// Copyright 2019 yuzu Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.
#pragma once
#include <algorithm>
#include <array>
#include <deque>
#include <memory>
#include <mutex>
#include <numeric>
#include <span>
#include <unordered_map>
#include <vector>
#include <boost/container/small_vector.hpp>
#include "common/common_types.h"
#include "common/div_ceil.h"
#include "common/microprofile.h"
#include "common/scope_exit.h"
#include "common/settings.h"
#include "core/memory.h"
#include "video_core/buffer_cache/buffer_base.h"
#include "video_core/delayed_destruction_ring.h"
#include "video_core/dirty_flags.h"
#include "video_core/engines/kepler_compute.h"
#include "video_core/engines/maxwell_3d.h"
#include "video_core/memory_manager.h"
#include "video_core/rasterizer_interface.h"
#include "video_core/texture_cache/slot_vector.h"
#include "video_core/texture_cache/types.h"
namespace VideoCommon {
MICROPROFILE_DECLARE(GPU_PrepareBuffers);
MICROPROFILE_DECLARE(GPU_BindUploadBuffers);
MICROPROFILE_DECLARE(GPU_DownloadMemory);
using BufferId = SlotId;
constexpr u32 NUM_VERTEX_BUFFERS = 32;
constexpr u32 NUM_TRANSFORM_FEEDBACK_BUFFERS = 4;
constexpr u32 NUM_GRAPHICS_UNIFORM_BUFFERS = 18;
constexpr u32 NUM_COMPUTE_UNIFORM_BUFFERS = 8;
constexpr u32 NUM_STORAGE_BUFFERS = 16;
constexpr u32 NUM_STAGES = 5;
template <typename P>
class BufferCache {
// Page size for caching purposes.
// This is unrelated to the CPU page size and it can be changed as it seems optimal.
static constexpr u32 PAGE_BITS = 16;
static constexpr u64 PAGE_SIZE = u64{1} << PAGE_BITS;
static constexpr bool IS_OPENGL = P::IS_OPENGL;
static constexpr bool HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS =
P::HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS;
static constexpr bool HAS_FULL_INDEX_AND_PRIMITIVE_SUPPORT =
P::HAS_FULL_INDEX_AND_PRIMITIVE_SUPPORT;
static constexpr bool NEEDS_BIND_UNIFORM_INDEX = P::NEEDS_BIND_UNIFORM_INDEX;
static constexpr bool NEEDS_BIND_STORAGE_INDEX = P::NEEDS_BIND_STORAGE_INDEX;
static constexpr bool USE_MEMORY_MAPS = P::USE_MEMORY_MAPS;
static constexpr BufferId NULL_BUFFER_ID{0};
using Maxwell = Tegra::Engines::Maxwell3D::Regs;
using Runtime = typename P::Runtime;
using Buffer = typename P::Buffer;
struct Empty {};
struct OverlapResult {
std::vector<BufferId> ids;
VAddr begin;
VAddr end;
bool has_stream_leap = false;
};
struct Binding {
VAddr cpu_addr{};
u32 size{};
BufferId buffer_id;
};
static constexpr Binding NULL_BINDING{
.cpu_addr = 0,
.size = 0,
.buffer_id = NULL_BUFFER_ID,
};
public:
static constexpr u32 DEFAULT_SKIP_CACHE_SIZE = 4096;
explicit BufferCache(VideoCore::RasterizerInterface& rasterizer_,
Tegra::Engines::Maxwell3D& maxwell3d_,
Tegra::Engines::KeplerCompute& kepler_compute_,
Tegra::MemoryManager& gpu_memory_, Core::Memory::Memory& cpu_memory_,
Runtime& runtime_);
void TickFrame();
void WriteMemory(VAddr cpu_addr, u64 size);
void CachedWriteMemory(VAddr cpu_addr, u64 size);
void DownloadMemory(VAddr cpu_addr, u64 size);
void BindGraphicsUniformBuffer(size_t stage, u32 index, GPUVAddr gpu_addr, u32 size);
void UpdateGraphicsBuffers(bool is_indexed);
void UpdateComputeBuffers();
void BindHostGeometryBuffers(bool is_indexed);
void BindHostStageBuffers(size_t stage);
void BindHostComputeBuffers();
void SetEnabledUniformBuffers(size_t stage, u32 enabled);
void SetEnabledComputeUniformBuffers(u32 enabled);
void UnbindGraphicsStorageBuffers(size_t stage);
void BindGraphicsStorageBuffer(size_t stage, size_t ssbo_index, u32 cbuf_index, u32 cbuf_offset,
bool is_written);
void UnbindComputeStorageBuffers();
void BindComputeStorageBuffer(size_t ssbo_index, u32 cbuf_index, u32 cbuf_offset,
bool is_written);
void FlushCachedWrites();
/// Return true when there are uncommitted buffers to be downloaded
[[nodiscard]] bool HasUncommittedFlushes() const noexcept;
/// Return true when the caller should wait for async downloads
[[nodiscard]] bool ShouldWaitAsyncFlushes() const noexcept;
/// Commit asynchronous downloads
void CommitAsyncFlushes();
/// Pop asynchronous downloads
void PopAsyncFlushes();
/// Return true when a CPU region is modified from the GPU
[[nodiscard]] bool IsRegionGpuModified(VAddr addr, size_t size);
std::mutex mutex;
private:
template <typename Func>
static void ForEachEnabledBit(u32 enabled_mask, Func&& func) {
for (u32 index = 0; enabled_mask != 0; ++index, enabled_mask >>= 1) {
const int disabled_bits = std::countr_zero(enabled_mask);
index += disabled_bits;
enabled_mask >>= disabled_bits;
func(index);
}
}
template <typename Func>
void ForEachBufferInRange(VAddr cpu_addr, u64 size, Func&& func) {
const u64 page_end = Common::DivCeil(cpu_addr + size, PAGE_SIZE);
for (u64 page = cpu_addr >> PAGE_BITS; page < page_end;) {
const BufferId buffer_id = page_table[page];
if (!buffer_id) {
++page;
continue;
}
Buffer& buffer = slot_buffers[buffer_id];
func(buffer_id, buffer);
const VAddr end_addr = buffer.CpuAddr() + buffer.SizeBytes();
page = Common::DivCeil(end_addr, PAGE_SIZE);
}
}
static bool IsRangeGranular(VAddr cpu_addr, size_t size) {
return (cpu_addr & ~Core::Memory::PAGE_MASK) ==
((cpu_addr + size) & ~Core::Memory::PAGE_MASK);
}
void BindHostIndexBuffer();
void BindHostVertexBuffers();
