public VkBuffer(VkGraphicsDevice gd, ulong sizeInBytes, bool dynamic, VkBufferUsageFlags usage)
{
_gd = gd;
SizeInBytes = sizeInBytes;
usage |= VkBufferUsageFlags.TransferSrc | VkBufferUsageFlags.TransferDst;
VkBufferCreateInfo bufferCI = VkBufferCreateInfo.New();
bufferCI.size = sizeInBytes;
bufferCI.usage = usage;
VkResult result = vkCreateBuffer(gd.Device, ref bufferCI, null, out _deviceBuffer);
CheckResult(result);
vkGetBufferMemoryRequirements(gd.Device, _deviceBuffer, out VkMemoryRequirements bufferMemoryRequirements);
VkMemoryBlock memoryToken = gd.MemoryManager.Allocate(
gd.PhysicalDeviceMemProperties,
bufferMemoryRequirements.memoryTypeBits,
VkMemoryPropertyFlags.HostVisible | VkMemoryPropertyFlags.HostCoherent,
dynamic,
bufferMemoryRequirements.size,
bufferMemoryRequirements.alignment);
_memory = memoryToken;
result = vkBindBufferMemory(gd.Device, _deviceBuffer, _memory.DeviceMemory, _memory.Offset);
CheckResult(result);
}
public TransientBufferManager(VkBufferUsageFlags usage, uint size)
{
BufferUsageFlags = usage;
Size = size;
if (usage == VkBufferUsageFlags.UniformBuffer)
{
alignment = Device.Properties.limits.minUniformBufferOffsetAlignment;
}
else if (usage == VkBufferUsageFlags.StorageBuffer)
{
alignment = Device.Properties.limits.minStorageBufferOffsetAlignment;
}
else if (usage == VkBufferUsageFlags.UniformTexelBuffer)
{
alignment = Device.Properties.limits.minTexelBufferOffsetAlignment;
}
else if (usage == VkBufferUsageFlags.IndexBuffer || usage == VkBufferUsageFlags.VertexBuffer || usage == VkBufferUsageFlags.IndirectBuffer)
{
// Used to calculate the offset, required when allocating memory (its value should be power of 2)
alignment = 16;
}
else
{
throw new Exception("Usage not recognised");
}
}
public VkDeviceBuffer(
VkRenderContext rc,
ulong size,
VkBufferUsageFlags usage,
VkMemoryPropertyFlags memoryProperties,
bool dynamic)
{
_rc = rc;
usage |= VkBufferUsageFlags.TransferSrc;
_usage = usage;
_memoryProperties = memoryProperties;
_isDynamic = dynamic;
VkBufferCreateInfo bufferCI = VkBufferCreateInfo.New();
bufferCI.size = size;
bufferCI.usage = _usage;
VkResult result = vkCreateBuffer(rc.Device, ref bufferCI, null, out _buffer);
CheckResult(result);
vkGetBufferMemoryRequirements(rc.Device, _buffer, out _bufferMemoryRequirements);
_bufferCapacity = _bufferMemoryRequirements.size;
uint memoryType = FindMemoryType(rc.PhysicalDevice, _bufferMemoryRequirements.memoryTypeBits, memoryProperties);
VkMemoryBlock memoryToken = rc.MemoryManager.Allocate(
memoryType,
_bufferMemoryRequirements.size,
_bufferMemoryRequirements.alignment);
_memory = memoryToken;
vkBindBufferMemory(rc.Device, _buffer, _memory.DeviceMemory, _memory.Offset);
}
public Buffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropFlags, ulong stride, ulong count,
VkSharingMode sharingMode = VkSharingMode.Exclusive, uint[] queueFamilyIndices = null, IntPtr data = default)
{
Stride = stride;
Count = count;
Size = stride * count;
// Create the buffer handle
var bufferCreateInfo = new VkBufferCreateInfo(usageFlags, Size, queueFamilyIndices)
{
sharingMode = sharingMode
};
if (data != null && (memoryPropertyFlags & VkMemoryPropertyFlags.HostCoherent) == 0)
{
bufferCreateInfo.usage |= VkBufferUsageFlags.TransferDst;
}
handle = Device.CreateBuffer(ref bufferCreateInfo);
