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move noise to gfx.zig

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This commit is contained in:
David Allemang
2024-04-01 22:37:31 -04:00
parent 836daad0ae
commit 8e90619d6a
2 changed files with 480 additions and 470 deletions
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384
src/gfx.zig
View File

@@ -1,12 +1,396 @@
const std = @import("std"); const std = @import("std");
const builtin = @import("builtin"); const builtin = @import("builtin");
const vk = @import("vk"); const vk = @import("vk");
const c = @import("c.zig");
pub const use_debug_messenger = switch (builtin.mode) { pub const use_debug_messenger = switch (builtin.mode) {
.Debug, .ReleaseSafe => true, .Debug, .ReleaseSafe => true,
.ReleaseSmall, .ReleaseFast => false, .ReleaseSmall, .ReleaseFast => false,
}; };
const InstancePair = std.meta.Tuple(&.{ vk.Instance, InstanceDispatch, vk.DebugUtilsMessengerEXT });
/// note: destroy with vki.destroyInstance(instance, null)
pub fn create_instance(vkb: BaseDispatch, app_name: [*:0]const u8) !InstancePair {
var exts = std.BoundedArray([*:0]const u8, 32){};
var layers = std.BoundedArray([*:0]const u8, 32){};
if (use_debug_messenger) {
try exts.appendSlice(&.{
vk.extension_info.ext_debug_utils.name,
});
try layers.appendSlice(&.{
"VK_LAYER_KHRONOS_validation",
});
}
var glfw_exts_count: u32 = 0;
const glfw_exts: [*]const [*:0]const u8 =
@ptrCast(c.glfwGetRequiredInstanceExtensions(&glfw_exts_count));
try exts.appendSlice(glfw_exts[0..glfw_exts_count]);
const dumci: vk.DebugUtilsMessengerCreateInfoEXT = .{
.message_severity = .{
.error_bit_ext = true,
.info_bit_ext = true,
.verbose_bit_ext = true,
.warning_bit_ext = true,
},
.message_type = .{
.device_address_binding_bit_ext = true,
.general_bit_ext = false,
.performance_bit_ext = true,
.validation_bit_ext = true,
},
.pfn_user_callback = &debug_callback,
.p_user_data = null,
};
const instance = try vkb.createInstance(&vk.InstanceCreateInfo{
.p_application_info = &vk.ApplicationInfo{
.p_application_name = app_name,
.application_version = vk.makeApiVersion(0, 0, 0, 0),
.p_engine_name = app_name,
.engine_version = vk.makeApiVersion(0, 0, 0, 0),
.api_version = vk.API_VERSION_1_3,
},
.enabled_extension_count = @intCast(exts.len),
.pp_enabled_extension_names = &exts.buffer,
.enabled_layer_count = @intCast(layers.len),
.pp_enabled_layer_names = &layers.buffer,
.p_next = if (use_debug_messenger) &dumci else null,
}, null);
const vki = try InstanceDispatch.load(instance, vkb.dispatch.vkGetInstanceProcAddr);
errdefer vki.destroyInstance(instance, null);
const messenger: vk.DebugUtilsMessengerEXT = if (use_debug_messenger)
try vki.createDebugUtilsMessengerEXT(instance, &dumci, null)
else
.null_handle;
errdefer if (use_debug_messenger)
vki.destroyDebugUtilsMessengerEXT(instance, messenger, null);
return .{ instance, vki, messenger };
}
/// note: destroy with vki.destroySurfaceKHR(instance, surface, null)
pub fn create_surface(instance: vk.Instance, window: *c.GLFWwindow) !vk.SurfaceKHR {
