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329 lines
11 KiB
C++
329 lines
11 KiB
C++
// Copyright 2016 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 "VideoBackends/Vulkan/StreamBuffer.h"
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#include <algorithm>
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#include <cstdint>
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#include <functional>
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#include "Common/Align.h"
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#include "Common/Assert.h"
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#include "Common/MsgHandler.h"
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#include "VideoBackends/Vulkan/CommandBufferManager.h"
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#include "VideoBackends/Vulkan/VulkanContext.h"
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namespace Vulkan
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{
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StreamBuffer::StreamBuffer(VkBufferUsageFlags usage, u32 size) : m_usage(usage), m_size(size)
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{
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}
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StreamBuffer::~StreamBuffer()
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{
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if (m_host_pointer)
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vkUnmapMemory(g_vulkan_context->GetDevice(), m_memory);
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if (m_buffer != VK_NULL_HANDLE)
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g_command_buffer_mgr->DeferBufferDestruction(m_buffer);
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if (m_memory != VK_NULL_HANDLE)
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g_command_buffer_mgr->DeferDeviceMemoryDestruction(m_memory);
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}
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std::unique_ptr<StreamBuffer> StreamBuffer::Create(VkBufferUsageFlags usage, u32 size)
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{
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std::unique_ptr<StreamBuffer> buffer = std::make_unique<StreamBuffer>(usage, size);
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if (!buffer->AllocateBuffer())
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return nullptr;
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return buffer;
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}
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bool StreamBuffer::AllocateBuffer()
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{
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// Create the buffer descriptor
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VkBufferCreateInfo buffer_create_info = {
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VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO, // VkStructureType sType
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nullptr, // const void* pNext
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0, // VkBufferCreateFlags flags
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static_cast<VkDeviceSize>(m_size), // VkDeviceSize size
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m_usage, // VkBufferUsageFlags usage
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VK_SHARING_MODE_EXCLUSIVE, // VkSharingMode sharingMode
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0, // uint32_t queueFamilyIndexCount
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nullptr // const uint32_t* pQueueFamilyIndices
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};
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VkBuffer buffer = VK_NULL_HANDLE;
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VkResult res =
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vkCreateBuffer(g_vulkan_context->GetDevice(), &buffer_create_info, nullptr, &buffer);
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if (res != VK_SUCCESS)
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{
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LOG_VULKAN_ERROR(res, "vkCreateBuffer failed: ");
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return false;
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}
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// Get memory requirements (types etc) for this buffer
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VkMemoryRequirements memory_requirements;
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vkGetBufferMemoryRequirements(g_vulkan_context->GetDevice(), buffer, &memory_requirements);
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// Aim for a coherent mapping if possible.
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u32 memory_type_index = g_vulkan_context->GetUploadMemoryType(memory_requirements.memoryTypeBits,
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&m_coherent_mapping);
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// Allocate memory for backing this buffer
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VkMemoryAllocateInfo memory_allocate_info = {
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VK_STRUCTURE_TYPE_MEMORY_ALLOCATE_INFO, // VkStructureType sType
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nullptr, // const void* pNext
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memory_requirements.size, // VkDeviceSize allocationSize
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memory_type_index // uint32_t memoryTypeIndex
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};
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VkDeviceMemory memory = VK_NULL_HANDLE;
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res = vkAllocateMemory(g_vulkan_context->GetDevice(), &memory_allocate_info, nullptr, &memory);
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if (res != VK_SUCCESS)
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{
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LOG_VULKAN_ERROR(res, "vkAllocateMemory failed: ");
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vkDestroyBuffer(g_vulkan_context->GetDevice(), buffer, nullptr);
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return false;
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}
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// Bind memory to buffer
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res = vkBindBufferMemory(g_vulkan_context->GetDevice(), buffer, memory, 0);
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if (res != VK_SUCCESS)
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{
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LOG_VULKAN_ERROR(res, "vkBindBufferMemory failed: ");
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vkDestroyBuffer(g_vulkan_context->GetDevice(), buffer, nullptr);
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vkFreeMemory(g_vulkan_context->GetDevice(), memory, nullptr);
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return false;
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}
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// Map this buffer into user-space
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void* mapped_ptr = nullptr;
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res = vkMapMemory(g_vulkan_context->GetDevice(), memory, 0, m_size, 0, &mapped_ptr);
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if (res != VK_SUCCESS)
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{
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LOG_VULKAN_ERROR(res, "vkMapMemory failed: ");
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vkDestroyBuffer(g_vulkan_context->GetDevice(), buffer, nullptr);
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vkFreeMemory(g_vulkan_context->GetDevice(), memory, nullptr);
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return false;
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}