UsageFlags = usageFlags;
memoryPropertyFlags = memoryPropFlags;
Device.GetBufferMemoryRequirements(handle, out VkMemoryRequirements memReqs);
Allocate(memReqs);
Device.BindBufferMemory(handle, memory, 0);
if (data != IntPtr.Zero)
{
SetData(data, 0, Size);
}
SetupDescriptor();
}
//private void Flush(UInt64 start, UInt64 length) {
// VkMappedMemoryRange memoryRange = VkMappedMemoryRange.New();
// memoryRange.memory = vkMemory;
// memoryRange.size = length;
// memoryRange.offset = start;
// Util.CheckResult(vkFlushMappedMemoryRanges(device.device, 1, ref memoryRange));
//}
private void Allocate()
{
if (usageHint == BufferMemoryUsageHint.Static)
{
bufferUsageFlags |= VkBufferUsageFlags.TransferDst;
}
// Create the buffer handle
VkBufferCreateInfo bufferCreateInfo = Initializers.bufferCreateInfo(bufferUsageFlags, size);
bufferCreateInfo.sharingMode = VkSharingMode.Exclusive;
Util.CheckResult(vkCreateBuffer(device.device, &bufferCreateInfo, null, out vkBuffer));
// Create the memory backing up the buffer handle
VkMemoryRequirements memReqs;
vkGetBufferMemoryRequirements(device.device, vkBuffer, &memReqs);
var hostVisible = usageHint == BufferMemoryUsageHint.Dynamic;
memory = device.memoryAllocator.Allocate(memReqs, hostVisible);
// Attach the memory to the buffer object
Util.CheckResult(vkBindBufferMemory(device.device, vkBuffer, memory.vkDeviceMemory, memory.offset));
}
public VkBuffer(VkGraphicsDevice gd, uint sizeInBytes, BufferUsage usage)
{
_gd = gd;
SizeInBytes = sizeInBytes;
Usage = usage;
VkBufferUsageFlags vkUsage = VkBufferUsageFlags.TransferSrc | VkBufferUsageFlags.TransferDst;
if ((usage & BufferUsage.VertexBuffer) == BufferUsage.VertexBuffer)
{
vkUsage |= VkBufferUsageFlags.VertexBuffer;
}
if ((usage & BufferUsage.IndexBuffer) == BufferUsage.IndexBuffer)
{
vkUsage |= VkBufferUsageFlags.IndexBuffer;
}
if ((usage & BufferUsage.UniformBuffer) == BufferUsage.UniformBuffer)
{
vkUsage |= VkBufferUsageFlags.UniformBuffer;
}
if ((usage & BufferUsage.StructuredBufferReadWrite) == BufferUsage.StructuredBufferReadWrite ||
(usage & BufferUsage.StructuredBufferReadOnly) == BufferUsage.StructuredBufferReadOnly)
{
vkUsage |= VkBufferUsageFlags.StorageBuffer;
}
if ((usage & BufferUsage.IndirectBuffer) == BufferUsage.IndirectBuffer)
{
vkUsage |= VkBufferUsageFlags.IndirectBuffer;
}
VkBufferCreateInfo bufferCI = VkBufferCreateInfo.New();
bufferCI.size = sizeInBytes;
bufferCI.usage = vkUsage;
VkResult result = vkCreateBuffer(gd.Device, ref bufferCI, null, out _deviceBuffer);
CheckResult(result);
vkGetBufferMemoryRequirements(gd.Device, _deviceBuffer, out _bufferMemoryRequirements);
bool hostVisible = (usage & BufferUsage.Dynamic) == BufferUsage.Dynamic ||
(usage & BufferUsage.Staging) == BufferUsage.Staging;
VkMemoryPropertyFlags memoryPropertyFlags =
hostVisible
? VkMemoryPropertyFlags.HostVisible | VkMemoryPropertyFlags.HostCoherent
: VkMemoryPropertyFlags.DeviceLocal;
VkMemoryBlock memoryToken = gd.MemoryManager.Allocate(
gd.PhysicalDeviceMemProperties,
_bufferMemoryRequirements.memoryTypeBits,
memoryPropertyFlags,
hostVisible,
_bufferMemoryRequirements.size,
_bufferMemoryRequirements.alignment);
_memory = memoryToken;
result = vkBindBufferMemory(gd.Device, _deviceBuffer, _memory.DeviceMemory, _memory.Offset);
CheckResult(result);
}
