Query Cache: Simplify Prefix Sum compute shader

This commit is contained in:
Fernando Sahmkow 2023-08-22 12:28:25 +02:00
parent c8237d5c31
commit a07c88e686
6 changed files with 252 additions and 73 deletions

View File

@ -42,6 +42,7 @@ set(SHADER_FILES
present_bicubic.frag
present_gaussian.frag
queries_prefix_scan_sum.comp
queries_prefix_scan_sum_nosubgroups.comp
resolve_conditional_render.comp
smaa_edge_detection.vert
smaa_edge_detection.frag
@ -72,6 +73,7 @@ if ("${GLSLANGVALIDATOR}" STREQUAL "GLSLANGVALIDATOR-NOTFOUND")
endif()
set(GLSL_FLAGS "")
set(SPIR_V_VERSION "spirv1.3")
set(QUIET_FLAG "--quiet")
set(SHADER_INCLUDE ${CMAKE_CURRENT_BINARY_DIR}/include)
@ -125,7 +127,7 @@ foreach(FILENAME IN ITEMS ${SHADER_FILES})
OUTPUT
${SPIRV_HEADER_FILE}
COMMAND
${GLSLANGVALIDATOR} -V ${QUIET_FLAG} -I"${FIDELITYFX_INCLUDE_DIR}" ${GLSL_FLAGS} --variable-name ${SPIRV_VARIABLE_NAME} -o ${SPIRV_HEADER_FILE} ${SOURCE_FILE}
${GLSLANGVALIDATOR} -V ${QUIET_FLAG} -I"${FIDELITYFX_INCLUDE_DIR}" ${GLSL_FLAGS} --variable-name ${SPIRV_VARIABLE_NAME} -o ${SPIRV_HEADER_FILE} ${SOURCE_FILE} --target-env ${SPIR_V_VERSION}
MAIN_DEPENDENCY
${SOURCE_FILE}
)

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@ -1,26 +1,24 @@
// SPDX-FileCopyrightText: Copyright 2015 Graham Sellers, Richard Wright Jr. and Nicholas Haemel
// SPDX-License-Identifier: MIT
// Code obtained from OpenGL SuperBible, Seventh Edition by Graham Sellers, Richard Wright Jr. and
// Nicholas Haemel. Modified to suit needs and optimize for subgroup
// SPDX-FileCopyrightText: Copyright 2023 yuzu Emulator Project
// SPDX-License-Identifier: GPL-3.0-or-later
#version 460 core
#extension GL_KHR_shader_subgroup_basic : require
#extension GL_KHR_shader_subgroup_shuffle : require
#extension GL_KHR_shader_subgroup_shuffle_relative : require
#extension GL_KHR_shader_subgroup_arithmetic : require
#ifdef VULKAN
#extension GL_KHR_shader_subgroup_arithmetic : enable
#define HAS_EXTENDED_TYPES 1
#define BEGIN_PUSH_CONSTANTS layout(push_constant) uniform PushConstants {
#define END_PUSH_CONSTANTS \
} \
;
#define END_PUSH_CONSTANTS };
#define UNIFORM(n)
#define BINDING_INPUT_BUFFER 0
#define BINDING_OUTPUT_IMAGE 1
#else // ^^^ Vulkan ^^^ // vvv OpenGL vvv
#extension GL_KHR_shader_subgroup_arithmetic : enable
#extension GL_NV_gpu_shader5 : enable
#ifdef GL_NV_gpu_shader5
#define HAS_EXTENDED_TYPES 1
@ -43,19 +41,20 @@ END_PUSH_CONSTANTS
layout(local_size_x = 32) in;
layout(std430, binding = 0) readonly buffer block1 {
uvec2 input_data[gl_WorkGroupSize.x];
uvec2 input_data[];
};
layout(std430, binding = 1) writeonly coherent buffer block2 {
uvec2 output_data[gl_WorkGroupSize.x];
layout(std430, binding = 1) coherent buffer block2 {
uvec2 output_data[];
};
layout(std430, binding = 2) coherent buffer block3 {
uvec2 accumulated_data;
};
shared uvec2 shared_data[gl_WorkGroupSize.x * 2];
shared uvec2 shared_data[2];
// Simple Uint64 add that uses 2 uint variables for GPUs that don't support uint64
uvec2 AddUint64(uvec2 value_1, uvec2 value_2) {
uint carry = 0;
uvec2 result;
@ -64,61 +63,102 @@ uvec2 AddUint64(uvec2 value_1, uvec2 value_2) {
return result;
}
void main(void) {
uint id = gl_LocalInvocationID.x;
uvec2 base_value_1 = (id * 2) < max_accumulation_base ? accumulated_data : uvec2(0);
uvec2 base_value_2 = (id * 2 + 1) < max_accumulation_base ? accumulated_data : uvec2(0);