void BindHostGraphicsUniformBuffers(size_t stage);
void BindHostGraphicsUniformBuffer(size_t stage, u32 index, u32 binding_index, bool needs_bind);
void BindHostGraphicsStorageBuffers(size_t stage);
void BindHostTransformFeedbackBuffers();
void BindHostComputeUniformBuffers();
void BindHostComputeStorageBuffers();
void DoUpdateGraphicsBuffers(bool is_indexed);
void DoUpdateComputeBuffers();
void UpdateIndexBuffer();
void UpdateVertexBuffers();
void UpdateVertexBuffer(u32 index);
void UpdateUniformBuffers(size_t stage);
void UpdateStorageBuffers(size_t stage);
void UpdateTransformFeedbackBuffers();
void UpdateTransformFeedbackBuffer(u32 index);
void UpdateComputeUniformBuffers();
void UpdateComputeStorageBuffers();
void MarkWrittenBuffer(BufferId buffer_id, VAddr cpu_addr, u32 size);
[[nodiscard]] BufferId FindBuffer(VAddr cpu_addr, u32 size);
[[nodiscard]] OverlapResult ResolveOverlaps(VAddr cpu_addr, u32 wanted_size);
void JoinOverlap(BufferId new_buffer_id, BufferId overlap_id, bool accumulate_stream_score);
[[nodiscard]] BufferId CreateBuffer(VAddr cpu_addr, u32 wanted_size);
void Register(BufferId buffer_id);
void Unregister(BufferId buffer_id);
template <bool insert>
void ChangeRegister(BufferId buffer_id);
bool SynchronizeBuffer(Buffer& buffer, VAddr cpu_addr, u32 size);
bool SynchronizeBufferImpl(Buffer& buffer, VAddr cpu_addr, u32 size);
void UploadMemory(Buffer& buffer, u64 total_size_bytes, u64 largest_copy,
std::span<BufferCopy> copies);
void ImmediateUploadMemory(Buffer& buffer, u64 largest_copy,
std::span<const BufferCopy> copies);
void MappedUploadMemory(Buffer& buffer, u64 total_size_bytes, std::span<BufferCopy> copies);
void DeleteBuffer(BufferId buffer_id);
void ReplaceBufferDownloads(BufferId old_buffer_id, BufferId new_buffer_id);
void NotifyBufferDeletion();
[[nodiscard]] Binding StorageBufferBinding(GPUVAddr ssbo_addr) const;
[[nodiscard]] std::span<const u8> ImmediateBufferWithData(VAddr cpu_addr, size_t size);
[[nodiscard]] std::span<u8> ImmediateBuffer(size_t wanted_capacity);
[[nodiscard]] bool HasFastUniformBufferBound(size_t stage, u32 binding_index) const noexcept;
VideoCore::RasterizerInterface& rasterizer;
Tegra::Engines::Maxwell3D& maxwell3d;
Tegra::Engines::KeplerCompute& kepler_compute;
Tegra::MemoryManager& gpu_memory;
Core::Memory::Memory& cpu_memory;
Runtime& runtime;
SlotVector<Buffer> slot_buffers;
DelayedDestructionRing<Buffer, 8> delayed_destruction_ring;
u32 last_index_count = 0;
Binding index_buffer;
std::array<Binding, NUM_VERTEX_BUFFERS> vertex_buffers;
std::array<std::array<Binding, NUM_GRAPHICS_UNIFORM_BUFFERS>, NUM_STAGES> uniform_buffers;
std::array<std::array<Binding, NUM_STORAGE_BUFFERS>, NUM_STAGES> storage_buffers;
std::array<Binding, NUM_TRANSFORM_FEEDBACK_BUFFERS> transform_feedback_buffers;
std::array<Binding, NUM_COMPUTE_UNIFORM_BUFFERS> compute_uniform_buffers;
std::array<Binding, NUM_STORAGE_BUFFERS> compute_storage_buffers;
std::array<u32, NUM_STAGES> enabled_uniform_buffers{};
u32 enabled_compute_uniform_buffers = 0;
std::array<u32, NUM_STAGES> enabled_storage_buffers{};
std::array<u32, NUM_STAGES> written_storage_buffers{};
u32 enabled_compute_storage_buffers = 0;
u32 written_compute_storage_buffers = 0;
std::array<u32, NUM_STAGES> fast_bound_uniform_buffers{};
std::array<u32, 16> uniform_cache_hits{};
std::array<u32, 16> uniform_cache_shots{};
u32 uniform_buffer_skip_cache_size = DEFAULT_SKIP_CACHE_SIZE;
bool has_deleted_buffers = false;
std::conditional_t<HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS, std::array<u32, NUM_STAGES>, Empty>
dirty_uniform_buffers{};
std::vector<BufferId> cached_write_buffer_ids;
// TODO: This data structure is not optimal and it should be reworked
std::vector<BufferId> uncommitted_downloads;
std::deque<std::vector<BufferId>> committed_downloads;
size_t immediate_buffer_capacity = 0;
std::unique_ptr<u8[]> immediate_buffer_alloc;
std::array<BufferId, ((1ULL << 39) >> PAGE_BITS)> page_table;
};
template <class P>
BufferCache<P>::BufferCache(VideoCore::RasterizerInterface& rasterizer_,
Tegra::Engines::Maxwell3D& maxwell3d_,
Tegra::Engines::KeplerCompute& kepler_compute_,
Tegra::MemoryManager& gpu_memory_, Core::Memory::Memory& cpu_memory_,
Runtime& runtime_)
: rasterizer{rasterizer_}, maxwell3d{maxwell3d_}, kepler_compute{kepler_compute_},
gpu_memory{gpu_memory_}, cpu_memory{cpu_memory_}, runtime{runtime_} {
// Ensure the first slot is used for the null buffer
void(slot_buffers.insert(runtime, NullBufferParams{}));
}
template <class P>
void BufferCache<P>::TickFrame() {
// Calculate hits and shots and move hit bits to the right
const u32 hits = std::reduce(uniform_cache_hits.begin(), uniform_cache_hits.end());
const u32 shots = std::reduce(uniform_cache_shots.begin(), uniform_cache_shots.end());
std::copy_n(uniform_cache_hits.begin(), uniform_cache_hits.size() - 1,
uniform_cache_hits.begin() + 1);
std::copy_n(uniform_cache_shots.begin(), uniform_cache_shots.size() - 1,
uniform_cache_shots.begin() + 1);
uniform_cache_hits[0] = 0;
uniform_cache_shots[0] = 0;
const bool skip_preferred = hits * 256 < shots * 251;
uniform_buffer_skip_cache_size = skip_preferred ? DEFAULT_SKIP_CACHE_SIZE : 0;
delayed_destruction_ring.Tick();
}
template <class P>