public DeviceBuffer(GraphicsDevice device, UInt64 size, BufferUsageFlags flags, BufferMemoryUsageHint usageHint)
{
this.device = device;
this.size = size;
this.bufferUsageFlags = (VkBufferUsageFlags)flags;
this.usageHint = usageHint;
Allocate();
}
internal DeviceBuffer(GraphicsDevice device, UInt64 size, void *data, BufferUsageFlags flags, BufferMemoryUsageHint usageHint)
{
this.device = device;
this.size = size;
this.bufferUsageFlags = (VkBufferUsageFlags)flags;
this.usageHint = usageHint;
Allocate();
StagingTransfer(0, size, data);
}
public SharedBuffer(VkBufferUsageFlags bufferUsage, uint size)
{
buffers[0] = new Buffer(bufferUsage, VkMemoryPropertyFlags.HostVisible, size);
buffers[0].Map(0, size);
buffers[1] = new Buffer(bufferUsage, VkMemoryPropertyFlags.HostVisible, size);
buffers[1].Map(0, size);
buffers[2] = new Buffer(bufferUsage, VkMemoryPropertyFlags.HostVisible, size);
buffers[2].Map(0, size);
}
/// <summary>
/// Create a vulkan buffer and automatically activate it. Automatic activation on startup implies to explicitly dispose the buffer.
/// </summary>
/// <param name="device">Logical Device.</param>
/// <param name="usage">a bitmask specifying allowed usages of the buffer</param>
/// <param name="_memoryPropertyFlags">Memory property flags.</param>
/// <param name="size">Desired size in byte of the buffer to be created.</param>
/// <param name="sharingMode">value specifying the sharing mode of the buffer when it will be accessed by multiple queue familie</param>
public Buffer(Device device, VkBufferUsageFlags usage, VkMemoryPropertyFlags _memoryPropertyFlags, UInt64 size, VkSharingMode sharingMode = VkSharingMode.Exclusive)
: base(device, _memoryPropertyFlags)
{
createInfo.size = size;
createInfo.usage = usage;
createInfo.sharingMode = VkSharingMode.Exclusive;
Activate();
}
public Buffer(Device device, VkBufferUsageFlags usage, VkMemoryPropertyFlags _memoryPropertyFlags, UInt64 size)
: base(device, _memoryPropertyFlags)
{
createInfo.size = size;
createInfo.usage = usage;
createInfo.sharingMode = VkSharingMode.Exclusive;
Activate(); //DONT OVERRIDE Activate in derived classes!!!!
}
public VkResult createBuffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropertyFlags, ulong size, out VkBuffer buffer, out VkDeviceMemory memory, void *data = null)
{
VkBuffer b;
VkDeviceMemory dm;
VkResult result = createBuffer(usageFlags, memoryPropertyFlags, size, &b, &dm, data);
buffer = b;
memory = dm;
return(result);
}
public SharedBuffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropFlags, ulong size,
VkSharingMode sharingMode = VkSharingMode.Exclusive, uint[] queueFamilyIndices = null)
{
buffers[0] = new Buffer(usageFlags, memoryPropFlags, size, 1, sharingMode, queueFamilyIndices);
buffers[0].Map(0, size);
buffers[1] = new Buffer(usageFlags, memoryPropFlags, size, 1, sharingMode, queueFamilyIndices);
buffers[1].Map(0, size);
buffers[2] = new Buffer(usageFlags, memoryPropFlags, size, 1, sharingMode, queueFamilyIndices);
buffers[2].Map(0, size);
}
public static VkBufferCreateInfo bufferCreateInfo(
VkBufferUsageFlags usage,
ulong size)
{
VkBufferCreateInfo bufCreateInfo = VkBufferCreateInfo.New();
bufCreateInfo.usage = usage;
bufCreateInfo.size = size;
return(bufCreateInfo);
}
/// <summary>
/// Create and populate a mappable vulkan buffer.
