Continue refactor

2024-10-26 00:03:04 +02:00 · 2024-10-26 00:03:04 +02:00 · aff66bb482
commit aff66bb482
parent bd725421b6
7 changed files with 803 additions and 45 deletions
--- a/src/Context.zig
+++ b/src/Context.zig
@ -0,0 +1,340 @@
 const std = @import("std");
 const builtin = @import("builtin");
 const vk = @import("vulkan");
 const sdl = @import("sdl");
 const img = @import("zstbi");
 const validation = @import("validation_layers.zig");
 const Swapchain = @import("Swapchain.zig");
 const QueueUtils = @import("queue_utils.zig");
 const device_extensions = [_][*:0]const u8{vk.extensions.khr_swapchain.name};
 pub const apis: []const vk.ApiInfo = &.{
    vk.features.version_1_0,
    vk.features.version_1_1,
    vk.features.version_1_2,
    vk.features.version_1_3,
    vk.extensions.khr_surface,
    vk.extensions.khr_swapchain,
    vk.extensions.ext_debug_utils,
 };
 const enable_validation_layers = builtin.mode == .Debug;
 const validation_layers = [_][*:0]const u8{"VK_LAYER_KHRONOS_validation"};
 const BaseDispatch = vk.BaseWrapper(apis);
 const InstanceDispatch = vk.InstanceWrapper(apis);
 const DeviceDispatch = vk.DeviceWrapper(apis);
 pub const Instance = vk.InstanceProxy(apis);
 pub const Device = vk.DeviceProxy(apis);
 pub const Queue = vk.QueueProxy(apis);
 // ---
 const Self = @This();
 allocator: std.mem.Allocator,
 vkb: BaseDispatch,
 window: sdl.Window,
 instance: Instance,
 physical_device: vk.PhysicalDevice,
 device: Device,
 command_pool: vk.CommandPool,
 graphics_queue: Queue,
 presentation_queue: Queue,
 surface: vk.SurfaceKHR,
 swapchain: Swapchain,
 debug_utils: ?vk.DebugUtilsMessengerEXT,
 pub fn init(allocator: std.mem.Allocator, window: sdl.Window) !Self {
    var self: Self = undefined;
    self.window = window;
    self.allocator = allocator;
    self.vkb = try BaseDispatch.load(try sdl.vulkan.getVkGetInstanceProcAddr());
    img.init(allocator);
    try self.createInstance();
    if (enable_validation_layers) {
        self.debug_utils = try validation.createDebugMessenger(self.instance);
    }
    try self.createSurface();
    try self.getPhysicalDevice();
    try self.createLogicalDevice();
    self.swapchain = try Swapchain.create(allocator, self);
    return self;
 }
 pub fn deinit(self: *Self) void {
    if (enable_validation_layers) {
        self.instance.destroyDebugUtilsMessengerEXT(self.debug_utils.?, null);
    }
    self.device.destroyDevice(null);
    self.instance.destroySurfaceKHR(self.surface, null);
    self.instance.destroyInstance(null);
    self.allocator.destroy(self.device.wrapper);
    self.allocator.destroy(self.instance.wrapper);
    img.deinit();
 }
 fn createInstance(self: *Self) !void {
    if (enable_validation_layers and !self.checkValidationLayersSupport()) {
        // TODO Better error
        return error.LayerNotPresent;
    }
    const extensions = try self.getRequiredExtensions();
    defer self.allocator.free(extensions);
    std.debug.print("[Required instance extensions]\n", .{});
    for (extensions) |ext| {
        std.debug.print("\t- {s}\n", .{ext});
    }
    if (!try self.checkInstanceExtensions(&extensions)) {
        return error.ExtensionNotPresent;
    }
    const app_info = vk.ApplicationInfo{
        .p_application_name = "Vulkan SDL Test",
        .application_version = vk.makeApiVersion(0, 0, 1, 0),
        .p_engine_name = "Vulkan SDL Test",
        .engine_version = vk.makeApiVersion(0, 0, 1, 0),
        .api_version = vk.API_VERSION_1_3,
    };
    var instance_create_info: vk.InstanceCreateInfo = .{
        .p_application_info = &app_info,
        .enabled_extension_count = @intCast(extensions.len),
        .pp_enabled_extension_names = @ptrCast(extensions),
    };
    if (enable_validation_layers) {
        const debug_create_info = validation.getDebugUtilsCreateInfo();
        instance_create_info.enabled_layer_count = @intCast(validation_layers.len);
        instance_create_info.pp_enabled_layer_names = &validation_layers;
        instance_create_info.p_next = &debug_create_info;
    }
    const instance_handle = try self.vkb.createInstance(&instance_create_info, null);
    const vki = try self.allocator.create(InstanceDispatch);
    errdefer self.allocator.destroy(vki);
    vki.* = try InstanceDispatch.load(instance_handle, self.vkb.dispatch.vkGetInstanceProcAddr);
    self.instance = Instance.init(instance_handle, vki);
 }
 fn createSurface(self: *Self) !void {
    self.surface = try sdl.vulkan.createSurface(self.window, self.instance.handle);
 }
 fn getPhysicalDevice(self: *Self) !void {
    var pdev_count: u32 = 0;
    _ = try self.instance.enumeratePhysicalDevices(&pdev_count, null);
    const pdevs = try self.allocator.alloc(vk.PhysicalDevice, pdev_count);
    defer self.allocator.free(pdevs);
    _ = try self.instance.enumeratePhysicalDevices(&pdev_count, pdevs.ptr);
    for (pdevs) |pdev| {
        if (self.checkDeviceSuitable(pdev)) {
            self.physical_device = pdev;
            break;
        }
    } else {
        // TODO Obviously needs to be something else
        unreachable;
    }
 }
 fn createLogicalDevice(self: *Self) !void {
    const indices = try QueueUtils.getQueueFamilies(self.*, self.physical_device);
    // 1 is the highest priority
    const priority = [_]f32{1};
    const qci = [_]vk.DeviceQueueCreateInfo{
        .{
            .queue_family_index = indices.graphics_family.?,
            .queue_count = 1,
            .p_queue_priorities = &priority,
        },
        .{
            .queue_family_index = indices.presentation_family.?,
            .queue_count = 1,
            .p_queue_priorities = &priority,
        },
    };
    const queue_count: u32 = if (indices.graphics_family.? == indices.presentation_family.?)