void BufferCache<P>::WriteMemory(VAddr cpu_addr, u64 size) {
ForEachBufferInRange(cpu_addr, size, [&](BufferId, Buffer& buffer) {
buffer.MarkRegionAsCpuModified(cpu_addr, size);
});
}
template <class P>
void BufferCache<P>::CachedWriteMemory(VAddr cpu_addr, u64 size) {
ForEachBufferInRange(cpu_addr, size, [&](BufferId buffer_id, Buffer& buffer) {
if (!buffer.HasCachedWrites()) {
cached_write_buffer_ids.push_back(buffer_id);
}
buffer.CachedCpuWrite(cpu_addr, size);
});
}
template <class P>
void BufferCache<P>::DownloadMemory(VAddr cpu_addr, u64 size) {
ForEachBufferInRange(cpu_addr, size, [&](BufferId, Buffer& buffer) {
boost::container::small_vector<BufferCopy, 1> copies;
u64 total_size_bytes = 0;
u64 largest_copy = 0;
buffer.ForEachDownloadRange(cpu_addr, size, [&](u64 range_offset, u64 range_size) {
copies.push_back(BufferCopy{
.src_offset = range_offset,
.dst_offset = total_size_bytes,
.size = range_size,
});
total_size_bytes += range_size;
largest_copy = std::max(largest_copy, range_size);
});
if (total_size_bytes == 0) {
return;
}
MICROPROFILE_SCOPE(GPU_DownloadMemory);
if constexpr (USE_MEMORY_MAPS) {
auto download_staging = runtime.DownloadStagingBuffer(total_size_bytes);
const u8* const mapped_memory = download_staging.mapped_span.data();
const std::span<BufferCopy> copies_span(copies.data(), copies.data() + copies.size());
for (BufferCopy& copy : copies) {
// Modify copies to have the staging offset in mind
copy.dst_offset += download_staging.offset;
}
runtime.CopyBuffer(download_staging.buffer, buffer, copies_span);
runtime.Finish();
for (const BufferCopy& copy : copies) {
const VAddr copy_cpu_addr = buffer.CpuAddr() + copy.src_offset;
// Undo the modified offset
const u64 dst_offset = copy.dst_offset - download_staging.offset;
const u8* copy_mapped_memory = mapped_memory + dst_offset;
cpu_memory.WriteBlockUnsafe(copy_cpu_addr, copy_mapped_memory, copy.size);
}
} else {
const std::span<u8> immediate_buffer = ImmediateBuffer(largest_copy);
for (const BufferCopy& copy : copies) {
buffer.ImmediateDownload(copy.src_offset, immediate_buffer.subspan(0, copy.size));
const VAddr copy_cpu_addr = buffer.CpuAddr() + copy.src_offset;
cpu_memory.WriteBlockUnsafe(copy_cpu_addr, immediate_buffer.data(), copy.size);
}
}
});
}
template <class P>
void BufferCache<P>::BindGraphicsUniformBuffer(size_t stage, u32 index, GPUVAddr gpu_addr,
u32 size) {
const std::optional<VAddr> cpu_addr = gpu_memory.GpuToCpuAddress(gpu_addr);
if (!cpu_addr) {
uniform_buffers[stage][index] = NULL_BINDING;
return;
}
const Binding binding{
.cpu_addr = *cpu_addr,
.size = size,
.buffer_id = BufferId{},
};
uniform_buffers[stage][index] = binding;
}
template <class P>
void BufferCache<P>::UpdateGraphicsBuffers(bool is_indexed) {
MICROPROFILE_SCOPE(GPU_PrepareBuffers);
do {
has_deleted_buffers = false;
DoUpdateGraphicsBuffers(is_indexed);
} while (has_deleted_buffers);
}
template <class P>
void BufferCache<P>::UpdateComputeBuffers() {
MICROPROFILE_SCOPE(GPU_PrepareBuffers);
do {
has_deleted_buffers = false;
DoUpdateComputeBuffers();
} while (has_deleted_buffers);
}
template <class P>
void BufferCache<P>::BindHostGeometryBuffers(bool is_indexed) {
MICROPROFILE_SCOPE(GPU_BindUploadBuffers);
if (is_indexed) {
BindHostIndexBuffer();
} else if constexpr (!HAS_FULL_INDEX_AND_PRIMITIVE_SUPPORT) {
const auto& regs = maxwell3d.regs;
if (regs.draw.topology == Maxwell::PrimitiveTopology::Quads) {
runtime.BindQuadArrayIndexBuffer(regs.vertex_buffer.first, regs.vertex_buffer.count);
}
}
BindHostVertexBuffers();
BindHostTransformFeedbackBuffers();
}
template <class P>
void BufferCache<P>::BindHostStageBuffers(size_t stage) {
MICROPROFILE_SCOPE(GPU_BindUploadBuffers);
BindHostGraphicsUniformBuffers(stage);
BindHostGraphicsStorageBuffers(stage);
}
template <class P>
void BufferCache<P>::BindHostComputeBuffers() {
MICROPROFILE_SCOPE(GPU_BindUploadBuffers);
BindHostComputeUniformBuffers();
BindHostComputeStorageBuffers();
}
template <class P>
void BufferCache<P>::SetEnabledUniformBuffers(size_t stage, u32 enabled) {
if constexpr (HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS) {
if (enabled_uniform_buffers[stage] != enabled) {
dirty_uniform_buffers[stage] = ~u32{0};
}
}
enabled_uniform_buffers[stage] = enabled;
}
template <class P>
void BufferCache<P>::SetEnabledComputeUniformBuffers(u32 enabled) {
enabled_compute_uniform_buffers = enabled;
}
template <class P>
void BufferCache<P>::UnbindGraphicsStorageBuffers(size_t stage) {
enabled_storage_buffers[stage] = 0;
written_storage_buffers[stage] = 0;
}
template <class P>
void BufferCache<P>::BindGraphicsStorageBuffer(size_t stage, size_t ssbo_index, u32 cbuf_index,
u32 cbuf_offset, bool is_written) {
enabled_storage_buffers[stage] |= 1U << ssbo_index;
written_storage_buffers[stage] |= (is_written ? 1U : 0U) << ssbo_index;
const auto& cbufs = maxwell3d.state.shader_stages[stage];
const GPUVAddr ssbo_addr = cbufs.const_buffers[cbuf_index].address + cbuf_offset;
storage_buffers[stage][ssbo_index] = StorageBufferBinding(ssbo_addr);
}
template <class P>
void BufferCache<P>::UnbindComputeStorageBuffers() {
enabled_compute_storage_buffers = 0;
written_compute_storage_buffers = 0;
}
template <class P>
void BufferCache<P>::BindComputeStorageBuffer(size_t ssbo_index, u32 cbuf_index, u32 cbuf_offset,