/// </summary>
/// <param name="device">Logical Device.</param>
/// <param name="usage">Buffer Usage.</param>
/// <param name="data">an array of T which will be used to populate the buffer.</param>
/// <param name="keepMapped">If set to <c>true</c>, buffer will stay mapped after the constructor.</param>
/// <param name="coherentMem">If set to <c>true</c> vulkan memory with have the coherent flag.</param>
public HostBuffer(Device device, VkBufferUsageFlags usage, T[] data, bool keepMapped = false, bool coherentMem = true)
: base(device, usage, (ulong)(Marshal.SizeOf <T> () * data.Length), keepMapped, coherentMem)
{
TSize = Marshal.SizeOf <T> ();
Map();
Update(data, createInfo.size);
if (!keepMapped)
{
Unmap();
}
}
void CreateBuffer(long size, VkBufferUsageFlags usage, VkMemoryPropertyFlags properties, out VkBuffer buffer, out VkDeviceMemory memory)
{
var info = new VkBufferCreateInfo();
info.size = size;
info.usage = usage;
info.sharingMode = VkSharingMode.Exclusive;
buffer = new VkBuffer(device, info);
var allocInfo = new VkMemoryAllocateInfo();
allocInfo.allocationSize = buffer.Requirements.size;
allocInfo.memoryTypeIndex = FindMemoryType(buffer.Requirements.memoryTypeBits, properties);
memory = new VkDeviceMemory(device, allocInfo);
buffer.Bind(memory, 0);
}
private void CreateBuffer(ulong size, VkBufferUsageFlags usage, VkMemoryPropertyFlags properties, out IVkBuffer buffer, out IVkDeviceMemory bufferMemory)
{
buffer = device.CreateBuffer(new VkBufferCreateInfo
{
Size = size,
Usage = usage,
SharingMode = VkSharingMode.Exclusive
}, null).Object;
var memRequirements = buffer.GetMemoryRequirements();
bufferMemory = device.AllocateMemory(new VkMemoryAllocateInfo
{
AllocationSize = memRequirements.Size,
MemoryTypeIndex = FindMemoryType(memRequirements.MemoryTypeBits, properties)
}, null).Object;
buffer.BindMemory(bufferMemory, 0).CheckSuccess();
}
/**
* Create a buffer on the device
*
* @param usageFlags Usage flag bitmask for the buffer (i.e. index, vertex, uniform buffer)
* @param memoryPropertyFlags Memory properties for this buffer (i.e. device local, host visible, coherent)
* @param size Size of the buffer in byes
* @param buffer Pointer to the buffer handle acquired by the function
* @param memory Pointer to the memory handle acquired by the function
* @param data Pointer to the data that should be copied to the buffer after creation (optional, if not set, no data is copied over)
*
* @return VK_SUCCESS if buffer handle and memory have been created and (optionally passed) data has been copied
*/
public VkResult createBuffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropertyFlags, ulong size, VkBuffer *buffer, VkDeviceMemory *memory, void *data = null)
{
// Create the buffer handle
VkBufferCreateInfo bufferCreateInfo = Initializers.bufferCreateInfo(usageFlags, size);
bufferCreateInfo.sharingMode = VkSharingMode.Exclusive;
Util.CheckResult(vkCreateBuffer(LogicalDevice, &bufferCreateInfo, null, buffer));
// Create the memory backing up the buffer handle
VkMemoryRequirements memReqs;
VkMemoryAllocateInfo memAlloc = Initializers.memoryAllocateInfo();
vkGetBufferMemoryRequirements(LogicalDevice, *buffer, &memReqs);
memAlloc.allocationSize = memReqs.size;
// Find a memory type index that fits the properties of the buffer
memAlloc.memoryTypeIndex = GetMemoryType(memReqs.memoryTypeBits, memoryPropertyFlags);
Util.CheckResult(vkAllocateMemory(LogicalDevice, &memAlloc, null, memory));