        1
    else
        2;
    // Device features
    const device_features: vk.PhysicalDeviceFeatures = .{
        .sampler_anisotropy = vk.TRUE, // Enable anisotropy
    };
    const device_create_info: vk.DeviceCreateInfo = .{
        .queue_create_info_count = queue_count,
        .p_queue_create_infos = &qci,
        .pp_enabled_extension_names = &device_extensions,
        .enabled_extension_count = @intCast(device_extensions.len),
        .p_enabled_features = &device_features,
    };
    const device_handle = try self.instance.createDevice(self.physical_device, &device_create_info, null);
    const vkd = try self.allocator.create(DeviceDispatch);
    errdefer self.allocator.destroy(vkd);
    vkd.* = try DeviceDispatch.load(device_handle, self.instance.wrapper.dispatch.vkGetDeviceProcAddr);
    self.device = Device.init(device_handle, vkd);
    const queues = try QueueUtils.getDeviceQueues(self.*);
    self.graphics_queue = Queue.init(queues[0], self.device.wrapper);
    self.presentation_queue = Queue.init(queues[1], self.device.wrapper);
 }
 fn createCommandPool(self: *Self) !void {
    // Get indices of queue families from device
    const queue_family_indices = try QueueUtils.getQueueFamilies(self.*, self.physical_device);
    const pool_create_info: vk.CommandPoolCreateInfo = .{
        // Queue family type that buffers from this command pool will use
        .queue_family_index = queue_family_indices.graphics_family.?,
        .flags = .{ .reset_command_buffer_bit = true },
    };
    // Create a graphics queue family command pool
    self.graphics_command_pool = try self.device.createCommandPool(&pool_create_info, null);
 }
 fn getRequiredExtensions(self: Self) ![][*:0]const u8 {
    var ext_count = sdl.vulkan.getInstanceExtensionsCount(self.window);
    if (enable_validation_layers) {
        ext_count += 1;
    }
    var extensions = try self.allocator.alloc([*:0]const u8, ext_count);
    _ = try sdl.vulkan.getInstanceExtensions(self.window, extensions);
    if (enable_validation_layers) {
        extensions[extensions.len - 1] = vk.extensions.ext_debug_utils.name;
    }
    return extensions;
 }
 fn checkInstanceExtensions(self: Self, required_extensions: *const [][*:0]const u8) !bool {
    var prop_count: u32 = 0;
    _ = try self.vkb.enumerateInstanceExtensionProperties(null, &prop_count, null);
    const props = try self.allocator.alloc(vk.ExtensionProperties, prop_count);
    defer self.allocator.free(props);
    _ = try self.vkb.enumerateInstanceExtensionProperties(null, &prop_count, props.ptr);
    for (required_extensions.*) |required_extension| {
        for (props) |prop| {
            if (std.mem.eql(u8, std.mem.sliceTo(&prop.extension_name, 0), std.mem.span(required_extension))) {
                break;
            }
        } else {
            return false;
        }
    }
    return true;
 }
 fn checkDeviceExtensions(self: Self, pdev: vk.PhysicalDevice) !bool {
    var prop_count: u32 = 0;
    _ = try self.instance.enumerateDeviceExtensionProperties(pdev, null, &prop_count, null);
    if (prop_count == 0) {
        return false;
    }
    const props = try self.allocator.alloc(vk.ExtensionProperties, prop_count);
    defer self.allocator.free(props);
    _ = try self.instance.enumerateDeviceExtensionProperties(pdev, null, &prop_count, props.ptr);
    for (device_extensions) |device_extension| {
        for (props) |prop| {
            if (std.mem.eql(u8, std.mem.sliceTo(&prop.extension_name, 0), std.mem.span(device_extension))) {
                break;
            }
        } else {
            return false;
        }
    }
    return true;
 }
 fn checkDeviceSuitable(self: Self, pdev: vk.PhysicalDevice) bool {
    const pdev_properties = self.instance.getPhysicalDeviceProperties(pdev);
    if (pdev_properties.device_type == .cpu) {
        return false;
    }
    const pdev_features = self.instance.getPhysicalDeviceFeatures(pdev);
    const queue_family_indices = QueueUtils.getQueueFamilies(self, pdev) catch return false;
    const extension_support = self.checkDeviceExtensions(pdev) catch return false;
    const swapchain_details = Swapchain.getSwapchainDetails(
        self.allocator,
        self.instance,
        pdev,
        self.surface,
    ) catch return false;
    defer self.allocator.free(swapchain_details.formats);
    defer self.allocator.free(swapchain_details.presentation_modes);
    const swapchain_valid = swapchain_details.formats.len != 0 and swapchain_details.formats.len != 0;
    return queue_family_indices.isValid() and extension_support and swapchain_valid and pdev_features.sampler_anisotropy == vk.TRUE;
 }
 fn checkValidationLayersSupport(self: Self) bool {
    var layer_count: u32 = undefined;
    _ = self.vkb.enumerateInstanceLayerProperties(&layer_count, null) catch return false;
    const available_layers = self.allocator.alloc(vk.LayerProperties, layer_count) catch unreachable;
    defer self.allocator.free(available_layers);
    _ = self.vkb.enumerateInstanceLayerProperties(&layer_count, available_layers.ptr) catch return false;
    for (validation_layers) |validation_layer| {
        for (available_layers) |available_layer| {
            if (std.mem.eql(u8, std.mem.span(validation_layer), std.mem.sliceTo(&available_layer.layer_name, 0))) {
                return true;
            }
        }
    }
    return false;
 }
--- a/src/Mesh.zig
+++ b/src/Mesh.zig
@ -2,6 +2,7 @@ const std = @import("std");
 const vk = @import("vulkan");
 const zm = @import("zmath");
 const Context = @import("Context.zig");
 const Utilities = @import("utilities.zig");
 const Vertex = Utilities.Vertex;
 const Device = @import("vulkan_renderer.zig").Device;
@ -11,7 +12,6 @@ const Model = @import("vulkan_renderer.zig").Model;
 const Self = @This();
 ubo_model: Model,
 tex_id: u32,
 vertex_count: u32,
 vertex_buffer: vk.Buffer,
@ -21,16 +21,20 @@ index_count: u32,
 index_buffer: vk.Buffer,
 index_buffer_memory: vk.DeviceMemory,