uint work_size = gl_WorkGroupSize.x;
uint rd_id;
uint wr_id;
uint mask;
uvec2 input_1 = input_data[id * 2];
uvec2 input_2 = input_data[id * 2 + 1];
// The number of steps is the log base 2 of the
// work group size, which should be a power of 2
const uint steps = uint(log2(work_size)) + 1;
uint step = 0;
// Each invocation is responsible for the content of
// two elements of the output array
shared_data[id * 2] = input_1;
shared_data[id * 2 + 1] = input_2;
// Synchronize to make sure that everyone has initialized
// their elements of shared_data[] with data loaded from
// the input arrays
barrier();
memoryBarrierShared();
// For each step...
for (step = 0; step < steps; step++) {
// Calculate the read and write index in the
// shared array
mask = (1 << step) - 1;
rd_id = ((id >> step) << (step + 1)) + mask;
wr_id = rd_id + 1 + (id & mask);
// Accumulate the read data into our element
shared_data[wr_id] = AddUint64(shared_data[rd_id], shared_data[wr_id]);
// Synchronize again to make sure that everyone
// has caught up with us
barrier();
memoryBarrierShared();
// do subgroup Prefix Sum using Hillis and Steele's algorithm
uvec2 subgroupInclusiveAddUint64(uvec2 value) {
uvec2 result = value;
for (uint i = 1; i < gl_SubgroupSize; i *= 2) {
if (i <= gl_SubgroupInvocationID) {
uvec2 other = subgroupShuffleUp(result, i); // get value from subgroup_inv_id - i;
result = AddUint64(result, other);
}
// Add the accumulation
shared_data[id * 2] = AddUint64(shared_data[id * 2], base_value_1);
shared_data[id * 2 + 1] = AddUint64(shared_data[id * 2 + 1], base_value_2);
barrier();
memoryBarrierShared();
}
return result;
}
// Finally write our data back to the output buffer
output_data[id * 2] = shared_data[id * 2];
output_data[id * 2 + 1] = shared_data[id * 2 + 1];
if (id == 0) {
// Writes down the results to the output buffer and to the accumulation buffer
void WriteResults(uvec2 result) {
uint current_global_id = gl_GlobalInvocationID.x;
uvec2 base_data = current_global_id < max_accumulation_base ? accumulated_data : uvec2(0);
output_data[current_global_id] = result + base_data;
if (max_accumulation_base >= accumulation_limit + 1) {
accumulated_data = shared_data[accumulation_limit];
if (current_global_id == accumulation_limit) {
accumulated_data = result;
}
return;
}
uvec2 value_1 = shared_data[max_accumulation_base];
uvec2 value_2 = shared_data[accumulation_limit];
accumulated_data = AddUint64(value_1, -value_2);
// We have that ugly case in which the accumulation data is reset in the middle somewhere.
barrier();
groupMemoryBarrier();
if (current_global_id == accumulation_limit) {
uvec2 value_1 = output_data[max_accumulation_base];
accumulated_data = AddUint64(result, -value_1);
}
}
void main() {
uint subgroup_inv_id = gl_SubgroupInvocationID;
uint subgroup_id = gl_SubgroupID;
uint last_subgroup_id = subgroupMax(subgroup_inv_id);
uint current_global_id = gl_GlobalInvocationID.x;
uint total_work = gl_NumWorkGroups.x * gl_WorkGroupSize.x;
uvec2 data = input_data[current_global_id];
// make sure all input data has been loaded
subgroupBarrier();
subgroupMemoryBarrier();
uvec2 result = subgroupInclusiveAddUint64(data);
// if we had less queries than our subgroup, just write down the results.
if (total_work <= gl_SubgroupSize) { // This condition is constant per dispatch.