// If a pointer to the buffer data has been passed, map the buffer and copy over the data
if (data != null)
{
void *mapped;
Util.CheckResult(vkMapMemory(LogicalDevice, *memory, 0, size, 0, &mapped));
Unsafe.CopyBlock(mapped, data, (uint)size);
// If host coherency hasn't been requested, do a manual flush to make writes visible
if ((memoryPropertyFlags & VkMemoryPropertyFlags.HostCoherent) == 0)
{
VkMappedMemoryRange mappedRange = Initializers.mappedMemoryRange();
mappedRange.memory = *memory;
mappedRange.offset = 0;
mappedRange.size = size;
vkFlushMappedMemoryRanges(LogicalDevice, 1, &mappedRange);
}
vkUnmapMemory(LogicalDevice, *memory);
}
// Attach the memory to the buffer object
Util.CheckResult(vkBindBufferMemory(LogicalDevice, *buffer, *memory, 0));
return(VkResult.Success);
}
public unsafe VkBufferCreateInfo(VkBufferUsageFlags usage, ulong size, uint[] queueFamilyIndices = default)
{
this.sType = VkStructureType.BufferCreateInfo;
this.pNext = null;
this.flags = VkBufferCreateFlags.None;
this.sharingMode = VkSharingMode.Exclusive;
if (queueFamilyIndices != null)
{
this.queueFamilyIndexCount = (uint)queueFamilyIndices.Length;
this.pQueueFamilyIndices = (uint *)Unsafe.AsPointer(ref queueFamilyIndices[0]);
}
else
{
this.queueFamilyIndexCount = 0;
this.pQueueFamilyIndices = null;
}
this.usage = usage;
this.size = size;
}
/**
* Create a buffer on the device
*
* @param usageFlags Usage flag bitmask for the buffer (i.e. index, vertex, uniform buffer)
* @param memoryPropertyFlags Memory properties for this buffer (i.e. device local, host visible, coherent)
* @param buffer Pointer to a vk::Vulkan buffer object
* @param size Size of the buffer in byes
* @param data Pointer to the data that should be copied to the buffer after creation (optional, if not set, no data is copied over)
*
* @return VK_SUCCESS if buffer handle and memory have been created and (optionally passed) data has been copied
*/
public VkResult createBuffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropertyFlags, vksBuffer buffer, ulong size, void *data = null)
{
buffer.device = _logicalDevice;
// Create the buffer handle
VkBufferCreateInfo bufferCreateInfo = VkBufferCreateInfo.New();
bufferCreateInfo.usage = usageFlags;
bufferCreateInfo.size = size;
Util.CheckResult(vkCreateBuffer(_logicalDevice, &bufferCreateInfo, null, out buffer.buffer));
// Create the memory backing up the buffer handle
VkMemoryRequirements memReqs;
VkMemoryAllocateInfo memAlloc = VkMemoryAllocateInfo.New();
vkGetBufferMemoryRequirements(_logicalDevice, buffer.buffer, &memReqs);
memAlloc.allocationSize = memReqs.size;
// Find a memory type index that fits the properties of the buffer
memAlloc.memoryTypeIndex = GetMemoryType(memReqs.memoryTypeBits, memoryPropertyFlags);
Util.CheckResult(vkAllocateMemory(_logicalDevice, &memAlloc, null, out buffer.memory));
buffer.alignment = memReqs.alignment;
buffer.size = memAlloc.allocationSize;
buffer.usageFlags = usageFlags;
buffer.memoryPropertyFlags = memoryPropertyFlags;
// If a pointer to the buffer data has been passed, map the buffer and copy over the data
if (data != null)
{
Util.CheckResult(buffer.map());
Unsafe.CopyBlock(buffer.mapped, data, (uint)size);
buffer.unmap();
}
// Initialize a default descriptor that covers the whole buffer size
buffer.setupDescriptor();
// Attach the memory to the buffer object
return(buffer.bind());
}
public GPUBuffer(Device device, VkBufferUsageFlags usage, UInt64 size)
: base(device, usage, VkMemoryPropertyFlags.DeviceLocal, size)