-instance: Instance,
+ctx: Context,
 physical_device: vk.PhysicalDevice,
 device: Device,
 allocator: std.mem.Allocator,
 <<<<<<< Updated upstream
 pub fn new(
    instance: Instance,
    pdev: vk.PhysicalDevice,
    device: Device,
 =======
 pub fn create(
    allocator: std.mem.Allocator,
    ctx: Context,
 >>>>>>> Stashed changes
    transfer_queue: vk.Queue,
    transfer_command_pool: vk.CommandPool,
    vertices: []const Vertex,
@ -40,13 +44,12 @@ pub fn new(
 ) !Self {
    var self: Self = undefined;
    self.allocator = allocator;
    self.vertex_count = @intCast(vertices.len);
    self.index_count = @intCast(indices.len);
-    self.instance = instance;
+    self.ctx = ctx;
    self.physical_device = pdev;
    self.device = device;
    self.allocator = allocator;
    try self.createVertexBuffer(transfer_queue, transfer_command_pool, vertices);
    try self.createIndexBuffer(transfer_queue, transfer_command_pool, indices);
@ -57,12 +60,18 @@ pub fn new(
    return self;
 }
 <<<<<<< Updated upstream
 pub fn destroyBuffers(self: Self) void {
    self.device.destroyBuffer(self.vertex_buffer, null);
    self.device.freeMemory(self.vertex_buffer_memory, null);
 =======
 pub fn destroy(self: Self) void {
    self.ctx.device.destroyBuffer(self.vertex_buffer, null);
    self.ctx.device.freeMemory(self.vertex_buffer_memory, null);
 >>>>>>> Stashed changes
-    self.device.destroyBuffer(self.index_buffer, null);
+    self.ctx.device.destroyBuffer(self.index_buffer, null);
-    self.device.freeMemory(self.index_buffer_memory, null);
+    self.ctx.device.freeMemory(self.index_buffer_memory, null);
 }
 fn createVertexBuffer(
@ -77,14 +86,12 @@ fn createVertexBuffer(
    // Temporary buffer to "stage" vertex data before transfering to GPU
    var staging_buffer: vk.Buffer = undefined;
    var staging_buffer_memory: vk.DeviceMemory = undefined;
-    defer self.device.destroyBuffer(staging_buffer, null);
+    defer self.ctx.device.destroyBuffer(staging_buffer, null);
-    defer self.device.freeMemory(staging_buffer_memory, null);
+    defer self.ctx.device.freeMemory(staging_buffer_memory, null);
    // Create buffer and allocate memory to it
    try Utilities.createBuffer(
-        self.physical_device,
+        self.ctx,
        self.instance,
        self.device,
        buffer_size,
        .{ .transfer_src_bit = true },
        .{ .host_visible_bit = true, .host_coherent_bit = true },
@ -95,21 +102,19 @@ fn createVertexBuffer(
    // Map memory to vertex
    // 1. Create pointer to a point in normal memory
    // 2. Map the vertex buffer memory to that point
-    const data = try self.device.mapMemory(staging_buffer_memory, 0, buffer_size, .{});
+    const data = try self.ctx.device.mapMemory(staging_buffer_memory, 0, buffer_size, .{});
    // 3. Copy memory from vertices vector to the point in memory
    const gpu_vertices: [*]Vertex = @ptrCast(@alignCast(data));
    @memcpy(gpu_vertices, vertices[0..]);
    // 4. Unmap the vertex buffer memory
-    self.device.unmapMemory(staging_buffer_memory);
+    self.ctx.device.unmapMemory(staging_buffer_memory);
    // ---
    // Create buffer with TRANSFER_DST_BIT to mark as recipient of transfer data (also VERTEX_BUFFER)
    // Buffer memory is to be DEVICE_LOCAL_BIT meaning memory is on the GPU and only accessible by it and not CPU (host)
    try Utilities.createBuffer(
-        self.physical_device,
+        self.ctx,
        self.instance,
        self.device,
        buffer_size,
        .{ .transfer_dst_bit = true, .vertex_buffer_bit = true },
        .{ .device_local_bit = true },
@ -119,7 +124,7 @@ fn createVertexBuffer(
    // Copy staging buffer to vertex buffer on GPU
    try Utilities.copyBuffer(
-        self.device,
+        self.ctx,
        transfer_queue,
        transfer_command_pool,
        staging_buffer,
@ -140,13 +145,11 @@ fn createIndexBuffer(
    // Temporary buffer to "stage" vertex data before transfering to GPU
    var staging_buffer: vk.Buffer = undefined;
    var staging_buffer_memory: vk.DeviceMemory = undefined;
-    defer self.device.destroyBuffer(staging_buffer, null);
+    defer self.ctx.device.destroyBuffer(staging_buffer, null);
-    defer self.device.freeMemory(staging_buffer_memory, null);
+    defer self.ctx.device.freeMemory(staging_buffer_memory, null);
    try Utilities.createBuffer(
-        self.physical_device,
+        self.ctx,
        self.instance,
        self.device,
        buffer_size,
        .{ .transfer_src_bit = true },
        .{ .host_visible_bit = true, .host_coherent_bit = true },
@ -155,16 +158,14 @@ fn createIndexBuffer(
    );
    // Map memory to index buffer
-    const data = try self.device.mapMemory(staging_buffer_memory, 0, buffer_size, .{});
+    const data = try self.ctx.device.mapMemory(staging_buffer_memory, 0, buffer_size, .{});
    const gpu_vertices: [*]u32 = @ptrCast(@alignCast(data));
    @memcpy(gpu_vertices, indices[0..]);
-    self.device.unmapMemory(staging_buffer_memory);
+    self.ctx.device.unmapMemory(staging_buffer_memory);
    // Create buffer for index data on GPU access only
    try Utilities.createBuffer(
-        self.physical_device,
+        self.ctx,
        self.instance,
        self.device,
        buffer_size,
        .{ .transfer_dst_bit = true, .index_buffer_bit = true },
        .{ .device_local_bit = true },
@ -174,7 +175,7 @@ fn createIndexBuffer(
    // Copy from staging buffer to GPU access buffer
    try Utilities.copyBuffer(
-        self.device,
+        self.ctx,
        transfer_queue,
        transfer_command_pool,
        staging_buffer,
--- a/src/MeshModel.zig
+++ b/src/MeshModel.zig
@ -15,7 +15,20 @@ allocator: std.mem.Allocator,
 mesh_list: std.ArrayList(Mesh),
 model: zm.Mat,
 <<<<<<< Updated upstream
 pub fn new(allocator: std.mem.Allocator, mesh_list: std.ArrayList(Mesh)) Self {
 =======
 sampler_descriptor_sets: std.ArrayList(vk.DescriptorSet),
 pub fn new(