WriteResults(result);
return;
}
// We now have more, so lets write the last result into shared memory.
// Only pick the last subgroup.
if (subgroup_inv_id == last_subgroup_id) {
shared_data[subgroup_id] = result;
}
// wait until everyone loaded their stuffs
barrier();
memoryBarrierShared();
// Case 1: the total work for the grouped results can be calculated in a single subgroup
// operation (about 1024 queries).
uint total_extra_work = gl_NumSubgroups * gl_NumWorkGroups.x;
if (total_extra_work <= gl_SubgroupSize) { // This condition is constant per dispatch.
if (subgroup_id != 0) {
uvec2 tmp = shared_data[subgroup_inv_id];
subgroupBarrier();
subgroupMemoryBarrierShared();
tmp = subgroupInclusiveAddUint64(tmp);
result = AddUint64(result, subgroupShuffle(tmp, subgroup_id - 1));
}
WriteResults(result);
return;
}
// Case 2: our work amount is huge, so lets do it in O(log n) steps.
const uint extra = (total_extra_work ^ (total_extra_work - 1)) != 0 ? 1 : 0;
const uint steps = 1 << (findMSB(total_extra_work) + extra);
uint step;
// Hillis and Steele's algorithm
for (step = 1; step < steps; step *= 2) {
if (current_global_id < steps && current_global_id >= step) {
uvec2 current = shared_data[current_global_id];
uvec2 other = shared_data[current_global_id - step];
shared_data[current_global_id] = AddUint64(current, other);
}
// steps is constant, so this will always execute in ever workgroup's thread.
barrier();
memoryBarrierShared();
}
// Only add results for groups higher than 0
if (subgroup_id != 0) {
result = AddUint64(result, shared_data[subgroup_id - 1]);
}
// Just write the final results. We are done
WriteResults(result);
}

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@ -0,0 +1,120 @@
// SPDX-FileCopyrightText: Copyright 2015 Graham Sellers, Richard Wright Jr. and Nicholas Haemel
// SPDX-License-Identifier: MIT
// Code obtained from OpenGL SuperBible, Seventh Edition by Graham Sellers, Richard Wright Jr. and
// Nicholas Haemel. Modified to suit needs.
#version 460 core
#ifdef VULKAN
#define HAS_EXTENDED_TYPES 1
#define BEGIN_PUSH_CONSTANTS layout(push_constant) uniform PushConstants {
#define END_PUSH_CONSTANTS };
#define UNIFORM(n)
#define BINDING_INPUT_BUFFER 0
#define BINDING_OUTPUT_IMAGE 1
#else // ^^^ Vulkan ^^^ // vvv OpenGL vvv
#extension GL_NV_gpu_shader5 : enable
#ifdef GL_NV_gpu_shader5
#define HAS_EXTENDED_TYPES 1
#else
#define HAS_EXTENDED_TYPES 0
#endif
#define BEGIN_PUSH_CONSTANTS
#define END_PUSH_CONSTANTS
#define UNIFORM(n) layout(location = n) uniform
#define BINDING_INPUT_BUFFER 0
#define BINDING_OUTPUT_IMAGE 0
#endif
BEGIN_PUSH_CONSTANTS
UNIFORM(0) uint max_accumulation_base;
UNIFORM(1) uint accumulation_limit;
END_PUSH_CONSTANTS
layout(local_size_x = 32) in;
layout(std430, binding = 0) readonly buffer block1 {
uvec2 input_data[gl_WorkGroupSize.x];
};
layout(std430, binding = 1) writeonly coherent buffer block2 {
uvec2 output_data[gl_WorkGroupSize.x];
};
layout(std430, binding = 2) coherent buffer block3 {
uvec2 accumulated_data;
};
shared uvec2 shared_data[gl_WorkGroupSize.x * 2];
uvec2 AddUint64(uvec2 value_1, uvec2 value_2) {