bool is_written) {
enabled_compute_storage_buffers |= 1U << ssbo_index;
written_compute_storage_buffers |= (is_written ? 1U : 0U) << ssbo_index;
const auto& launch_desc = kepler_compute.launch_description;
ASSERT(((launch_desc.const_buffer_enable_mask >> cbuf_index) & 1) != 0);
const auto& cbufs = launch_desc.const_buffer_config;
const GPUVAddr ssbo_addr = cbufs[cbuf_index].Address() + cbuf_offset;
compute_storage_buffers[ssbo_index] = StorageBufferBinding(ssbo_addr);
}
template <class P>
void BufferCache<P>::FlushCachedWrites() {
for (const BufferId buffer_id : cached_write_buffer_ids) {
slot_buffers[buffer_id].FlushCachedWrites();
}
cached_write_buffer_ids.clear();
}
template <class P>
bool BufferCache<P>::HasUncommittedFlushes() const noexcept {
return !uncommitted_downloads.empty();
}
template <class P>
bool BufferCache<P>::ShouldWaitAsyncFlushes() const noexcept {
return !committed_downloads.empty() && !committed_downloads.front().empty();
}
template <class P>
void BufferCache<P>::CommitAsyncFlushes() {
// This is intentionally passing the value by copy
committed_downloads.push_front(uncommitted_downloads);
uncommitted_downloads.clear();
}
template <class P>
void BufferCache<P>::PopAsyncFlushes() {
if (committed_downloads.empty()) {
return;
}
auto scope_exit_pop_download = detail::ScopeExit([this] { committed_downloads.pop_back(); });
const std::span<const BufferId> download_ids = committed_downloads.back();
if (download_ids.empty()) {
return;
}
MICROPROFILE_SCOPE(GPU_DownloadMemory);
boost::container::small_vector<std::pair<BufferCopy, BufferId>, 1> downloads;
u64 total_size_bytes = 0;
u64 largest_copy = 0;
for (const BufferId buffer_id : download_ids) {
slot_buffers[buffer_id].ForEachDownloadRange([&](u64 range_offset, u64 range_size) {
downloads.push_back({
BufferCopy{
.src_offset = range_offset,
.dst_offset = total_size_bytes,
.size = range_size,
},
buffer_id,
});
total_size_bytes += range_size;
largest_copy = std::max(largest_copy, range_size);
});
}
if (downloads.empty()) {
return;
}
if constexpr (USE_MEMORY_MAPS) {
auto download_staging = runtime.DownloadStagingBuffer(total_size_bytes);
for (auto& [copy, buffer_id] : downloads) {
// Have in mind the staging buffer offset for the copy
copy.dst_offset += download_staging.offset;
const std::array copies{copy};
runtime.CopyBuffer(download_staging.buffer, slot_buffers[buffer_id], copies);
}
runtime.Finish();
for (const auto [copy, buffer_id] : downloads) {
const Buffer& buffer = slot_buffers[buffer_id];
const VAddr cpu_addr = buffer.CpuAddr() + copy.src_offset;
// Undo the modified offset
const u64 dst_offset = copy.dst_offset - download_staging.offset;
const u8* read_mapped_memory = download_staging.mapped_span.data() + dst_offset;
cpu_memory.WriteBlockUnsafe(cpu_addr, read_mapped_memory, copy.size);
}
} else {
const std::span<u8> immediate_buffer = ImmediateBuffer(largest_copy);
for (const auto [copy, buffer_id] : downloads) {
Buffer& buffer = slot_buffers[buffer_id];
buffer.ImmediateDownload(copy.src_offset, immediate_buffer.subspan(0, copy.size));
const VAddr cpu_addr = buffer.CpuAddr() + copy.src_offset;
cpu_memory.WriteBlockUnsafe(cpu_addr, immediate_buffer.data(), copy.size);
}
}
}
template <class P>
bool BufferCache<P>::IsRegionGpuModified(VAddr addr, size_t size) {
const u64 page_end = Common::DivCeil(addr + size, PAGE_SIZE);
for (u64 page = addr >> PAGE_BITS; page < page_end;) {
const BufferId image_id = page_table[page];
if (!image_id) {
++page;
continue;
}
Buffer& buffer = slot_buffers[image_id];
if (buffer.IsRegionGpuModified(addr, size)) {
return true;
}
const VAddr end_addr = buffer.CpuAddr() + buffer.SizeBytes();
page = Common::DivCeil(end_addr, PAGE_SIZE);
}
return false;
}
template <class P>
void BufferCache<P>::BindHostIndexBuffer() {
Buffer& buffer = slot_buffers[index_buffer.buffer_id];
const u32 offset = buffer.Offset(index_buffer.cpu_addr);
const u32 size = index_buffer.size;
SynchronizeBuffer(buffer, index_buffer.cpu_addr, size);
if constexpr (HAS_FULL_INDEX_AND_PRIMITIVE_SUPPORT) {
runtime.BindIndexBuffer(buffer, offset, size);
} else {
runtime.BindIndexBuffer(maxwell3d.regs.draw.topology, maxwell3d.regs.index_array.format,
maxwell3d.regs.index_array.first, maxwell3d.regs.index_array.count,
buffer, offset, size);
}
}
template <class P>
void BufferCache<P>::BindHostVertexBuffers() {
auto& flags = maxwell3d.dirty.flags;
for (u32 index = 0; index < NUM_VERTEX_BUFFERS; ++index) {
const Binding& binding = vertex_buffers[index];
Buffer& buffer = slot_buffers[binding.buffer_id];
SynchronizeBuffer(buffer, binding.cpu_addr, binding.size);
if (!flags[Dirty::VertexBuffer0 + index]) {
continue;
}
flags[Dirty::VertexBuffer0 + index] = false;
const u32 stride = maxwell3d.regs.vertex_array[index].stride;
const u32 offset = buffer.Offset(binding.cpu_addr);
runtime.BindVertexBuffer(index, buffer, offset, binding.size, stride);
}
}
template <class P>
void BufferCache<P>::BindHostGraphicsUniformBuffers(size_t stage) {
u32 dirty = ~0U;
if constexpr (HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS) {
dirty = std::exchange(dirty_uniform_buffers[stage], 0);
}
u32 binding_index = 0;
ForEachEnabledBit(enabled_uniform_buffers[stage], [&](u32 index) {