    allocator: std.mem.Allocator,
    ctx: Context,
    graphics_command_pool: vk.CommandPool,
    texture_sampler: vk.Sampler,
    model_file: []const u8,
 ) Self {
    _ = texture_sampler;
 >>>>>>> Stashed changes
    var new_mesh_model: Self = undefined;
    new_mesh_model.allocator = allocator;
--- a/src/ResourceManager.zig
+++ b/src/ResourceManager.zig
@ -0,0 +1,55 @@
 const std = @import("std");
 const vk = @import("vulkan");
 const Context = @import("Context.zig");
 const Mesh = @import("Mesh.zig");
 const Material = @import("Material.zig");
 const Self = @This();
 allocator: std.mem.Allocator,
 ctx: Context,
 sampler_descriptor_pool: vk.DescriptorPool,
 sampler_descriptor_set_layout: vk.DescriptorSetLayout,
 mesh_cache: std.AutoArrayHashMap([]const u8, Mesh),
 material_cache: std.AutoArrayHashMap([]const u8, Material),
 pub fn new(allocator: std.mem.Allocator, ctx: Context) Self {
    var self: Self = undefined;
    self.allocator = allocator;
    self.ctx = ctx;
    self.mesh_cache = std.AutoArrayHashMap([]const u8, Mesh).init(allocator);
    self.material_cache = std.AutoArrayHashMap([]const u8, Material).init(allocator);
    return self;
 }
 pub fn deinit(self: *Self) void {
    // TODO Release resources properly
    self.mesh_cache.deinit();
    self.material_cache.deinit();
 }
 pub fn getMesh(self: *Self, file_name: []const u8) !Mesh {
    if (self.mesh_cache.get(file_name)) |mesh| {
        return mesh;
    }
    // TODO Create mesh
    // load mesh
    return undefined;
 }
 fn allocateDescriptorSet(self: *Self) !void {
    // TODO
 }
 fn createDescriptorSetLayout(self: *Self) !void {
    // TODO
 }
--- a/src/Texture.zig
+++ b/src/Texture.zig
@ -0,0 +1,200 @@
 const std = @import("std");
 const vk = @import("vulkan");
 const img = @import("zstbi");
 const Context = @import("Context.zig");
 const Image = @import("image.zig");
 const Utilities = @import("utilities.zig");
 const Self = @This();
 allocator: std.mem.Allocator,
 ctx: Context,
 idx: u32,
 texture_image: vk.Image,
 texture_image_memory: vk.DeviceMemory,
 texture_image_view: vk.ImageView,
 sampler_descriptor_set: vk.DescriptorSet,
 image_file: img.Image,
 pub fn create(
    file_name: []const u8,
    ctx: Context,
    graphics_command_pool: vk.CommandPool,
    texture_sampler: vk.Sampler,
    sampler_set_layout: vk.DescriptorSetLayout,
    sampler_descriptor_pool: vk.DescriptorPool,
 ) Self {
    var self: Self = undefined;
    self.ctx = ctx;
    // Create texture image and get its location in the array
    const texture_image_loc = try self.createTextureImage(file_name, graphics_command_pool);
    // Create image view
    self.texture_image_view = try Image.createImageView(
        ctx,
        self.texture_images.items[texture_image_loc],
        .r8g8b8a8_srgb,
        .{ .color_bit = true },
    );
    // Create texture descriptor
    try self.createTextureDescriptor(
        texture_sampler,
        sampler_set_layout,
        sampler_descriptor_pool,
    );
    // Return location of set with texture
    return self;
 }
 pub fn destroy(self: *Self) void {
    _ = self;
 }
 fn createTextureImage(
    self: *Self,
    file_name: []const u8,
    graphics_command_pool: vk.CommandPool,
 ) !u32 {
    // Load image file
    var width: u32 = undefined;
    var height: u32 = undefined;
    var image_size: vk.DeviceSize = undefined;
    const image = try self.loadTextureFile(file_name, &width, &height, &image_size);
    // Create staging buffer to hold loaded data, ready to copy to device
    var image_staging_buffer: vk.Buffer = undefined;
    var image_staging_buffer_memory: vk.DeviceMemory = undefined;
    defer self.ctx.device.destroyBuffer(image_staging_buffer, null);
    defer self.ctx.device.freeMemory(image_staging_buffer_memory, null);
    try Utilities.createBuffer(
        self.ctx.physical_device,
        self.ctx.instance,
        self.ctx.device,
        image_size,
        .{ .transfer_src_bit = true },
        .{ .host_visible_bit = true, .host_coherent_bit = true },
        &image_staging_buffer,
        &image_staging_buffer_memory,
    );
    // Copy data to staging buffer
    const data = try self.ctx.device.mapMemory(image_staging_buffer_memory, 0, image_size, .{});
    const image_data: [*]u8 = @ptrCast(@alignCast(data));
    @memcpy(image_data, image[0..]);
    self.ctx.device.unmapMemory(image_staging_buffer_memory);
    // Create image to hold final texture
    var tex_image_memory: vk.DeviceMemory = undefined;
    const tex_image = try Image.createImage(
        self.ctx,
        width,
        height,
        .r8g8b8a8_srgb,
        .optimal,
        .{ .transfer_dst_bit = true, .sampled_bit = true },
        .{ .device_local_bit = true },
        &tex_image_memory,
    );
    // Transition image to be DST for copy operation
    try Utilities.transitionImageLayout(
        self.ctx.device,
        self.ctx.graphics_queue.handle,
        graphics_command_pool,
        tex_image,
        .undefined,
        .transfer_dst_optimal,
    );
    // Copy data to image
    try Utilities.copyImageBuffer(
        self.ctx.device,
        self.ctx.graphics_queue.handle,
        graphics_command_pool,
        image_staging_buffer,
        tex_image,
        width,
        height,
    );
    // Transition image to be shader readable for shader usage
    try Utilities.transitionImageLayout(
        self.ctx.device,
        self.ctx.graphics_queue.handle,
        graphics_command_pool,
        tex_image,
        .transfer_dst_optimal,
        .shader_read_only_optimal,
    );
    self.texture_image = tex_image;
    self.texture_image_memory = tex_image_memory;
    // Return index of new texture image
    return @intCast(self.texture_images.items.len - 1);
 }
 fn createTextureDescriptor(
    self: *Self,
    texture_sampler: vk.Sampler,
    sampler_set_layout: vk.DescriptorSetLayout,
    sampler_descriptor_pool: vk.DescriptorPool,
 ) !u32 {
    // Descriptor set allocation info