var surface: vk.SurfaceKHR = undefined;
if (c.glfwCreateWindowSurface(instance, window, null, &surface) != .success) {
return error.SurfaceInitFailed;
}
return surface;
}
/// note: destroy with c.glfwDestroyWindow(window)
pub fn create_window(extent: vk.Extent2D, title: [*:0]const u8) !*c.GLFWwindow {
c.glfwWindowHintString(c.GLFW_X11_CLASS_NAME, "floating_window");
c.glfwWindowHintString(c.GLFW_X11_INSTANCE_NAME, "floating_window");
c.glfwWindowHint(c.GLFW_CLIENT_API, c.GLFW_NO_API);
return c.glfwCreateWindow(
@intCast(extent.width),
@intCast(extent.height),
title,
null,
null,
) orelse error.WindowInitFailed;
}
const DevicePair = std.meta.Tuple(&.{ vk.PhysicalDevice, vk.Device, DeviceDispatch, u32 });
/// note: destroy with vkd.destroyDevice(dev, null)
pub fn create_device(
ally: std.mem.Allocator,
instance: vk.Instance,
surface: vk.SurfaceKHR,
vki: InstanceDispatch,
) !DevicePair {
const required_device_extensions: []const [*:0]const u8 = &.{
vk.extension_info.khr_swapchain.name,
vk.extension_info.khr_dynamic_rendering.name,
};
var pdev_count: u32 = undefined;
_ = try vki.enumeratePhysicalDevices(instance, &pdev_count, null);
const pdevs = try ally.alloc(vk.PhysicalDevice, pdev_count);
defer ally.free(pdevs);
_ = try vki.enumeratePhysicalDevices(instance, &pdev_count, pdevs.ptr);
pdev_search: for (pdevs) |pdev| {
const props = vki.getPhysicalDeviceProperties(pdev);
if (props.device_type != .discrete_gpu) continue :pdev_search;
var format_count: u32 = undefined;
_ = try vki.getPhysicalDeviceSurfaceFormatsKHR(pdev, surface, &format_count, null);
if (format_count == 0) continue :pdev_search;
var mode_count: u32 = undefined;
_ = try vki.getPhysicalDeviceSurfacePresentModesKHR(pdev, surface, &mode_count, null);
if (mode_count == 0) continue :pdev_search;
var ext_count: u32 = undefined;
_ = try vki.enumerateDeviceExtensionProperties(pdev, null, &ext_count, null);
const exts = try ally.alloc(vk.ExtensionProperties, ext_count);
defer ally.free(exts);
_ = try vki.enumerateDeviceExtensionProperties(pdev, null, &ext_count, exts.ptr);
for (required_device_extensions) |name| {
for (exts) |ext| {
if (std.mem.eql(
u8,
std.mem.span(name),
std.mem.sliceTo(&ext.extension_name, 0),
)) {
break;
}
} else {
continue :pdev_search;
}
}
var family_count: u32 = undefined;
vki.getPhysicalDeviceQueueFamilyProperties(pdev, &family_count, null);
const families = try ally.alloc(vk.QueueFamilyProperties, family_count);
defer ally.free(families);
vki.getPhysicalDeviceQueueFamilyProperties(pdev, &family_count, families.ptr);
// just find one family that does graphics and present, so we can use exclusive sharing
// on the swapchain. apparently most hardware supports this. logic for queue allocation
// and swapchain creation is so much simpler this way. swapchain creation needs to know
// the list of queue family indices which will have access to the images, and there's a
// performance penalty to allow concurrent access to multiple queue families.
//
// multiple _queues_ may have exclusive access, but only if they're in the smae family.