const bool needs_bind = ((dirty >> index) & 1) != 0;
BindHostGraphicsUniformBuffer(stage, index, binding_index, needs_bind);
if constexpr (NEEDS_BIND_UNIFORM_INDEX) {
++binding_index;
}
});
}
template <class P>
void BufferCache<P>::BindHostGraphicsUniformBuffer(size_t stage, u32 index, u32 binding_index,
bool needs_bind) {
const Binding& binding = uniform_buffers[stage][index];
const VAddr cpu_addr = binding.cpu_addr;
const u32 size = binding.size;
Buffer& buffer = slot_buffers[binding.buffer_id];
if (size <= uniform_buffer_skip_cache_size && !buffer.IsRegionGpuModified(cpu_addr, size)) {
if constexpr (IS_OPENGL) {
if (runtime.HasFastBufferSubData()) {
// Fast path for Nvidia
if (!HasFastUniformBufferBound(stage, binding_index)) {
// We only have to bind when the currently bound buffer is not the fast version
runtime.BindFastUniformBuffer(stage, binding_index, size);
}
const auto span = ImmediateBufferWithData(cpu_addr, size);
runtime.PushFastUniformBuffer(stage, binding_index, span);
return;
}
}
fast_bound_uniform_buffers[stage] |= 1U << binding_index;
// Stream buffer path to avoid stalling on non-Nvidia drivers or Vulkan
const std::span<u8> span = runtime.BindMappedUniformBuffer(stage, binding_index, size);
cpu_memory.ReadBlockUnsafe(cpu_addr, span.data(), size);
return;
}
// Classic cached path
const bool sync_cached = SynchronizeBuffer(buffer, cpu_addr, size);
if (sync_cached) {
++uniform_cache_hits[0];
}
++uniform_cache_shots[0];
if (!needs_bind && !HasFastUniformBufferBound(stage, binding_index)) {
// Skip binding if it's not needed and if the bound buffer is not the fast version
// This exists to avoid instances where the fast buffer is bound and a GPU write happens
return;
}
fast_bound_uniform_buffers[stage] &= ~(1U << binding_index);
const u32 offset = buffer.Offset(cpu_addr);
if constexpr (NEEDS_BIND_UNIFORM_INDEX) {
runtime.BindUniformBuffer(stage, binding_index, buffer, offset, size);
} else {
runtime.BindUniformBuffer(buffer, offset, size);
}
}
template <class P>
void BufferCache<P>::BindHostGraphicsStorageBuffers(size_t stage) {
u32 binding_index = 0;
ForEachEnabledBit(enabled_storage_buffers[stage], [&](u32 index) {
const Binding& binding = storage_buffers[stage][index];
Buffer& buffer = slot_buffers[binding.buffer_id];
const u32 size = binding.size;
SynchronizeBuffer(buffer, binding.cpu_addr, size);
const u32 offset = buffer.Offset(binding.cpu_addr);
const bool is_written = ((written_storage_buffers[stage] >> index) & 1) != 0;
if constexpr (NEEDS_BIND_STORAGE_INDEX) {
runtime.BindStorageBuffer(stage, binding_index, buffer, offset, size, is_written);
++binding_index;
} else {
runtime.BindStorageBuffer(buffer, offset, size, is_written);
}
});
}
template <class P>
void BufferCache<P>::BindHostTransformFeedbackBuffers() {
if (maxwell3d.regs.tfb_enabled == 0) {
return;
}
for (u32 index = 0; index < NUM_TRANSFORM_FEEDBACK_BUFFERS; ++index) {
const Binding& binding = transform_feedback_buffers[index];
Buffer& buffer = slot_buffers[binding.buffer_id];
const u32 size = binding.size;
SynchronizeBuffer(buffer, binding.cpu_addr, size);
const u32 offset = buffer.Offset(binding.cpu_addr);
runtime.BindTransformFeedbackBuffer(index, buffer, offset, size);
}
}
template <class P>
void BufferCache<P>::BindHostComputeUniformBuffers() {
if constexpr (HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS) {
// Mark all uniform buffers as dirty
dirty_uniform_buffers.fill(~u32{0});
}
u32 binding_index = 0;
ForEachEnabledBit(enabled_compute_uniform_buffers, [&](u32 index) {
const Binding& binding = compute_uniform_buffers[index];
Buffer& buffer = slot_buffers[binding.buffer_id];
const u32 size = binding.size;
SynchronizeBuffer(buffer, binding.cpu_addr, size);
const u32 offset = buffer.Offset(binding.cpu_addr);
if constexpr (NEEDS_BIND_UNIFORM_INDEX) {
runtime.BindComputeUniformBuffer(binding_index, buffer, offset, size);
++binding_index;
} else {
runtime.BindUniformBuffer(buffer, offset, size);
}
});
}
template <class P>
void BufferCache<P>::BindHostComputeStorageBuffers() {
u32 binding_index = 0;
ForEachEnabledBit(enabled_compute_storage_buffers, [&](u32 index) {
const Binding& binding = compute_storage_buffers[index];
Buffer& buffer = slot_buffers[binding.buffer_id];
const u32 size = binding.size;
SynchronizeBuffer(buffer, binding.cpu_addr, size);
const u32 offset = buffer.Offset(binding.cpu_addr);
const bool is_written = ((written_compute_storage_buffers >> index) & 1) != 0;
if constexpr (NEEDS_BIND_STORAGE_INDEX) {
runtime.BindComputeStorageBuffer(binding_index, buffer, offset, size, is_written);
++binding_index;
} else {
runtime.BindStorageBuffer(buffer, offset, size, is_written);
}
});
}
template <class P>
void BufferCache<P>::DoUpdateGraphicsBuffers(bool is_indexed) {
if (is_indexed) {
UpdateIndexBuffer();
}
UpdateVertexBuffers();
UpdateTransformFeedbackBuffers();
for (size_t stage = 0; stage < NUM_STAGES; ++stage) {
UpdateUniformBuffers(stage);
UpdateStorageBuffers(stage);
}
}
template <class P>
void BufferCache<P>::DoUpdateComputeBuffers() {
UpdateComputeUniformBuffers();
UpdateComputeStorageBuffers();
}
template <class P>
void BufferCache<P>::UpdateIndexBuffer() {
// We have to check for the dirty flags and index count