    const set_alloc_info: vk.DescriptorSetAllocateInfo = .{
        .descriptor_pool = sampler_descriptor_pool,
        .descriptor_set_count = 1,
        .p_set_layouts = @ptrCast(&sampler_set_layout),
    };
    // Allocate descriptor sets
    try self.ctx.device.allocateDescriptorSets(&set_alloc_info, @ptrCast(&self.sampler_descriptor_set));
    const image_info: vk.DescriptorImageInfo = .{
        .image_layout = .shader_read_only_optimal, // Image layout when in use
        .image_view = self.texture_image_view, // Image to bind to set
        .sampler = texture_sampler, // Sampler to use for set
    };
    // Descriptor write info
    const descriptor_write: vk.WriteDescriptorSet = .{
        .dst_set = self.sampler_descriptor_set,
        .dst_binding = 0,
        .dst_array_element = 0,
        .descriptor_type = .combined_image_sampler,
        .descriptor_count = 1,
        .p_image_info = @ptrCast(&image_info),
        .p_buffer_info = undefined,
        .p_texel_buffer_view = undefined,
    };
    // Update the new descriptor set
    self.ctx.device.updateDescriptorSets(1, @ptrCast(&descriptor_write), 0, null);
 }
 fn loadTextureFile(self: *Self, file_name: []const u8, width: *u32, height: *u32, image_size: *vk.DeviceSize) !void {
    const path_concat = [2][]const u8{ "./assets/textures/", file_name };
    const path = try std.mem.concatWithSentinel(self.allocator, u8, &path_concat, 0);
    defer self.allocator.free(path);
    const image = try img.Image.loadFromFile(path, 0);
    width.* = image.width;
    height.* = image.height;
    // Calculate image size using given and known data
    image_size.* = width.* * height.* * 4;
    self.image_file = image;
 }
--- a/src/utilities.zig
+++ b/src/utilities.zig
@ -1,8 +1,14 @@
 const std = @import("std");
 const vk = @import("vulkan");
 <<<<<<< Updated upstream
 const Instance = @import("vulkan_renderer.zig").Instance;
 const Device = @import("vulkan_renderer.zig").Device;
 =======
 const Context = @import("Context.zig");
 const Instance = @import("Context.zig").Instance;
 const Device = @import("Context.zig").Device;
 >>>>>>> Stashed changes
 const CommandBuffer = @import("vulkan_renderer.zig").CommandBuffer;
 pub const device_extensions = [_][*:0]const u8{vk.extensions.khr_swapchain.name};
@ -17,6 +23,7 @@ pub const Vertex = struct {
    tex: Vector2, // Texture coords (u, v)
 };
 <<<<<<< Updated upstream
 pub const QueueFamilyIndices = struct {
    graphics_family: ?u32 = null,
    presentation_family: ?u32 = null,
@ -38,8 +45,11 @@ pub const SwapchainImage = struct {
 };
 pub fn findMemoryTypeIndex(pdev: vk.PhysicalDevice, instance: Instance, allowed_types: u32, properties: vk.MemoryPropertyFlags) u32 {
 =======
 pub fn findMemoryTypeIndex(ctx: Context, allowed_types: u32, properties: vk.MemoryPropertyFlags) u32 {
 >>>>>>> Stashed changes
    // Get properties of physical device memory
-    const memory_properties = instance.getPhysicalDeviceMemoryProperties(pdev);
+    const memory_properties = ctx.instance.getPhysicalDeviceMemoryProperties(ctx.physical_device);
    const mem_type_count = memory_properties.memory_type_count;
    for (memory_properties.memory_types[0..mem_type_count], 0..mem_type_count) |mem_type, i| {
@ -54,9 +64,7 @@ pub fn findMemoryTypeIndex(pdev: vk.PhysicalDevice, instance: Instance, allowed_
 }
 pub fn createBuffer(
-    pdev: vk.PhysicalDevice,
+    ctx: Context,
    instance: Instance,
    device: Device,
    buffer_size: vk.DeviceSize,
    buffer_usage: vk.BufferUsageFlags,
    buffer_properties: vk.MemoryPropertyFlags,
@ -72,17 +80,16 @@ pub fn createBuffer(
        .sharing_mode = .exclusive, // Similar to swapchain images, can share vertex buffers
    };
-    buffer.* = try device.createBuffer(&buffer_create_info, null);
+    buffer.* = try ctx.device.createBuffer(&buffer_create_info, null);
    // Get buffer memory requirements
-    const mem_requirements = device.getBufferMemoryRequirements(buffer.*);
+    const mem_requirements = ctx.device.getBufferMemoryRequirements(buffer.*);
    // Allocate memory to buffer
    const allocate_info: vk.MemoryAllocateInfo = .{
        .allocation_size = mem_requirements.size,
        .memory_type_index = findMemoryTypeIndex(
-            pdev,
+            ctx,
            instance,
            mem_requirements.memory_type_bits, // Index of memory type of physical device that has required bit flags
            // Host visible: CPU can interact with memory
            // Host coherent: Allows placement of data straight into buffer after mapping (otherwise would have to specify manually)
@ -91,10 +98,10 @@ pub fn createBuffer(
    };
    // Allocate memory to vkDeviceMemory
-    buffer_memory.* = try device.allocateMemory(&allocate_info, null);
+    buffer_memory.* = try ctx.device.allocateMemory(&allocate_info, null);
    // Allocate memory to given vertex buffer
-    try device.bindBufferMemory(buffer.*, buffer_memory.*, 0);
+    try ctx.device.bindBufferMemory(buffer.*, buffer_memory.*, 0);
 }
 fn beginCommandBuffer(device: Device, command_pool: vk.CommandPool) !CommandBuffer {
--- a/src/vulkan_renderer.zig
+++ b/src/vulkan_renderer.zig
@ -59,9 +59,13 @@ pub const VulkanRenderer = struct {
    vkb: BaseDispatch,
 <<<<<<< Updated upstream
    window: sdl.Window,
    current_frame: u32 = 0,
 =======
    ctx: Context,
 >>>>>>> Stashed changes
    // Scene settings
    ubo_view_projection: UboViewProjection,
@ -122,9 +126,6 @@ pub const VulkanRenderer = struct {
    render_pass: vk.RenderPass,
    // Pools
    graphics_command_pool: vk.CommandPool,
    // Utilities
    swapchain_image_format: vk.Format,
    depth_format: vk.Format,
@ -142,8 +143,11 @@ pub const VulkanRenderer = struct {
        self.window = window;
        self.current_frame = 0;
 <<<<<<< Updated upstream
        self.allocator = allocator;
        self.vkb = try BaseDispatch.load(try sdl.vulkan.getVkGetInstanceProcAddr());
 =======
 >>>>>>> Stashed changes