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// Unmap current host pointer (if there was a previous buffer)
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if (m_host_pointer)
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vkUnmapMemory(g_vulkan_context->GetDevice(), m_memory);
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// Destroy the backings for the buffer after the command buffer executes
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if (m_buffer != VK_NULL_HANDLE)
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g_command_buffer_mgr->DeferBufferDestruction(m_buffer);
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if (m_memory != VK_NULL_HANDLE)
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g_command_buffer_mgr->DeferDeviceMemoryDestruction(m_memory);
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// Replace with the new buffer
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m_buffer = buffer;
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m_memory = memory;
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m_host_pointer = reinterpret_cast<u8*>(mapped_ptr);
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m_current_offset = 0;
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m_current_gpu_position = 0;
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m_tracked_fences.clear();
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return true;
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}
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bool StreamBuffer::ReserveMemory(u32 num_bytes, u32 alignment)
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{
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const u32 required_bytes = num_bytes + alignment;
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// Check for sane allocations
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if (required_bytes > m_size)
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{
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PanicAlert("Attempting to allocate %u bytes from a %u byte stream buffer",
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static_cast<uint32_t>(num_bytes), static_cast<uint32_t>(m_size));
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return false;
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}
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// Is the GPU behind or up to date with our current offset?
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UpdateCurrentFencePosition();
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if (m_current_offset >= m_current_gpu_position)
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{
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const u32 remaining_bytes = m_size - m_current_offset;
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if (required_bytes <= remaining_bytes)
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{
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// Place at the current position, after the GPU position.
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m_current_offset = Common::AlignUp(m_current_offset, alignment);
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m_last_allocation_size = num_bytes;
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return true;
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}
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// Check for space at the start of the buffer
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// We use < here because we don't want to have the case of m_current_offset ==
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// m_current_gpu_position. That would mean the code above would assume the
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// GPU has caught up to us, which it hasn't.
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if (required_bytes < m_current_gpu_position)
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{
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// Reset offset to zero, since we're allocating behind the gpu now
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m_current_offset = 0;
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m_last_allocation_size = num_bytes;
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return true;
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}
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}
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// Is the GPU ahead of our current offset?
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if (m_current_offset < m_current_gpu_position)
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{
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// We have from m_current_offset..m_current_gpu_position space to use.
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const u32 remaining_bytes = m_current_gpu_position - m_current_offset;
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if (required_bytes < remaining_bytes)
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{
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// Place at the current position, since this is still behind the GPU.
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m_current_offset = Common::AlignUp(m_current_offset, alignment);
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m_last_allocation_size = num_bytes;
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return true;
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}
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}
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// Can we find a fence to wait on that will give us enough memory?
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if (WaitForClearSpace(required_bytes))
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{
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m_current_offset = Common::AlignUp(m_current_offset, alignment);
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m_last_allocation_size = num_bytes;
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return true;
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}
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// We tried everything we could, and still couldn't get anything. This means that too much space
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// in the buffer is being used by the command buffer currently being recorded. Therefore, the
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// only option is to execute it, and wait until it's done.
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return false;
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}
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void StreamBuffer::CommitMemory(u32 final_num_bytes)
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{
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ASSERT((m_current_offset + final_num_bytes) <= m_size);
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ASSERT(final_num_bytes <= m_last_allocation_size);
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// For non-coherent mappings, flush the memory range
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if (!m_coherent_mapping)
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{
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VkMappedMemoryRange range = {VK_STRUCTURE_TYPE_MAPPED_MEMORY_RANGE, nullptr, m_memory,
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m_current_offset, final_num_bytes};
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vkFlushMappedMemoryRanges(g_vulkan_context->GetDevice(), 1, &range);
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}
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m_current_offset += final_num_bytes;
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}
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void StreamBuffer::UpdateCurrentFencePosition()
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{
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// Don't create a tracking entry if the GPU is caught up with the buffer.