uint carry = 0;
uvec2 result;
result.x = uaddCarry(value_1.x, value_2.x, carry);
result.y = value_1.y + value_2.y + carry;
return result;
}
void main(void) {
uint id = gl_LocalInvocationID.x;
uvec2 base_value_1 = (id * 2) < max_accumulation_base ? accumulated_data : uvec2(0);
uvec2 base_value_2 = (id * 2 + 1) < max_accumulation_base ? accumulated_data : uvec2(0);
uint work_size = gl_WorkGroupSize.x;
uint rd_id;
uint wr_id;
uint mask;
uvec2 input_1 = input_data[id * 2];
uvec2 input_2 = input_data[id * 2 + 1];
// The number of steps is the log base 2 of the
// work group size, which should be a power of 2
const uint steps = uint(log2(work_size)) + 1;
uint step = 0;
// Each invocation is responsible for the content of
// two elements of the output array
shared_data[id * 2] = input_1;
shared_data[id * 2 + 1] = input_2;
// Synchronize to make sure that everyone has initialized
// their elements of shared_data[] with data loaded from
// the input arrays
barrier();
memoryBarrierShared();
// For each step...
for (step = 0; step < steps; step++) {
// Calculate the read and write index in the
// shared array
mask = (1 << step) - 1;
rd_id = ((id >> step) << (step + 1)) + mask;
wr_id = rd_id + 1 + (id & mask);
// Accumulate the read data into our element
shared_data[wr_id] = AddUint64(shared_data[rd_id], shared_data[wr_id]);
// Synchronize again to make sure that everyone
// has caught up with us
barrier();
memoryBarrierShared();
}
// Add the accumulation
shared_data[id * 2] = AddUint64(shared_data[id * 2], base_value_1);
shared_data[id * 2 + 1] = AddUint64(shared_data[id * 2 + 1], base_value_2);
barrier();
memoryBarrierShared();
// Finally write our data back to the output buffer
output_data[id * 2] = shared_data[id * 2];
output_data[id * 2 + 1] = shared_data[id * 2 + 1];
if (id == 0) {
if (max_accumulation_base >= accumulation_limit + 1) {
accumulated_data = shared_data[accumulation_limit];
return;
}
uvec2 value_1 = shared_data[max_accumulation_base];
uvec2 value_2 = shared_data[accumulation_limit];
accumulated_data = AddUint64(value_1, -value_2);
}
}

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@ -13,6 +13,7 @@
#include "common/div_ceil.h"
#include "video_core/host_shaders/astc_decoder_comp_spv.h"
#include "video_core/host_shaders/queries_prefix_scan_sum_comp_spv.h"
#include "video_core/host_shaders/queries_prefix_scan_sum_nosubgroups_comp_spv.h"
#include "video_core/host_shaders/resolve_conditional_render_comp_spv.h"
#include "video_core/host_shaders/vulkan_quad_indexed_comp_spv.h"
#include "video_core/host_shaders/vulkan_uint8_comp_spv.h"
@ -187,7 +188,8 @@ ComputePass::ComputePass(const Device& device_, DescriptorPool& descriptor_pool,
vk::Span<VkDescriptorSetLayoutBinding> bindings,
vk::Span<VkDescriptorUpdateTemplateEntry> templates,
const DescriptorBankInfo& bank_info,
vk::Span<VkPushConstantRange> push_constants, std::span<const u32> code)
vk::Span<VkPushConstantRange> push_constants, std::span<const u32> code,
std::optional<u32> optional_subgroup_size)
: device{device_} {
descriptor_set_layout = device.GetLogical().CreateDescriptorSetLayout({