        img.init(allocator);
@ -166,7 +170,11 @@ pub const VulkanRenderer = struct {
        try self.createFramebuffers();
        try self.createCommandPool();
 <<<<<<< Updated upstream
        self.sampler_descriptor_sets = try std.ArrayList(vk.DescriptorSet).initCapacity(self.allocator, self.swapchain_images.len);
 =======
        self.sampler_descriptor_sets = try std.ArrayList(vk.DescriptorSet).initCapacity(self.allocator, self.ctx.swapchain.swapchain_images.len);
 >>>>>>> Stashed changes
        try self.createCommandBuffers();
        try self.createTextureSampler();
@ -182,7 +190,11 @@ pub const VulkanRenderer = struct {
        self.texture_image_views = std.ArrayList(vk.ImageView).init(self.allocator);
        self.model_list = std.ArrayList(MeshModel).init(allocator);
 <<<<<<< Updated upstream
        const aspect: f32 = @as(f32, @floatFromInt(self.extent.width)) / @as(f32, @floatFromInt(self.extent.height));
 =======
        const aspect: f32 = @as(f32, @floatFromInt(self.ctx.swapchain.extent.width)) / @as(f32, @floatFromInt(self.ctx.swapchain.extent.height));
 >>>>>>> Stashed changes
        self.ubo_view_projection.projection = zm.perspectiveFovRh(
            std.math.degreesToRadians(45.0),
            aspect,
@ -226,8 +238,13 @@ pub const VulkanRenderer = struct {
        // -- Get next image
        // Get index of next image to be drawn to, and signal semaphore when ready to be drawn to
 <<<<<<< Updated upstream
        const image_index_result = try self.device.acquireNextImageKHR(
            self.swapchain,
 =======
        const image_index_result = try self.ctx.device.acquireNextImageKHR(
            self.ctx.swapchain.handle,
 >>>>>>> Stashed changes
            std.math.maxInt(u64),
            self.image_available[self.current_frame],
            .null_handle,
@ -258,7 +275,11 @@ pub const VulkanRenderer = struct {
            .wait_semaphore_count = 1, // Number of semaphores to wait on
            .p_wait_semaphores = @ptrCast(&self.render_finished[self.current_frame]), // Semaphores to wait on
            .swapchain_count = 1, // Number of swapchains to present to
 <<<<<<< Updated upstream
            .p_swapchains = @ptrCast(&self.swapchain), // Swapchains to present images to
 =======
            .p_swapchains = @ptrCast(&self.ctx.swapchain.handle), // Swapchains to present images to
 >>>>>>> Stashed changes
            .p_image_indices = @ptrCast(&image_index_result.image_index), // Index of images in swapchains to present
        };
@ -331,9 +352,15 @@ pub const VulkanRenderer = struct {
        self.sampler_descriptor_sets.deinit();
        self.allocator.free(self.input_descriptor_sets);
 <<<<<<< Updated upstream
        for (0..self.swapchain_images.len) |i| {
            self.device.destroyBuffer(self.vp_uniform_buffer[i], null);
            self.device.freeMemory(self.vp_uniform_buffer_memory[i], null);
 =======
        for (0..self.ctx.swapchain.swapchain_images.len) |i| {
            self.ctx.device.destroyBuffer(self.vp_uniform_buffer[i], null);
            self.ctx.device.freeMemory(self.vp_uniform_buffer_memory[i], null);
 >>>>>>> Stashed changes
        }
        self.allocator.free(self.vp_uniform_buffer);
        self.allocator.free(self.vp_uniform_buffer_memory);
@ -352,7 +379,11 @@ pub const VulkanRenderer = struct {
            self.device.destroyFramebuffer(framebuffer, null);
        }
 <<<<<<< Updated upstream
        self.allocator.free(self.swapchain_framebuffers);
 =======
        self.ctx.swapchain.deinit();
 >>>>>>> Stashed changes
        self.device.destroyPipeline(self.second_pipeline, null);
        self.device.destroyPipelineLayout(self.second_pipeline_layout, null);
@ -616,7 +647,11 @@ pub const VulkanRenderer = struct {
        // Colour attachment of the render pass
        const swapchain_colour_attachment: vk.AttachmentDescription = .{
 <<<<<<< Updated upstream
            .format = self.swapchain_image_format, // Format to use for attachment
 =======
            .format = self.ctx.swapchain.swapchain_image_format, // Format to use for attachment
 >>>>>>> Stashed changes
            .samples = .{ .@"1_bit" = true }, // Number of samples to write for multisampling
            .load_op = .clear, // Describes what to do with attachment before rendering
            .store_op = .store, // Describes what to do with attachment after rendering
@ -787,9 +822,15 @@ pub const VulkanRenderer = struct {
    }
    fn createColourBufferImage(self: *Self) !void {
 <<<<<<< Updated upstream
        self.colour_buffer_image = try self.allocator.alloc(vk.Image, self.swapchain_images.len);
        self.colour_buffer_image_memory = try self.allocator.alloc(vk.DeviceMemory, self.swapchain_images.len);
        self.colour_buffer_image_view = try self.allocator.alloc(vk.ImageView, self.swapchain_images.len);
 =======
        self.colour_buffer_image = try self.allocator.alloc(vk.Image, self.ctx.swapchain.swapchain_images.len);
        self.colour_buffer_image_memory = try self.allocator.alloc(vk.DeviceMemory, self.ctx.swapchain.swapchain_images.len);
        self.colour_buffer_image_view = try self.allocator.alloc(vk.ImageView, self.ctx.swapchain.swapchain_images.len);
 >>>>>>> Stashed changes
        // Get supported format for colour attachment
        const colour_format = chooseSupportedFormat(
@ -802,9 +843,16 @@ pub const VulkanRenderer = struct {
        // Create colour buffers
        for (0..self.colour_buffer_image.len) |i| {
 <<<<<<< Updated upstream
            self.colour_buffer_image[i] = try self.createImage(
                self.extent.width,
                self.extent.height,
 =======
            self.colour_buffer_image[i] = try Image.createImage(
                self.ctx,
                self.ctx.swapchain.extent.width,
                self.ctx.swapchain.extent.height,
 >>>>>>> Stashed changes
                colour_format,
                .optimal,
