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Added GpuTexture tied to arena like buffer

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This commit is contained in:
adrien 2026-05-20 09:14:54 +02:00
parent ad3fcf2592
commit 32f5d2b828
7 changed files with 390 additions and 43 deletions
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22
src/GpuAllocator.zig
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@ -2,18 +2,28 @@ const GpuDevice = @import("GpuDevice.zig");
const c = @import("utils.zig").c; const c = @import("utils.zig").c;
pub const VTable = struct { pub const VTable = struct {
alloc: *const fn (ctx: *anyopaque, bytes: u64, usage: c.WGPUBufferUsage) anyerror!c.WGPUBuffer, allocBuffer: *const fn (ctx: *anyopaque, desc: c.WGPUBufferDescriptor) anyerror!c.WGPUBuffer,
free: *const fn (ctx: *anyopaque, buf_raw: c.WGPUBuffer, size: u64) void, freeBuffer: *const fn (ctx: *anyopaque, buf_raw: c.WGPUBuffer) void,
allocTexture: *const fn (ctx: *anyopaque, desc: c.WGPUTextureDescriptor) anyerror!c.WGPUTexture,
freeTexture: *const fn (ctx: *anyopaque, buf_raw: c.WGPUTexture) void,
}; };
device: GpuDevice, device: GpuDevice,
ptr: *anyopaque, ptr: *anyopaque,
vtable: *const VTable, vtable: *const VTable,
pub fn allocBuffer(self: @This(), bytes: u64, usage: c.WGPUBufferUsage) !c.WGPUBuffer { pub fn allocBuffer(self: @This(), desc: c.WGPUBufferDescriptor) !c.WGPUBuffer {
return self.vtable.alloc(self.ptr, bytes, usage); return self.vtable.allocBuffer(self.ptr, desc);
} }
pub fn freeBuffer(self: @This(), buf_raw: c.WGPUBuffer, size: u64) void { pub fn freeBuffer(self: @This(), buf_raw: c.WGPUBuffer) void {
self.vtable.free(self.ptr, buf_raw, size); self.vtable.freeBuffer(self.ptr, buf_raw);
}
pub fn allocTexture(self: @This(), desc: c.WGPUTextureDescriptor) !c.WGPUTexture {
return self.vtable.allocTexture(self.ptr, desc);
}
pub fn freeTexture(self: @This(), buf_raw: c.WGPUTexture) void {
self.vtable.freeTexture(self.ptr, buf_raw);
} }

72
src/GpuArena.zig
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@ -1,26 +1,34 @@
const std = @import("std"); const std = @import("std");
const GpuDevice = @import("GpuDevice.zig"); const GpuDevice = @import("GpuDevice.zig");
const GpuAllocator = @import("GpuAllocator.zig"); const GpuAllocator = @import("GpuAllocator.zig");
const GpuTextureFormat = @import("lib.zig").GpuTextureFormat;
const c = @import("utils.zig").c; const c = @import("utils.zig").c;
device: GpuDevice, device: GpuDevice,
tracked_buffers: std.AutoHashMap(c.WGPUBuffer, void), tracked_buffers: std.AutoHashMap(c.WGPUBuffer, c.WGPUBufferDescriptor),
tracked_textures: std.AutoHashMap(c.WGPUTexture, c.WGPUTextureDescriptor),
allocated_vram_bytes: u64 = 0, allocated_vram_bytes: u64 = 0,
pub fn init(cpu_allocator: std.mem.Allocator, device: GpuDevice) @This() { pub fn init(cpu_allocator: std.mem.Allocator, device: GpuDevice) @This() {
return .{ return .{
.device = device, .device = device,
.tracked_buffers = .init(cpu_allocator), .tracked_buffers = .init(cpu_allocator),
.tracked_textures = .init(cpu_allocator),
}; };
} }
pub fn deinit(self: *@This()) void { pub fn deinit(self: *@This()) void {
var it = self.tracked_buffers.keyIterator(); var it_buffer = self.tracked_buffers.keyIterator();
while (it.next()) |buf_ptr| { while (it_buffer.next()) |buf_ptr| {
c.wgpuBufferDestroy(buf_ptr.*); c.wgpuBufferDestroy(buf_ptr.*);
c.wgpuBufferRelease(buf_ptr.*); c.wgpuBufferRelease(buf_ptr.*);
} }
self.tracked_buffers.deinit(); self.tracked_buffers.deinit();