// The index count is currently changed without updating the dirty flags
const auto& index_array = maxwell3d.regs.index_array;
auto& flags = maxwell3d.dirty.flags;
if (!flags[Dirty::IndexBuffer] && last_index_count == index_array.count) {
return;
}
flags[Dirty::IndexBuffer] = false;
last_index_count = index_array.count;
const GPUVAddr gpu_addr_begin = index_array.StartAddress();
const GPUVAddr gpu_addr_end = index_array.EndAddress();
const std::optional<VAddr> cpu_addr = gpu_memory.GpuToCpuAddress(gpu_addr_begin);
const u32 address_size = static_cast<u32>(gpu_addr_end - gpu_addr_begin);
const u32 draw_size = index_array.count * index_array.FormatSizeInBytes();
const u32 size = std::min(address_size, draw_size);
if (size == 0 || !cpu_addr) {
index_buffer = NULL_BINDING;
return;
}
index_buffer = Binding{
.cpu_addr = *cpu_addr,
.size = size,
.buffer_id = FindBuffer(*cpu_addr, size),
};
}
template <class P>
void BufferCache<P>::UpdateVertexBuffers() {
auto& flags = maxwell3d.dirty.flags;
if (!maxwell3d.dirty.flags[Dirty::VertexBuffers]) {
return;
}
flags[Dirty::VertexBuffers] = false;
for (u32 index = 0; index < NUM_VERTEX_BUFFERS; ++index) {
UpdateVertexBuffer(index);
}
}
template <class P>
void BufferCache<P>::UpdateVertexBuffer(u32 index) {
if (!maxwell3d.dirty.flags[Dirty::VertexBuffer0 + index]) {
return;
}
const auto& array = maxwell3d.regs.vertex_array[index];
const auto& limit = maxwell3d.regs.vertex_array_limit[index];
const GPUVAddr gpu_addr_begin = array.StartAddress();
const GPUVAddr gpu_addr_end = limit.LimitAddress() + 1;
const std::optional<VAddr> cpu_addr = gpu_memory.GpuToCpuAddress(gpu_addr_begin);
const u32 address_size = static_cast<u32>(gpu_addr_end - gpu_addr_begin);
const u32 size = address_size; // TODO: Analyze stride and number of vertices
if (array.enable == 0 || size == 0 || !cpu_addr) {
vertex_buffers[index] = NULL_BINDING;
return;
}
vertex_buffers[index] = Binding{
.cpu_addr = *cpu_addr,
.size = size,
.buffer_id = FindBuffer(*cpu_addr, size),
};
}
template <class P>
void BufferCache<P>::UpdateUniformBuffers(size_t stage) {
ForEachEnabledBit(enabled_uniform_buffers[stage], [&](u32 index) {
Binding& binding = uniform_buffers[stage][index];
if (binding.buffer_id) {
// Already updated
return;
}
// Mark as dirty
if constexpr (HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS) {
dirty_uniform_buffers[stage] |= 1U << index;
}
// Resolve buffer
binding.buffer_id = FindBuffer(binding.cpu_addr, binding.size);
});
}
template <class P>
void BufferCache<P>::UpdateStorageBuffers(size_t stage) {
const u32 written_mask = written_storage_buffers[stage];
ForEachEnabledBit(enabled_storage_buffers[stage], [&](u32 index) {
// Resolve buffer
Binding& binding = storage_buffers[stage][index];
const BufferId buffer_id = FindBuffer(binding.cpu_addr, binding.size);
binding.buffer_id = buffer_id;
// Mark buffer as written if needed
if (((written_mask >> index) & 1) != 0) {
MarkWrittenBuffer(buffer_id, binding.cpu_addr, binding.size);
}
});
}
template <class P>
void BufferCache<P>::UpdateTransformFeedbackBuffers() {
if (maxwell3d.regs.tfb_enabled == 0) {
return;
}
for (u32 index = 0; index < NUM_TRANSFORM_FEEDBACK_BUFFERS; ++index) {
UpdateTransformFeedbackBuffer(index);
}
}
template <class P>
void BufferCache<P>::UpdateTransformFeedbackBuffer(u32 index) {
const auto& binding = maxwell3d.regs.tfb_bindings[index];
const GPUVAddr gpu_addr = binding.Address() + binding.buffer_offset;
const u32 size = binding.buffer_size;
const std::optional<VAddr> cpu_addr = gpu_memory.GpuToCpuAddress(gpu_addr);
if (binding.buffer_enable == 0 || size == 0 || !cpu_addr) {
transform_feedback_buffers[index] = NULL_BINDING;
return;
}
const BufferId buffer_id = FindBuffer(*cpu_addr, size);
transform_feedback_buffers[index] = Binding{
.cpu_addr = *cpu_addr,
.size = size,
.buffer_id = buffer_id,
};
MarkWrittenBuffer(buffer_id, *cpu_addr, size);
}
template <class P>
void BufferCache<P>::UpdateComputeUniformBuffers() {
ForEachEnabledBit(enabled_compute_uniform_buffers, [&](u32 index) {
Binding& binding = compute_uniform_buffers[index];
binding = NULL_BINDING;
const auto& launch_desc = kepler_compute.launch_description;
if (((launch_desc.const_buffer_enable_mask >> index) & 1) != 0) {
const auto& cbuf = launch_desc.const_buffer_config[index];
const std::optional<VAddr> cpu_addr = gpu_memory.GpuToCpuAddress(cbuf.Address());
if (cpu_addr) {
binding.cpu_addr = *cpu_addr;
binding.size = cbuf.size;
}
}
binding.buffer_id = FindBuffer(binding.cpu_addr, binding.size);
});
}
template <class P>
void BufferCache<P>::UpdateComputeStorageBuffers() {
ForEachEnabledBit(enabled_compute_storage_buffers, [&](u32 index) {
// Resolve buffer
Binding& binding = compute_storage_buffers[index];
const BufferId buffer_id = FindBuffer(binding.cpu_addr, binding.size);
binding.buffer_id = buffer_id;
// Mark as written if needed
if (((written_compute_storage_buffers >> index) & 1) != 0) {
MarkWrittenBuffer(buffer_id, binding.cpu_addr, binding.size);
}
});
}
template <class P>
void BufferCache<P>::MarkWrittenBuffer(BufferId buffer_id, VAddr cpu_addr, u32 size) {
Buffer& buffer = slot_buffers[buffer_id];
buffer.MarkRegionAsGpuModified(cpu_addr, size);
const bool is_accuracy_high = Settings::IsGPULevelHigh();