                .{ .color_attachment_bit = true, .input_attachment_bit = true },
@ -821,9 +869,15 @@ pub const VulkanRenderer = struct {
    }
    fn createDepthBufferImage(self: *Self) !void {
 <<<<<<< Updated upstream
        self.depth_buffer_image = try self.allocator.alloc(vk.Image, self.swapchain_images.len);
        self.depth_buffer_image_memory = try self.allocator.alloc(vk.DeviceMemory, self.swapchain_images.len);
        self.depth_buffer_image_view = try self.allocator.alloc(vk.ImageView, self.swapchain_images.len);
 =======
        self.depth_buffer_image = try self.allocator.alloc(vk.Image, self.ctx.swapchain.swapchain_images.len);
        self.depth_buffer_image_memory = try self.allocator.alloc(vk.DeviceMemory, self.ctx.swapchain.swapchain_images.len);
        self.depth_buffer_image_view = try self.allocator.alloc(vk.ImageView, self.ctx.swapchain.swapchain_images.len);
 >>>>>>> Stashed changes
        // Get supported depth buffer format
        const formats = [_]vk.Format{ .d32_sfloat_s8_uint, .d32_sfloat, .d24_unorm_s8_uint };
@ -837,9 +891,16 @@ pub const VulkanRenderer = struct {
        for (0..self.depth_buffer_image.len) |i| {
            // Create depth buffer image
 <<<<<<< Updated upstream
            self.depth_buffer_image[i] = try self.createImage(
                self.extent.width,
                self.extent.height,
 =======
            self.depth_buffer_image[i] = try Image.createImage(
                self.ctx,
                self.ctx.swapchain.extent.width,
                self.ctx.swapchain.extent.height,
 >>>>>>> Stashed changes
                self.depth_format,
                .optimal,
                .{ .depth_stencil_attachment_bit = true, .input_attachment_bit = true },
@ -939,15 +1000,24 @@ pub const VulkanRenderer = struct {
        self.viewport = .{
            .x = 0.0,
            .y = 0.0,
 <<<<<<< Updated upstream
            .width = @floatFromInt(self.extent.width),
            .height = @floatFromInt(self.extent.height),
 =======
            .width = @floatFromInt(self.ctx.swapchain.extent.width),
            .height = @floatFromInt(self.ctx.swapchain.extent.height),
 >>>>>>> Stashed changes
            .min_depth = 0.0,
            .max_depth = 1.0,
        };
        self.scissor = .{
            .offset = .{ .x = 0, .y = 0 },
 <<<<<<< Updated upstream
            .extent = self.extent,
 =======
            .extent = self.ctx.swapchain.extent,
 >>>>>>> Stashed changes
        };
        const viewport_state_create_info: vk.PipelineViewportStateCreateInfo = .{
@ -1121,10 +1191,17 @@ pub const VulkanRenderer = struct {
    }
    fn createFramebuffers(self: *Self) !void {
 <<<<<<< Updated upstream
        self.swapchain_framebuffers = try self.allocator.alloc(vk.Framebuffer, self.swapchain_images.len);
        // Create a frammebuffer for each swapchain image
        for (self.swapchain_images, 0..) |swapchain_image, i| {
 =======
        self.ctx.swapchain.swapchain_framebuffers = try self.allocator.alloc(vk.Framebuffer, self.ctx.swapchain.swapchain_images.len);
        // Create a frammebuffer for each swapchain image
        for (self.ctx.swapchain.swapchain_images, 0..) |swapchain_image, i| {
 >>>>>>> Stashed changes
            // Order matters
            const attachments = [_]vk.ImageView{
                swapchain_image.image_view,
@ -1136,6 +1213,7 @@ pub const VulkanRenderer = struct {
                .render_pass = self.render_pass, // Render pass layout the frambuffer will be used with
                .attachment_count = @intCast(attachments.len),
                .p_attachments = &attachments, // List of attachments (1:1 with render pass)
 <<<<<<< Updated upstream
                .width = self.extent.width, // Framebuffer width
                .height = self.extent.height, // Framebuffer height
                .layers = 1, // Framebuffer layers
@ -1162,6 +1240,20 @@ pub const VulkanRenderer = struct {
    fn createCommandBuffers(self: *Self) !void {
        // Allocate one command buffer for each framebuffer
        const command_buffer_handles = try self.allocator.alloc(vk.CommandBuffer, self.swapchain_framebuffers.len);
 =======
                .width = self.ctx.swapchain.extent.width, // Framebuffer width
                .height = self.ctx.swapchain.extent.height, // Framebuffer height
                .layers = 1, // Framebuffer layers
            };
            self.ctx.swapchain.swapchain_framebuffers[i] = try self.ctx.device.createFramebuffer(&framebuffer_create_info, null);
        }
    }
    fn createCommandBuffers(self: *Self) !void {
        // Allocate one command buffer for each framebuffer
        const command_buffer_handles = try self.allocator.alloc(vk.CommandBuffer, self.ctx.swapchain.swapchain_framebuffers.len);
 >>>>>>> Stashed changes
        defer self.allocator.free(command_buffer_handles);
        self.command_buffers = try self.allocator.alloc(CommandBuffer, command_buffer_handles.len);
@ -1218,8 +1310,13 @@ pub const VulkanRenderer = struct {
        const vp_buffer_size: vk.DeviceSize = @sizeOf(UboViewProjection);
        // One uniform buffer for each image (and by extension, command buffer)
 <<<<<<< Updated upstream
        self.vp_uniform_buffer = try self.allocator.alloc(vk.Buffer, self.swapchain_images.len);
        self.vp_uniform_buffer_memory = try self.allocator.alloc(vk.DeviceMemory, self.swapchain_images.len);
 =======
        self.vp_uniform_buffer = try self.allocator.alloc(vk.Buffer, self.ctx.swapchain.swapchain_images.len);
        self.vp_uniform_buffer_memory = try self.allocator.alloc(vk.DeviceMemory, self.ctx.swapchain.swapchain_images.len);
 >>>>>>> Stashed changes
        // Create the uniform buffers
        for (0..self.vp_uniform_buffer.len) |i| {
@ -1251,7 +1348,11 @@ pub const VulkanRenderer = struct {
        // Data to create descriptor pool
        const pool_create_info: vk.DescriptorPoolCreateInfo = .{
 <<<<<<< Updated upstream