var it_texture = self.tracked_textures.keyIterator();
while (it_texture.next()) |tex_ptr|
c.wgpuTextureRelease(tex_ptr.*);
self.tracked_textures.deinit();
} }
/// Returns the type-erased immutable interface wrapper /// Returns the type-erased immutable interface wrapper
@ -29,41 +37,71 @@ pub fn gpuAllocator(self: *@This()) GpuAllocator {
.device = self.device, .device = self.device,
.ptr = self, .ptr = self,
.vtable = &.{ .vtable = &.{
.alloc = alloc, .allocBuffer = allocBuffer,
.free = free, .freeBuffer = freeBuffer,
.allocTexture = allocTexture,
.freeTexture = freeTexture,
}, },
}; };
} }
fn alloc(ctx: *anyopaque, bytes: u64, usage: c.WGPUBufferUsage) anyerror!c.WGPUBuffer { fn allocBuffer(ctx: *anyopaque, desc: c.WGPUBufferDescriptor) anyerror!c.WGPUBuffer {
const self: *@This() = @ptrCast(@alignCast(ctx)); const self: *@This() = @ptrCast(@alignCast(ctx));
if (bytes > self.device.limits.maxBufferSize) if (desc.size > self.device.limits.maxBufferSize)
return error.SingleBufferExceedsLimit; return error.SingleBufferExceedsLimit;
if (bytes + self.allocated_vram_bytes > self.device.config.vram_bytes_limit) if (desc.size + self.allocated_vram_bytes > self.device.config.vram_bytes_limit)
return error.ExceedsVramBudget; return error.ExceedsVramBudget;
const buf = c.wgpuDeviceCreateBuffer(self.device.device, &.{ const buf = c.wgpuDeviceCreateBuffer(self.device.device, &desc) orelse return error.BufferAlloc;
.usage = usage,
.size = bytes,
}) orelse return error.BufferAlloc;
errdefer { errdefer {
c.wgpuBufferDestroy(buf); c.wgpuBufferDestroy(buf);
c.wgpuBufferRelease(buf); c.wgpuBufferRelease(buf);
} }
try self.tracked_buffers.put(buf, {}); try self.tracked_buffers.put(buf, desc);
self.allocated_vram_bytes += bytes; self.allocated_vram_bytes += desc.size;
return buf; return buf;
} }
fn free(ctx: *anyopaque, buf_raw: c.WGPUBuffer, size: u64) void { fn freeBuffer(ctx: *anyopaque, buf_raw: c.WGPUBuffer) void {
const self: *@This() = @ptrCast(@alignCast(ctx)); const self: *@This() = @ptrCast(@alignCast(ctx));
if (self.tracked_buffers.remove(buf_raw)) { if (self.tracked_buffers.fetchRemove(buf_raw)) |kv| {
c.wgpuBufferDestroy(buf_raw); c.wgpuBufferDestroy(buf_raw);
c.wgpuBufferRelease(buf_raw); c.wgpuBufferRelease(buf_raw);
self.allocated_vram_bytes -= size; self.allocated_vram_bytes -= kv.value.size;
}
}
fn allocTexture(ctx: *anyopaque, desc: c.WGPUTextureDescriptor) anyerror!c.WGPUTexture {
const self: *@This() = @ptrCast(@alignCast(ctx));
const format: GpuTextureFormat = @enumFromInt(desc.format);
const bytes_size = desc.size.width * desc.size.height * format.bytesPerPixel();
if (bytes_size > self.device.limits.maxBufferSize)
return error.SingleBufferExceedsLimit;
if (bytes_size + self.allocated_vram_bytes > self.device.config.vram_bytes_limit)
return error.ExceedsVramBudget;
const texture = c.wgpuDeviceCreateTexture(self.device.device, &desc) orelse return error.Texture;
try self.tracked_textures.put(texture, desc);
self.allocated_vram_bytes += bytes_size;
return texture;
}
fn freeTexture(ctx: *anyopaque, texture_raw: c.WGPUTexture) void {
const self: *@This() = @ptrCast(@alignCast(ctx));
if (self.tracked_textures.fetchRemove(texture_raw)) |kv| {
c.wgpuTextureRelease(texture_raw);
const desc = kv.value;
const format: GpuTextureFormat = @enumFromInt(desc.format);
const bytes_size = desc.size.width * desc.size.height * format.bytesPerPixel();
self.allocated_vram_bytes -= bytes_size;
} }
} }

4
src/GpuBuffer.zig
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@ -30,7 +30,7 @@ pub fn init(gloc: GpuAllocator, size: u64, usage: std.EnumSet(BufferUsage)) !@Th