const bool is_async = Settings::values.use_asynchronous_gpu_emulation.GetValue();
if (!is_accuracy_high || !is_async) {
return;
}
if (std::ranges::find(uncommitted_downloads, buffer_id) != uncommitted_downloads.end()) {
// Already inserted
return;
}
uncommitted_downloads.push_back(buffer_id);
}
template <class P>
BufferId BufferCache<P>::FindBuffer(VAddr cpu_addr, u32 size) {
if (cpu_addr == 0) {
return NULL_BUFFER_ID;
}
const u64 page = cpu_addr >> PAGE_BITS;
const BufferId buffer_id = page_table[page];
if (!buffer_id) {
return CreateBuffer(cpu_addr, size);
}
const Buffer& buffer = slot_buffers[buffer_id];
if (buffer.IsInBounds(cpu_addr, size)) {
return buffer_id;
}
return CreateBuffer(cpu_addr, size);
}
template <class P>
typename BufferCache<P>::OverlapResult BufferCache<P>::ResolveOverlaps(VAddr cpu_addr,
u32 wanted_size) {
static constexpr int STREAM_LEAP_THRESHOLD = 16;
std::vector<BufferId> overlap_ids;
VAddr begin = cpu_addr;
VAddr end = cpu_addr + wanted_size;
int stream_score = 0;
bool has_stream_leap = false;
for (; cpu_addr >> PAGE_BITS < Common::DivCeil(end, PAGE_SIZE); cpu_addr += PAGE_SIZE) {
const BufferId overlap_id = page_table[cpu_addr >> PAGE_BITS];
if (!overlap_id) {
continue;
}
Buffer& overlap = slot_buffers[overlap_id];
if (overlap.IsPicked()) {
continue;
}
overlap_ids.push_back(overlap_id);
overlap.Pick();
const VAddr overlap_cpu_addr = overlap.CpuAddr();
if (overlap_cpu_addr < begin) {
cpu_addr = begin = overlap_cpu_addr;
}
end = std::max(end, overlap_cpu_addr + overlap.SizeBytes());
stream_score += overlap.StreamScore();
if (stream_score > STREAM_LEAP_THRESHOLD && !has_stream_leap) {
// When this memory region has been joined a bunch of times, we assume it's being used
// as a stream buffer. Increase the size to skip constantly recreating buffers.
has_stream_leap = true;
end += PAGE_SIZE * 256;
}
}
return OverlapResult{
.ids = std::move(overlap_ids),
.begin = begin,
.end = end,
.has_stream_leap = has_stream_leap,
};
}
template <class P>
void BufferCache<P>::JoinOverlap(BufferId new_buffer_id, BufferId overlap_id,
bool accumulate_stream_score) {
Buffer& new_buffer = slot_buffers[new_buffer_id];
Buffer& overlap = slot_buffers[overlap_id];
if (accumulate_stream_score) {
new_buffer.IncreaseStreamScore(overlap.StreamScore() + 1);
}
std::vector<BufferCopy> copies;
const size_t dst_base_offset = overlap.CpuAddr() - new_buffer.CpuAddr();
overlap.ForEachDownloadRange([&](u64 begin, u64 range_size) {
copies.push_back(BufferCopy{
.src_offset = begin,
.dst_offset = dst_base_offset + begin,
.size = range_size,
});
new_buffer.UnmarkRegionAsCpuModified(begin, range_size);
new_buffer.MarkRegionAsGpuModified(begin, range_size);
});
if (!copies.empty()) {
runtime.CopyBuffer(slot_buffers[new_buffer_id], overlap, copies);
}
ReplaceBufferDownloads(overlap_id, new_buffer_id);
DeleteBuffer(overlap_id);
}
template <class P>
BufferId BufferCache<P>::CreateBuffer(VAddr cpu_addr, u32 wanted_size) {
const OverlapResult overlap = ResolveOverlaps(cpu_addr, wanted_size);
const u32 size = static_cast<u32>(overlap.end - overlap.begin);
const BufferId new_buffer_id = slot_buffers.insert(runtime, rasterizer, overlap.begin, size);
for (const BufferId overlap_id : overlap.ids) {
JoinOverlap(new_buffer_id, overlap_id, !overlap.has_stream_leap);
}
Register(new_buffer_id);
return new_buffer_id;
}
template <class P>
void BufferCache<P>::Register(BufferId buffer_id) {
ChangeRegister<true>(buffer_id);
}
template <class P>
void BufferCache<P>::Unregister(BufferId buffer_id) {
ChangeRegister<false>(buffer_id);
}
template <class P>
template <bool insert>
void BufferCache<P>::ChangeRegister(BufferId buffer_id) {
const Buffer& buffer = slot_buffers[buffer_id];
const VAddr cpu_addr_begin = buffer.CpuAddr();
const VAddr cpu_addr_end = cpu_addr_begin + buffer.SizeBytes();
const u64 page_begin = cpu_addr_begin / PAGE_SIZE;
const u64 page_end = Common::DivCeil(cpu_addr_end, PAGE_SIZE);
for (u64 page = page_begin; page != page_end; ++page) {
if constexpr (insert) {
page_table[page] = buffer_id;
} else {
page_table[page] = BufferId{};
}
}
}
template <class P>
bool BufferCache<P>::SynchronizeBuffer(Buffer& buffer, VAddr cpu_addr, u32 size) {
if (buffer.CpuAddr() == 0) {
return true;
}
return SynchronizeBufferImpl(buffer, cpu_addr, size);
}
template <class P>
bool BufferCache<P>::SynchronizeBufferImpl(Buffer& buffer, VAddr cpu_addr, u32 size) {
boost::container::small_vector<BufferCopy, 4> copies;
u64 total_size_bytes = 0;
u64 largest_copy = 0;
buffer.ForEachUploadRange(cpu_addr, size, [&](u64 range_offset, u64 range_size) {
copies.push_back(BufferCopy{
.src_offset = total_size_bytes,
.dst_offset = range_offset,
.size = range_size,
});
total_size_bytes += range_size;
largest_copy = std::max(largest_copy, range_size);
});
if (total_size_bytes == 0) {
return true;
}
const std::span<BufferCopy> copies_span(copies.data(), copies.size());
UploadMemory(buffer, total_size_bytes, largest_copy, copies_span);
return false;
}
template <class P>
void BufferCache<P>::UploadMemory(Buffer& buffer, u64 total_size_bytes, u64 largest_copy,
std::span<BufferCopy> copies) {
if constexpr (USE_MEMORY_MAPS) {
MappedUploadMemory(buffer, total_size_bytes, copies);
} else {
