j = 0; j < s_unit.size(); j++)
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{
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if (j != i && s_unit[i].Overlaps(s_unit[j]))
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{
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// There is an overlap, downgrade both from CACHED
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// (for there to be an overlap, both must have started as valid or cached)
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s_unit[i].state = TextureUnitState::State::VALID;
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s_unit[j].state = TextureUnitState::State::VALID;
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}
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}
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}
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}
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bool IsCached(u32 unit)
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{
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return s_unit[unit].state == TextureUnitState::State::CACHED;
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}
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bool IsValid(u32 unit)
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{
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return s_unit[unit].state != TextureUnitState::State::INVALID;
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}
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void Init()
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{
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s_unit.fill({});
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}
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void DoState(PointerWrap& p)
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{
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p.DoArray(s_unit);
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}
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} // namespace TMEM
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