// Automatically align the buffer size forward to a multiple of 4 bytes under the hood // Automatically align the buffer size forward to a multiple of 4 bytes under the hood
const aligned_size = std.mem.alignForward(u64, size, 4); const aligned_size = std.mem.alignForward(u64, size, 4);
const raw_handle = try gloc.allocBuffer(aligned_size, use); const raw_handle = try gloc.allocBuffer(.{ .size = aligned_size, .usage = use });
return .{ return .{
.raw = raw_handle, .raw = raw_handle,
.size = aligned_size, .size = aligned_size,
@ -41,7 +41,7 @@ pub fn init(gloc: GpuAllocator, size: u64, usage: std.EnumSet(BufferUsage)) !@Th
/// Unregisters from the parent GpuAllocator and cleanly destroys GPU resources /// Unregisters from the parent GpuAllocator and cleanly destroys GPU resources
pub fn deinit(self: @This()) void { pub fn deinit(self: @This()) void {
self.gloc.freeBuffer(self.raw, self.size); self.gloc.freeBuffer(self.raw);
} }
/// Native getConstMappedRange wrapper /// Native getConstMappedRange wrapper

1
src/GpuRender.zig
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@ -58,7 +58,6 @@ pub fn init(device: GpuDevice, wgsl: []const u8, def: RenderDef) !@This() {
.vertex = .{ .vertex = .{
.module = shader, .module = shader,
.entryPoint = sv(def.vertex_entry), .entryPoint = sv(def.vertex_entry),
.bufferCount = 0, // Assuming procedural drawing (like our circle!)
}, },
.primitive = .{ .primitive = .{
.topology = def.topology, .topology = def.topology,

137
src/GpuTexture.zig Normal file
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@ -0,0 +1,137 @@
const std = @import("std");
const c = @import("utils.zig").c;
const GpuAllocator = @import("GpuAllocator.zig");
const GpuTextureFormat = @import("lib.zig").GpuTextureFormat;
const TextureUsage = enum(u64) {
None = 0x0000000000000000,
CopySrc = 0x0000000000000001,
CopyDst = 0x0000000000000002,
TextureBinding = 0x0000000000000004,
StorageBinding = 0x0000000000000008,
RenderAttachment = 0x0000000000000010,
TransientAttachment = 0x0000000000000020,
};
raw: c.WGPUTexture,
size: c.WGPUExtent3D,
usage: c.WGPUTextureUsage,
format: GpuTextureFormat,
gloc: GpuAllocator,
/// Allocates the underlying WebGPU handle and registers it to the parent GpuAllocator
pub fn init(gloc: GpuAllocator, format: GpuTextureFormat, size: c.WGPUExtent3D, usage: std.EnumSet(TextureUsage)) !@This() {
var use: u64 = 0;
var iter = usage.iterator();
while (iter.next()) |flag| use |= @intFromEnum(flag);
const desc = c.WGPUTextureDescriptor{
.usage = use,
.dimension = c.WGPUTextureDimension_2D,
.size = size,
.format = @intCast(@intFromEnum(format)),
.mipLevelCount = 1,
.sampleCount = 1,
};
const raw = try gloc.allocTexture(desc);
return .{ .gloc = gloc, .raw = raw, .size = size, .format = format, .usage = use };
}
/// Unregisters from the parent GpuAllocator and cleanly destroys GPU resources
pub fn deinit(self: @This()) void {
self.gloc.freeTexture(self.raw);
}
/// Native getConstMappedRange wrapper
pub fn getConstMappedRange(self: @This(), offset: u64, size: u64) ?*const anyopaque {
return c.wgpuBufferGetConstMappedRange(self.raw, offset, size);
}
/// Native mapAsync wrapper
pub fn mapAsync(
self: @This(),
mode: c.WGPUMapMode,
offset: u64,
size: u64,
callback_info: c.WGPUBufferMapCallbackInfo,
) void {
_ = c.wgpuBufferMapAsync(self.raw, mode, offset, size, callback_info);
}
/// Native unmap wrapper
pub fn unmap(self: @This()) void {
c.wgpuBufferUnmap(self.raw);
}
/// CPU to GPU.