.sType = VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO,
@ -228,13 +230,19 @@ ComputePass::ComputePass(const Device& device_, DescriptorPool& descriptor_pool,
.pCode = code.data(),
});
device.SaveShader(code);
const VkPipelineShaderStageRequiredSubgroupSizeCreateInfoEXT subgroup_size_ci{
.sType = VK_STRUCTURE_TYPE_PIPELINE_SHADER_STAGE_REQUIRED_SUBGROUP_SIZE_CREATE_INFO_EXT,
.pNext = nullptr,
.requiredSubgroupSize = optional_subgroup_size ? *optional_subgroup_size : 32U,
};
bool use_setup_size = device.IsExtSubgroupSizeControlSupported() && optional_subgroup_size;
pipeline = device.GetLogical().CreateComputePipeline({
.sType = VK_STRUCTURE_TYPE_COMPUTE_PIPELINE_CREATE_INFO,
.pNext = nullptr,
.flags = 0,
.stage{
.sType = VK_STRUCTURE_TYPE_PIPELINE_SHADER_STAGE_CREATE_INFO,
.pNext = nullptr,
.pNext = use_setup_size ? &subgroup_size_ci : nullptr,
.flags = 0,
.stage = VK_SHADER_STAGE_COMPUTE_BIT,
.module = *module,
@ -399,10 +407,17 @@ void ConditionalRenderingResolvePass::Resolve(VkBuffer dst_buffer, VkBuffer src_
QueriesPrefixScanPass::QueriesPrefixScanPass(
const Device& device_, Scheduler& scheduler_, DescriptorPool& descriptor_pool_,
ComputePassDescriptorQueue& compute_pass_descriptor_queue_)
: ComputePass(device_, descriptor_pool_, QUERIES_SCAN_DESCRIPTOR_SET_BINDINGS,
: ComputePass(
device_, descriptor_pool_, QUERIES_SCAN_DESCRIPTOR_SET_BINDINGS,
QUERIES_SCAN_DESCRIPTOR_UPDATE_TEMPLATE, QUERIES_SCAN_BANK_INFO,
COMPUTE_PUSH_CONSTANT_RANGE<sizeof(QueriesPrefixScanPushConstants)>,
QUERIES_PREFIX_SCAN_SUM_COMP_SPV),
device_.IsSubgroupFeatureSupported(VK_SUBGROUP_FEATURE_BASIC_BIT) &&
device_.IsSubgroupFeatureSupported(VK_SUBGROUP_FEATURE_ARITHMETIC_BIT) &&
device_.IsSubgroupFeatureSupported(VK_SUBGROUP_FEATURE_SHUFFLE_BIT) &&
device_.IsSubgroupFeatureSupported(VK_SUBGROUP_FEATURE_SHUFFLE_RELATIVE_BIT)
? std::span<const u32>(QUERIES_PREFIX_SCAN_SUM_COMP_SPV)
: std::span<const u32>(QUERIES_PREFIX_SCAN_SUM_NOSUBGROUPS_COMP_SPV),
{32}),
scheduler{scheduler_}, compute_pass_descriptor_queue{compute_pass_descriptor_queue_} {}
void QueriesPrefixScanPass::Run(VkBuffer accumulation_buffer, VkBuffer dst_buffer,

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@ -3,6 +3,7 @@
#pragma once
#include <optional>
#include <span>
#include <utility>
@ -31,7 +32,8 @@ public:
vk::Span<VkDescriptorSetLayoutBinding> bindings,
vk::Span<VkDescriptorUpdateTemplateEntry> templates,
const DescriptorBankInfo& bank_info,
vk::Span<VkPushConstantRange> push_constants, std::span<const u32> code);
vk::Span<VkPushConstantRange> push_constants, std::span<const u32> code,
std::optional<u32> optional_subgroup_size = std::nullopt);
~ComputePass();
protected:

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@ -1376,10 +1376,10 @@ bool QueryCacheRuntime::HostConditionalRenderingCompareValues(VideoCommon::Looku
return true;
}
}
/*if (!is_in_bc[0] && !is_in_bc[1]) {
if (!is_in_bc[0] && !is_in_bc[1]) {
// Both queries are in query cache, it's best to just flush.
return true;
}*/
}
HostConditionalRenderingCompareBCImpl(object_1.address, equal_check);
return true;
}