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if (m_current_offset == m_current_gpu_position)
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return;
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// Has the offset changed since the last fence?
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const u64 counter = g_command_buffer_mgr->GetCurrentFenceCounter();
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if (!m_tracked_fences.empty() && m_tracked_fences.back().first == counter)
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{
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// Still haven't executed a command buffer, so just update the offset.
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m_tracked_fences.back().second = m_current_offset;
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return;
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}
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// New buffer, so update the GPU position while we're at it.
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UpdateGPUPosition();
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m_tracked_fences.emplace_back(counter, m_current_offset);
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}
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void StreamBuffer::UpdateGPUPosition()
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{
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auto start = m_tracked_fences.begin();
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auto end = start;
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const u64 completed_counter = g_command_buffer_mgr->GetCompletedFenceCounter();
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while (end != m_tracked_fences.end() && completed_counter >= end->first)
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{
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m_current_gpu_position = end->second;
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++end;
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}
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if (start != end)
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m_tracked_fences.erase(start, end);
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}
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bool StreamBuffer::WaitForClearSpace(u32 num_bytes)
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{
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u32 new_offset = 0;
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u32 new_gpu_position = 0;
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auto iter = m_tracked_fences.begin();
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for (; iter != m_tracked_fences.end(); iter++)
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{
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// Would this fence bring us in line with the GPU?
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// This is the "last resort" case, where a command buffer execution has been forced
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// after no additional data has been written to it, so we can assume that after the
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// fence has been signaled the entire buffer is now consumed.
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u32 gpu_position = iter->second;
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if (m_current_offset == gpu_position)
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{
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new_offset = 0;
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new_gpu_position = 0;
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break;
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}
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// Assuming that we wait for this fence, are we allocating in front of the GPU?
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if (m_current_offset > gpu_position)
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{
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// This would suggest the GPU has now followed us and wrapped around, so we have from
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// m_current_position..m_size free, as well as and 0..gpu_position.
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const u32 remaining_space_after_offset = m_size - m_current_offset;
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if (remaining_space_after_offset >= num_bytes)
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{
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// Switch to allocating in front of the GPU, using the remainder of the buffer.
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new_offset = m_current_offset;
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new_gpu_position = gpu_position;
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break;
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}
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// We can wrap around to the start, behind the GPU, if there is enough space.
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// We use > here because otherwise we'd end up lining up with the GPU, and then the
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// allocator would assume that the GPU has consumed what we just wrote.
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if (gpu_position > num_bytes)
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{
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new_offset = 0;
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new_gpu_position = gpu_position;
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break;
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}
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}
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else
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{
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// We're currently allocating behind the GPU. This would give us between the current
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// offset and the GPU position worth of space to work with. Again, > because we can't
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// align the GPU position with the buffer offset.
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u32 available_space_inbetween = gpu_position - m_current_offset;
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if (available_space_inbetween > num_bytes)
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{
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// Leave the offset as-is, but update the GPU position.
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new_offset = m_current_offset;
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new_gpu_position = gpu_position;
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break;
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}
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}
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}
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// Did any fences satisfy this condition?
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// Has the command buffer been executed yet? If not, the caller should execute it.
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if (iter == m_tracked_fences.end() ||
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iter->first == g_command_buffer_mgr->GetCurrentFenceCounter())
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{
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return false;
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}
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// Wait until this fence is signaled. This will fire the callback, updating the GPU position.
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g_command_buffer_mgr->WaitForFenceCounter(iter->first);
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m_tracked_fences.erase(m_tracked_fences.begin(),
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m_current_offset == iter->second ? m_tracked_fences.end() : ++iter);
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m_current_offset = new_offset;
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m_current_gpu_position = new_gpu_position;
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return true;
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}
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} // namespace Vulkan
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