pub fn load(
self: @This(),
T: type,
data: []const T,
) !void {
const bytes = data.len * @sizeOf(T);
if (bytes == self.size) {
// Aligned path: direct download
c.wgpuQueueWriteBuffer(self.gloc.device.queue, self.raw, 0, data.ptr, self.size);
} else {
// Unaligned path: Split the write into an aligned chunk and a padded remainder
// to support arbitrary lengths without any allocations or large stack arrays.
const aligned_part = (bytes / 4) * 4;
if (aligned_part > 0) {
c.wgpuQueueWriteBuffer(self.gloc.device.queue, self.raw, 0, data.ptr, aligned_part);
}
var remainder_buf: [4]u8 = .{ 0, 0, 0, 0 };
const data_bytes = std.mem.sliceAsBytes(data);
@memcpy(remainder_buf[0 .. bytes - aligned_part], data_bytes[aligned_part..bytes]);
c.wgpuQueueWriteBuffer(self.gloc.device.queue, self.raw, aligned_part, &remainder_buf, 4);
}
}
pub fn read(self: @This(), alloc: std.mem.Allocator, T: type) ![]T {
const out = try alloc.alloc(T, @divExact(self.size, @sizeOf(T)));
const staging = try init(
self.gloc,
self.size,
.initMany(&.{ .MapRead, .CopyDst }),
);
defer staging.deinit();
const enc = c.wgpuDeviceCreateCommandEncoder(self.gloc.device.device, null) orelse return error.Encoder;
c.wgpuCommandEncoderCopyBufferToBuffer(enc, self.raw, 0, staging.raw, 0, self.size);
const cmd = c.wgpuCommandEncoderFinish(enc, null);
defer c.wgpuCommandEncoderRelease(enc);
defer c.wgpuCommandBufferRelease(cmd);
c.wgpuQueueSubmit(self.gloc.device.queue, 1, &cmd);
var mapped = false;
staging.mapAsync(
c.WGPUMapMode_Read,
0,
self.size,
.{ .callback = onMapped, .userdata1 = &mapped },
);
while (!mapped) self.gloc.device.poll();
const ptr: [*]const T = @ptrCast(@alignCast(
staging.getConstMappedRange(0, self.size),
));
@memcpy(out[0..out.len], ptr[0..out.len]);
staging.unmap();
return out;
}
fn onMapped(
status: c.WGPUMapAsyncStatus,
_: c.WGPUStringView,
userdata1: ?*anyopaque,
_: ?*anyopaque,
) callconv(.c) void {
const flag: *bool = @ptrCast(@alignCast(userdata1.?));
flag.* = (status == c.WGPUMapAsyncStatus_Success);
}

27
src/circle.zig
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@ -6,6 +6,7 @@ const GpuDevice = gpu.GpuDevice;
const GpuArena = gpu.GpuArena; const GpuArena = gpu.GpuArena;
const GpuBuffer = gpu.GpuBuffer; const GpuBuffer = gpu.GpuBuffer;
const GpuRender = gpu.GpuRender; const GpuRender = gpu.GpuRender;
const GpuTexture = gpu.GpuTexture;
pub fn main(init: std.process.Init) !void { pub fn main(init: std.process.Init) !void {
const allocator = init.gpa; const allocator = init.gpa;
@ -20,7 +21,6 @@ pub fn main(init: std.process.Init) !void {
const width: u32 = 512; const width: u32 = 512;
const height: u32 = 512; const height: u32 = 512;
// We use standard RGBA8Unorm format for an offscreen image target