{
}
public Buffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropertyFlags, ulong size, VkSharingMode sharingMode = VkSharingMode.Exclusive)
: this(usageFlags, memoryPropertyFlags, size, 1, sharingMode)
{
}
public static Buffer Create(VkBufferUsageFlags usageFlags, bool dynamic, ulong stride, ulong count, IntPtr data = default)
{
return(new Buffer(usageFlags, dynamic ? VkMemoryPropertyFlags.HostVisible | VkMemoryPropertyFlags.HostCoherent : VkMemoryPropertyFlags.DeviceLocal, stride, count, VkSharingMode.Exclusive, null, data));
}
public VkBuffer(VkGraphicsDevice gd, uint sizeInBytes, BufferUsage usage, string callerMember = null)
{
_gd = gd;
SizeInBytes = sizeInBytes;
Usage = usage;
VkBufferUsageFlags vkUsage = VkBufferUsageFlags.TransferSrc | VkBufferUsageFlags.TransferDst;
if ((usage & BufferUsage.VertexBuffer) == BufferUsage.VertexBuffer)
{
vkUsage |= VkBufferUsageFlags.VertexBuffer;
}
if ((usage & BufferUsage.IndexBuffer) == BufferUsage.IndexBuffer)
{
vkUsage |= VkBufferUsageFlags.IndexBuffer;
}
if ((usage & BufferUsage.UniformBuffer) == BufferUsage.UniformBuffer)
{
vkUsage |= VkBufferUsageFlags.UniformBuffer;
}
if ((usage & BufferUsage.StructuredBufferReadWrite) == BufferUsage.StructuredBufferReadWrite ||
(usage & BufferUsage.StructuredBufferReadOnly) == BufferUsage.StructuredBufferReadOnly)
{
vkUsage |= VkBufferUsageFlags.StorageBuffer;
}
if ((usage & BufferUsage.IndirectBuffer) == BufferUsage.IndirectBuffer)
{
vkUsage |= VkBufferUsageFlags.IndirectBuffer;
}
VkBufferCreateInfo bufferCI = VkBufferCreateInfo.New();
bufferCI.size = sizeInBytes;
bufferCI.usage = vkUsage;
VkResult result = vkCreateBuffer(gd.Device, ref bufferCI, null, out _deviceBuffer);
CheckResult(result);
bool prefersDedicatedAllocation;
if (_gd.GetBufferMemoryRequirements2 != null)
{
VkBufferMemoryRequirementsInfo2KHR memReqInfo2 = VkBufferMemoryRequirementsInfo2KHR.New();
memReqInfo2.buffer = _deviceBuffer;
VkMemoryRequirements2KHR memReqs2 = VkMemoryRequirements2KHR.New();
VkMemoryDedicatedRequirementsKHR dedicatedReqs = VkMemoryDedicatedRequirementsKHR.New();
memReqs2.pNext = &dedicatedReqs;
_gd.GetBufferMemoryRequirements2(_gd.Device, &memReqInfo2, &memReqs2);
_bufferMemoryRequirements = memReqs2.memoryRequirements;
prefersDedicatedAllocation = dedicatedReqs.prefersDedicatedAllocation || dedicatedReqs.requiresDedicatedAllocation;
}
else
{
vkGetBufferMemoryRequirements(gd.Device, _deviceBuffer, out _bufferMemoryRequirements);
prefersDedicatedAllocation = false;
}
bool hostVisible = (usage & BufferUsage.Dynamic) == BufferUsage.Dynamic ||
(usage & BufferUsage.Staging) == BufferUsage.Staging;
VkMemoryPropertyFlags memoryPropertyFlags =
hostVisible
? VkMemoryPropertyFlags.HostVisible | VkMemoryPropertyFlags.HostCoherent
: VkMemoryPropertyFlags.DeviceLocal;
VkMemoryBlock memoryToken = gd.MemoryManager.Allocate(
gd.PhysicalDeviceMemProperties,
_bufferMemoryRequirements.memoryTypeBits,
memoryPropertyFlags,
hostVisible,
_bufferMemoryRequirements.size,
_bufferMemoryRequirements.alignment,
prefersDedicatedAllocation,
VkImage.Null,
_deviceBuffer);
_memory = memoryToken;
result = vkBindBufferMemory(gd.Device, _deviceBuffer, _memory.DeviceMemory, _memory.Offset);
CheckResult(result);
RefCount = new ResourceRefCount(DisposeCore);
}
public DynamicBuffer(VkBufferUsageFlags bufferUsage, uint size) : base(bufferUsage, size)
{
this.Size = size;
}
public unsafe Buffer(
Device device,
uint size,
VkBufferUsageFlags bufferUsageFlags,