            .max_sets = @intCast(self.swapchain_images.len), // Maximum number of descriptor sets that can be created from pool
 =======
            .max_sets = @intCast(self.ctx.swapchain.swapchain_images.len), // Maximum number of descriptor sets that can be created from pool
 >>>>>>> Stashed changes
            .pool_size_count = @intCast(descriptor_pool_sizes.len), // Amount of pool sizes being passed
            .p_pool_sizes = &descriptor_pool_sizes, // Pool sizes to create pool with
        };
@ -1293,7 +1394,11 @@ pub const VulkanRenderer = struct {
        // Create input attachment pool
        const input_pool_create_info: vk.DescriptorPoolCreateInfo = .{
 <<<<<<< Updated upstream
            .max_sets = @intCast(self.swapchain_images.len),
 =======
            .max_sets = @intCast(self.ctx.swapchain.swapchain_images.len),
 >>>>>>> Stashed changes
            .pool_size_count = @intCast(input_pool_sizes.len),
            .p_pool_sizes = &input_pool_sizes,
        };
@ -1303,9 +1408,15 @@ pub const VulkanRenderer = struct {
    fn createDescriptorSets(self: *Self) !void {
        // One descriptor set for every buffer
 <<<<<<< Updated upstream
        self.descriptor_sets = try self.allocator.alloc(vk.DescriptorSet, self.swapchain_images.len);
        var set_layouts = try self.allocator.alloc(vk.DescriptorSetLayout, self.swapchain_images.len);
 =======
        self.descriptor_sets = try self.allocator.alloc(vk.DescriptorSet, self.ctx.swapchain.swapchain_images.len);
        var set_layouts = try self.allocator.alloc(vk.DescriptorSetLayout, self.ctx.swapchain.swapchain_images.len);
 >>>>>>> Stashed changes
        defer self.allocator.free(set_layouts);
        for (0..set_layouts.len) |i| {
            set_layouts[i] = self.descriptor_set_layout;
@ -1314,7 +1425,11 @@ pub const VulkanRenderer = struct {
        // Descriptor set allocation info
        const set_alloc_info: vk.DescriptorSetAllocateInfo = .{
            .descriptor_pool = self.descriptor_pool, // Pool to allocate descriptor set from
 <<<<<<< Updated upstream
            .descriptor_set_count = @intCast(self.swapchain_images.len), // Number of sets to allocate
 =======
            .descriptor_set_count = @intCast(self.ctx.swapchain.swapchain_images.len), // Number of sets to allocate
 >>>>>>> Stashed changes
            .p_set_layouts = set_layouts.ptr, // Layouts to use to allocate sets (1:1 relationship)
        };
@ -1322,7 +1437,11 @@ pub const VulkanRenderer = struct {
        try self.device.allocateDescriptorSets(&set_alloc_info, self.descriptor_sets.ptr);
        // Update all of descriptor set buffer bindings
 <<<<<<< Updated upstream
        for (0..self.swapchain_images.len) |i| {
 =======
        for (0..self.ctx.swapchain.swapchain_images.len) |i| {
 >>>>>>> Stashed changes
            // -- View projection descriptor
            // Buffer info and data offset info
            const vp_buffer_info: vk.DescriptorBufferInfo = .{
@ -1352,10 +1471,17 @@ pub const VulkanRenderer = struct {
    }
    fn createInputDescriptorSets(self: *Self) !void {
 <<<<<<< Updated upstream
        self.input_descriptor_sets = try self.allocator.alloc(vk.DescriptorSet, self.swapchain_images.len);
        // Fill array of layouts ready for set creation
        var set_layouts = try self.allocator.alloc(vk.DescriptorSetLayout, self.swapchain_images.len);
 =======
        self.input_descriptor_sets = try self.allocator.alloc(vk.DescriptorSet, self.ctx.swapchain.swapchain_images.len);
        // Fill array of layouts ready for set creation
        var set_layouts = try self.allocator.alloc(vk.DescriptorSetLayout, self.ctx.swapchain.swapchain_images.len);
 >>>>>>> Stashed changes
        defer self.allocator.free(set_layouts);
        for (0..set_layouts.len) |i| {
            set_layouts[i] = self.input_set_layout;
@ -1364,7 +1490,11 @@ pub const VulkanRenderer = struct {
        // Input attachment descriptor set allocation info
        const set_alloc_info: vk.DescriptorSetAllocateInfo = .{
            .descriptor_pool = self.input_descriptor_pool,
 <<<<<<< Updated upstream
            .descriptor_set_count = @intCast(self.swapchain_images.len),
 =======
            .descriptor_set_count = @intCast(self.ctx.swapchain.swapchain_images.len),
 >>>>>>> Stashed changes
            .p_set_layouts = set_layouts.ptr,
        };
@ -1372,7 +1502,11 @@ pub const VulkanRenderer = struct {
        try self.device.allocateDescriptorSets(&set_alloc_info, self.input_descriptor_sets.ptr);
        // Update each descriptor set with input attachment
 <<<<<<< Updated upstream
        for (0..self.swapchain_images.len) |i| {
 =======
        for (0..self.ctx.swapchain.swapchain_images.len) |i| {
 >>>>>>> Stashed changes
            // Colour attachment descriptor
            const colour_attachment_descriptor: vk.DescriptorImageInfo = .{
                .image_layout = .shader_read_only_optimal,
@ -1451,11 +1585,19 @@ pub const VulkanRenderer = struct {
            .render_pass = self.render_pass, // Render pass to begin
            .render_area = .{
                .offset = .{ .x = 0, .y = 0 }, // Start point of render pass in pixels
 <<<<<<< Updated upstream
                .extent = self.extent, // Size of region to run render pass on (starting at offset)
            },
            .p_clear_values = &clear_values, // List of clear values
            .clear_value_count = @intCast(clear_values.len),
            .framebuffer = self.swapchain_framebuffers[current_image],
 =======
                .extent = self.ctx.swapchain.extent, // Size of region to run render pass on (starting at offset)
            },
            .p_clear_values = &clear_values, // List of clear values
            .clear_value_count = @intCast(clear_values.len),
            .framebuffer = self.ctx.swapchain.swapchain_framebuffers[current_image],
 >>>>>>> Stashed changes
        };
        const command_buffer = self.command_buffers[current_image];