const render_format = c.WGPUTextureFormat_RGBA8Unorm; const render_format = c.WGPUTextureFormat_RGBA8Unorm;
// 2. Load our Render Pipeline (Procedural Triangle Strip) // 2. Load our Render Pipeline (Procedural Triangle Strip)
@ -36,22 +36,15 @@ pub fn main(init: std.process.Init) !void {
defer circle_rp.deinit(); defer circle_rp.deinit();
// 3. Create the offscreen VRAM texture to render into // 3. Create the offscreen VRAM texture to render into
const texture_desc = c.WGPUTextureDescriptor{ const texture = try GpuTexture.init(
.nextInChain = null, gloc,
.label = sv("Offscreen Render Target"), .RGBA8Unorm,
.usage = c.WGPUTextureUsage_RenderAttachment | c.WGPUTextureUsage_CopySrc, .{ .width = width, .height = height, .depthOrArrayLayers = 1 },
.dimension = c.WGPUTextureDimension_2D, .initMany(&.{ .RenderAttachment, .CopySrc }),
.size = .{ .width = width, .height = height, .depthOrArrayLayers = 1 }, );
.format = render_format, defer texture.deinit();
.mipLevelCount = 1,
.sampleCount = 1,
.viewFormatCount = 0,
.viewFormats = null,
};
const target_texture = c.wgpuDeviceCreateTexture(device.device, &texture_desc) orelse return error.Texture;
defer c.wgpuTextureRelease(target_texture);
const target_view = c.wgpuTextureCreateView(target_texture, null) orelse return error.View; const target_view = c.wgpuTextureCreateView(texture.raw, null) orelse return error.View;
defer c.wgpuTextureViewRelease(target_view); defer c.wgpuTextureViewRelease(target_view);
// 4. Create a staging buffer to pull pixels from VRAM to CPU // 4. Create a staging buffer to pull pixels from VRAM to CPU
@ -70,7 +63,7 @@ pub fn main(init: std.process.Init) !void {
defer c.wgpuCommandEncoderRelease(enc); defer c.wgpuCommandEncoderRelease(enc);
const src_copy = c.WGPUTexelCopyTextureInfo{ const src_copy = c.WGPUTexelCopyTextureInfo{
.texture = target_texture, .texture = texture.raw,
.mipLevel = 0, .mipLevel = 0,
.origin = .{ .x = 0, .y = 0, .z = 0 }, .origin = .{ .x = 0, .y = 0, .z = 0 },
.aspect = c.WGPUTextureAspect_All, .aspect = c.WGPUTextureAspect_All,

170
src/lib.zig
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@ -4,3 +4,173 @@ pub const GpuBuffer = @import("GpuBuffer.zig");
pub const GpuDevice = @import("GpuDevice.zig"); pub const GpuDevice = @import("GpuDevice.zig");
pub const GpuCompute = @import("GpuCompute.zig"); pub const GpuCompute = @import("GpuCompute.zig");
pub const GpuRender = @import("GpuRender.zig"); pub const GpuRender = @import("GpuRender.zig");
pub const GpuTexture = @import("GpuTexture.zig");
pub const GpuTextureFormat = enum(c_int) {
Undefined = 0,
R8Unorm = 1,
R8Snorm = 2,
R8Uint = 3,
R8Sint = 4,
R16Unorm = 5,
R16Snorm = 6,
R16Uint = 7,
R16Sint = 8,
R16Float = 9,
RG8Unorm = 10,
RG8Snorm = 11,
RG8Uint = 12,
RG8Sint = 13,
R32Float = 14,
R32Uint = 15,