VkMemoryPropertyFlags memoryProperty
)
{
if (size == 0)
{
throw new Exception("cannot create buffer with size of zero bytes");
}
//make sure buffer supports transfer data to and from buffer
if ((bufferUsageFlags & VkBufferUsageFlags.TransferSrc) == 0)
{
bufferUsageFlags |= VkBufferUsageFlags.TransferSrc;
}
if ((bufferUsageFlags & VkBufferUsageFlags.TransferDst) == 0)
{
bufferUsageFlags |= VkBufferUsageFlags.TransferDst;
}
//store parameter information
_size = size;
_device = device;
_bufferUsage = bufferUsageFlags;
_memoryProperty = memoryProperty;
var queueFamilyIndices = new NativeList <uint>();
foreach (var queueFamily in device.QueueFamilies)
{
queueFamilyIndices.Add(queueFamily.Index);
}
//buffer create info
var bufferCreateInfo = new VkBufferCreateInfo
{
sType = VkStructureType.BufferCreateInfo,
size = size,
usage = bufferUsageFlags,
sharingMode = VkSharingMode.Concurrent,
queueFamilyIndexCount = queueFamilyIndices.Count,
pQueueFamilyIndices = (uint *)queueFamilyIndices.Data.ToPointer()
};
//setup buffer handler
VkBuffer buffer;
if (VulkanNative.vkCreateBuffer(
device.Handle,
&bufferCreateInfo,
null,
&buffer
) != VkResult.Success)
{
throw new Exception("failed to create vulkan buffer handle");
}
_handle = buffer;
//memory allocation info
_memoryRequirements = GetMemoryRequirements(device.Handle, buffer);
var memoryAllocateInfo = new VkMemoryAllocateInfo
{
sType = VkStructureType.MemoryAllocateInfo,
allocationSize = _memoryRequirements.size,
memoryTypeIndex = device.FindMemoryType(
_memoryRequirements.memoryTypeBits,
_memoryProperty
)
};
//setup device memory
VkDeviceMemory deviceMemory;
if (VulkanNative.vkAllocateMemory(
device.Handle,
&memoryAllocateInfo,
null,
&deviceMemory
) != VkResult.Success)
{
throw new Exception("failed to allocat device memory");
}
_memoryHandle = deviceMemory;
//bind buffer handle with device memory
if (VulkanNative.vkBindBufferMemory(
device.Handle,
buffer,
deviceMemory,
0
) != VkResult.Success)
{
throw new Exception("failed to bind buffer handler to device memory");
}
}
public static Buffer Create <T>(VkBufferUsageFlags bufferUsages, T[] data, bool dynamic = false) where T : struct
{
return(Create(bufferUsages, dynamic, (ulong)Unsafe.SizeOf <T>(), (ulong)data.Length, Utilities.AsPointer(ref data[0])));
}
/// <summary>
/// Create an empty mappable vulkan buffer for elements of type T whith specified size.
/// </summary>
/// <param name="device">Logical Device.</param>
/// <param name="usage">Buffer Usage.</param>
/// <param name="arrayElementCount">Array element count.</param>
/// <param name="keepMapped">If set to <c>true</c>, buffer will stay mapped after the constructor.</param>
/// <param name="coherentMem">If set to <c>true</c> vulkan memory with have the coherent flag.</param>
public HostBuffer(Device device, VkBufferUsageFlags usage, uint arrayElementCount, bool keepMapped = false, bool coherentMem = true)
: base(device, usage, (ulong)(Marshal.SizeOf <T> () * arrayElementCount), keepMapped, coherentMem)
{
TSize = Marshal.SizeOf <T> ();
}
public static Buffer Create <T>(VkBufferUsageFlags bufferUsages, bool dynamic, ulong count = 1, IntPtr data = default) where T : unmanaged
{
return(Create(bufferUsages, dynamic, (ulong)Unsafe.SizeOf <T>(), count, data));
}
public VkResult createBuffer(VkBufferUsageFlags usageFlags, VkMemoryPropertyFlags memoryPropertyFlags, vksBuffer buffer, ulong size, IntPtr data) => createBuffer(usageFlags, memoryPropertyFlags, buffer, size, data.ToPointer());