ImmediateUploadMemory(buffer, largest_copy, copies);
}
}
template <class P>
void BufferCache<P>::ImmediateUploadMemory(Buffer& buffer, u64 largest_copy,
std::span<const BufferCopy> copies) {
std::span<u8> immediate_buffer;
for (const BufferCopy& copy : copies) {
std::span<const u8> upload_span;
const VAddr cpu_addr = buffer.CpuAddr() + copy.dst_offset;
if (IsRangeGranular(cpu_addr, copy.size)) {
upload_span = std::span(cpu_memory.GetPointer(cpu_addr), copy.size);
} else {
if (immediate_buffer.empty()) {
immediate_buffer = ImmediateBuffer(largest_copy);
}
cpu_memory.ReadBlockUnsafe(cpu_addr, immediate_buffer.data(), copy.size);
upload_span = immediate_buffer.subspan(0, copy.size);
}
buffer.ImmediateUpload(copy.dst_offset, upload_span);
}
}
template <class P>
void BufferCache<P>::MappedUploadMemory(Buffer& buffer, u64 total_size_bytes,
std::span<BufferCopy> copies) {
auto upload_staging = runtime.UploadStagingBuffer(total_size_bytes);
const std::span<u8> staging_pointer = upload_staging.mapped_span;
for (BufferCopy& copy : copies) {
u8* const src_pointer = staging_pointer.data() + copy.src_offset;
const VAddr cpu_addr = buffer.CpuAddr() + copy.dst_offset;
cpu_memory.ReadBlockUnsafe(cpu_addr, src_pointer, copy.size);
// Apply the staging offset
copy.src_offset += upload_staging.offset;
}
runtime.CopyBuffer(buffer, upload_staging.buffer, copies);
}
template <class P>
void BufferCache<P>::DeleteBuffer(BufferId buffer_id) {
const auto scalar_replace = [buffer_id](Binding& binding) {
if (binding.buffer_id == buffer_id) {
binding.buffer_id = BufferId{};
}
};
const auto replace = [scalar_replace](std::span<Binding> bindings) {
std::ranges::for_each(bindings, scalar_replace);
};
scalar_replace(index_buffer);
replace(vertex_buffers);
std::ranges::for_each(uniform_buffers, replace);
std::ranges::for_each(storage_buffers, replace);
replace(transform_feedback_buffers);
replace(compute_uniform_buffers);
replace(compute_storage_buffers);
std::erase(cached_write_buffer_ids, buffer_id);
// Mark the whole buffer as CPU written to stop tracking CPU writes
Buffer& buffer = slot_buffers[buffer_id];
buffer.MarkRegionAsCpuModified(buffer.CpuAddr(), buffer.SizeBytes());
Unregister(buffer_id);
delayed_destruction_ring.Push(std::move(slot_buffers[buffer_id]));
NotifyBufferDeletion();
}
template <class P>
void BufferCache<P>::ReplaceBufferDownloads(BufferId old_buffer_id, BufferId new_buffer_id) {
const auto replace = [old_buffer_id, new_buffer_id](std::vector<BufferId>& buffers) {
std::ranges::replace(buffers, old_buffer_id, new_buffer_id);
if (auto it = std::ranges::find(buffers, new_buffer_id); it != buffers.end()) {
buffers.erase(std::remove(it + 1, buffers.end(), new_buffer_id), buffers.end());
}
};
replace(uncommitted_downloads);
std::ranges::for_each(committed_downloads, replace);
}
template <class P>
void BufferCache<P>::NotifyBufferDeletion() {
if constexpr (HAS_PERSISTENT_UNIFORM_BUFFER_BINDINGS) {
dirty_uniform_buffers.fill(~u32{0});
}
auto& flags = maxwell3d.dirty.flags;
flags[Dirty::IndexBuffer] = true;
flags[Dirty::VertexBuffers] = true;
for (u32 index = 0; index < NUM_VERTEX_BUFFERS; ++index) {
flags[Dirty::VertexBuffer0 + index] = true;
}
has_deleted_buffers = true;
}
template <class P>
typename BufferCache<P>::Binding BufferCache<P>::StorageBufferBinding(GPUVAddr ssbo_addr) const {
const GPUVAddr gpu_addr = gpu_memory.Read<u64>(ssbo_addr);
const u32 size = gpu_memory.Read<u32>(ssbo_addr + 8);
const std::optional<VAddr> cpu_addr = gpu_memory.GpuToCpuAddress(gpu_addr);
if (!cpu_addr || size == 0) {
return NULL_BINDING;
}
// HACK(Rodrigo): This is the number of bytes bound in host beyond the guest API's range.
// It exists due to some games like Astral Chain operate out of bounds.
// Binding the whole map range would be technically correct, but games have large maps that make
// this approach unaffordable for now.
static constexpr u32 arbitrary_extra_bytes = 0xc000;
const u32 bytes_to_map_end = static_cast<u32>(gpu_memory.BytesToMapEnd(gpu_addr));
const Binding binding{
.cpu_addr = *cpu_addr,
.size = std::min(size + arbitrary_extra_bytes, bytes_to_map_end),
.buffer_id = BufferId{},
};
return binding;
}
template <class P>
std::span<const u8> BufferCache<P>::ImmediateBufferWithData(VAddr cpu_addr, size_t size) {
u8* const base_pointer = cpu_memory.GetPointer(cpu_addr);
if (IsRangeGranular(cpu_addr, size) ||
base_pointer + size == cpu_memory.GetPointer(cpu_addr + size)) {
return std::span(base_pointer, size);
} else {
const std::span<u8> span = ImmediateBuffer(size);
cpu_memory.ReadBlockUnsafe(cpu_addr, span.data(), size);
return span;
}
}
template <class P>
std::span<u8> BufferCache<P>::ImmediateBuffer(size_t wanted_capacity) {
if (wanted_capacity > immediate_buffer_capacity) {
immediate_buffer_capacity = wanted_capacity;
immediate_buffer_alloc = std::make_unique<u8[]>(wanted_capacity);
}
return std::span<u8>(immediate_buffer_alloc.get(), wanted_capacity);
}
template <class P>
bool BufferCache<P>::HasFastUniformBufferBound(size_t stage, u32 binding_index) const noexcept {
if constexpr (IS_OPENGL) {
return ((fast_bound_uniform_buffers[stage] >> binding_index) & 1) != 0;
} else {
// Only OpenGL has fast uniform buffers
return false;
}
}
} // namespace VideoCommon