R32Sint = 16,
RG16Unorm = 17,
RG16Snorm = 18,
RG16Uint = 19,
RG16Sint = 20,
RG16Float = 21,
RGBA8Unorm = 22,
RGBA8UnormSrgb = 23,
RGBA8Snorm = 24,
RGBA8Uint = 25,
RGBA8Sint = 26,
BGRA8Unorm = 27,
BGRA8UnormSrgb = 28,
RGB10A2Uint = 29,
RGB10A2Unorm = 30,
RG11B10Ufloat = 31,
RGB9E5Ufloat = 32,
RG32Float = 33,
RG32Uint = 34,
RG32Sint = 35,
RGBA16Unorm = 36,
RGBA16Snorm = 37,
RGBA16Uint = 38,
RGBA16Sint = 39,
RGBA16Float = 40,
RGBA32Float = 41,
RGBA32Uint = 42,
RGBA32Sint = 43,
Stencil8 = 44,
Depth16Unorm = 45,
Depth24Plus = 46,
Depth24PlusStencil8 = 47,
Depth32Float = 48,
Depth32FloatStencil8 = 49,
BC1RGBAUnorm = 50,
BC1RGBAUnormSrgb = 51,
BC2RGBAUnorm = 52,
BC2RGBAUnormSrgb = 53,
BC3RGBAUnorm = 54,
BC3RGBAUnormSrgb = 55,
BC4RUnorm = 56,
BC4RSnorm = 57,
BC5RGUnorm = 58,
BC5RGSnorm = 59,
BC6HRGBUfloat = 60,
BC6HRGBFloat = 61,
BC7RGBAUnorm = 62,
BC7RGBAUnormSrgb = 63,
ETC2RGB8Unorm = 64,
ETC2RGB8UnormSrgb = 65,
ETC2RGB8A1Unorm = 66,
ETC2RGB8A1UnormSrgb = 67,
ETC2RGBA8Unorm = 68,
ETC2RGBA8UnormSrgb = 69,
EACR11Unorm = 70,
EACR11Snorm = 71,
EACRG11Unorm = 72,
EACRG11Snorm = 73,
ASTC4x4Unorm = 74,
ASTC4x4UnormSrgb = 75,
ASTC5x4Unorm = 76,
ASTC5x4UnormSrgb = 77,
ASTC5x5Unorm = 78,
ASTC5x5UnormSrgb = 79,
ASTC6x5Unorm = 80,
ASTC6x5UnormSrgb = 81,
ASTC6x6Unorm = 82,
ASTC6x6UnormSrgb = 83,
ASTC8x5Unorm = 84,
ASTC8x5UnormSrgb = 85,
ASTC8x6Unorm = 86,
ASTC8x6UnormSrgb = 87,
ASTC8x8Unorm = 88,
ASTC8x8UnormSrgb = 89,
ASTC10x5Unorm = 90,
ASTC10x5UnormSrgb = 91,
ASTC10x6Unorm = 92,
ASTC10x6UnormSrgb = 93,
ASTC10x8Unorm = 94,
ASTC10x8UnormSrgb = 95,
ASTC10x10Unorm = 96,
ASTC10x10UnormSrgb = 97,
ASTC12x10Unorm = 98,
ASTC12x10UnormSrgb = 99,
ASTC12x12Unorm = 100,
ASTC12x12UnormSrgb = 101,
Force32 = 2147483647,
pub fn bytesPerPixel(format: GpuTextureFormat) u32 {
return switch (format) {
// 8-bit formats (1 byte)
.R8Unorm, .R8Snorm, .R8Uint, .R8Sint, .Stencil8 => 1,
// 16-bit formats (2 bytes)
.R16Unorm,
.R16Snorm,
.R16Uint,
.R16Sint,
.R16Float,
.RG8Unorm,
.RG8Snorm,
.RG8Uint,
.RG8Sint,
.Depth16Unorm,
=> 2,
// 32-bit formats (4 bytes)
.R32Float,
.R32Uint,
.R32Sint,
.RG16Unorm,
.RG16Snorm,
.RG16Uint,
.RG16Sint,
.RG16Float,
.RGBA8Unorm,
.RGBA8UnormSrgb,
.RGBA8Snorm,
.RGBA8Uint,
.RGBA8Sint,
.BGRA8Unorm,
.BGRA8UnormSrgb,
.RGB10A2Uint,
.RGB10A2Unorm,
.RG11B10Ufloat,
.RGB9E5Ufloat,
.Depth24Plus,
.Depth32Float,
=> 4,
// 64-bit formats (8 bytes)
.RG32Float,
.RG32Uint,
.RG32Sint,
.RGBA16Unorm,
.RGBA16Snorm,
.RGBA16Uint,
.RGBA16Sint,
.RGBA16Float,
.Depth24PlusStencil8, // 24-bit depth + 8-bit stencil layout padded to 4+4 or 1+3
.Depth32FloatStencil8, // 32-bit float depth + 8-bit stencil (padded to 8 bytes)
=> 8,
// 128-bit formats (16 bytes)
.RGBA32Float, .RGBA32Uint, .RGBA32Sint => 16,
// Block Compressed Formats (Handled separately)
else => 0,
};
}
};