const graphics_family: u32 = for (families, 0..) |family, idx| {
const graphics = family.queue_flags.graphics_bit;
const present = try vki.getPhysicalDeviceSurfaceSupportKHR(pdev, @intCast(idx), surface) == vk.TRUE;
if (graphics and present) {
break @intCast(idx);
}
} else {
continue :pdev_search;
};
std.log.debug("selecting device {s}", .{std.mem.sliceTo(&props.device_name, 0)});
const qci: []const vk.DeviceQueueCreateInfo = &.{
vk.DeviceQueueCreateInfo{
.queue_family_index = graphics_family,
.queue_count = 1,
.p_queue_priorities = &[_]f32{1.0},
},
};
const dev = try vki.createDevice(pdev, &.{
.queue_create_info_count = @intCast(qci.len),
.p_queue_create_infos = qci.ptr,
.enabled_extension_count = @intCast(required_device_extensions.len),
.pp_enabled_extension_names = required_device_extensions.ptr,
.p_next = &vk.PhysicalDeviceDynamicRenderingFeaturesKHR{
.dynamic_rendering = vk.TRUE,
},
}, null);
const vkd = try DeviceDispatch.load(dev, vki.dispatch.vkGetDeviceProcAddr);
errdefer vkd.destroyDevice(dev, null);
return .{ pdev, dev, vkd, graphics_family };
}
return error.NoSuitableDevice;
}
pub fn find_surface_format(
pdev: vk.PhysicalDevice,
vki: InstanceDispatch,
surface: vk.SurfaceKHR,
preferred: vk.SurfaceFormatKHR,
) !vk.SurfaceFormatKHR {
var formats_buf: [64]vk.SurfaceFormatKHR = undefined;
var formats_count: u32 = @intCast(formats_buf.len);
_ = try vki.getPhysicalDeviceSurfaceFormatsKHR(pdev, surface, &formats_count, &formats_buf);
const formats = formats_buf[0..formats_count];
for (formats) |format| {
if (std.meta.eql(format, preferred)) {
return format;
}
}
return formats[0];
}
pub fn find_present_mode(
pdev: vk.PhysicalDevice,
vki: InstanceDispatch,
surface: vk.SurfaceKHR,
preferred: vk.PresentModeKHR,
) !vk.PresentModeKHR {
var modes_buf: [8]vk.PresentModeKHR = undefined;
var modes_count: u32 = @intCast(modes_buf.len);
_ = try vki.getPhysicalDeviceSurfacePresentModesKHR(pdev, surface, &modes_count, &modes_buf);
const modes = modes_buf[0..modes_count];
for (modes) |mode| {
if (std.meta.eql(mode, preferred)) {
return mode;
}
}
return .mailbox_khr;
}
pub fn find_swap_extent(
pdev: vk.PhysicalDevice,
vki: InstanceDispatch,
surface: vk.SurfaceKHR,
window: *c.GLFWwindow,
) !vk.Extent2D {
const caps = try vki.getPhysicalDeviceSurfaceCapabilitiesKHR(pdev, surface);
var extent = caps.current_extent;
if (extent.width == std.math.maxInt(u32)) {
c.glfwGetFramebufferSize(window, @ptrCast(&extent.width), @ptrCast(&extent.height));
extent.width = std.math.clamp(extent.width, caps.min_image_extent.width, caps.max_image_extent.width);
extent.height = std.math.clamp(extent.height, caps.min_image_extent.height, caps.max_image_extent.height);
}
return extent;
}
pub fn find_swap_image_count(
pdev: vk.PhysicalDevice,
vki: InstanceDispatch,
surface: vk.SurfaceKHR,
) !u32 {
const caps = try vki.getPhysicalDeviceSurfaceCapabilitiesKHR(pdev, surface);
var count = caps.min_image_count + 1;
if (caps.max_image_count > 0) {
count = @min(count, caps.max_image_count);
}
return count;
}
pub fn uploadData(
comptime T: type,
pdev: vk.PhysicalDevice,
vki: InstanceDispatch,
dev: vk.Device,
vkd: DeviceDispatch,
queue: vk.Queue,
pool: vk.CommandPool,
buffer: vk.Buffer,
source: []const T,
) !void {
// if (@typeInfo(T) == .Struct and @typeInfo(T).Struct.layout == .auto) @compileError("Requires defined T layout");
const size = @sizeOf(T) * source.len;
const staging_buffer = try vkd.createBuffer(dev, &.{
.size = size,
.usage = .{ .transfer_src_bit = true },
.sharing_mode = .exclusive,
}, null);
defer vkd.destroyBuffer(dev, staging_buffer, null);
const mem_reqs = vkd.getBufferMemoryRequirements(dev, staging_buffer);
const staging_memory = try allocate(pdev, vki, dev, vkd, mem_reqs, .{
.host_visible_bit = true,
.host_coherent_bit = true,
});
defer vkd.freeMemory(dev, staging_memory, null);
try vkd.bindBufferMemory(dev, staging_buffer, staging_memory, 0);
{
const data = try vkd.mapMemory(dev, staging_memory, 0, vk.WHOLE_SIZE, .{});
defer vkd.unmapMemory(dev, staging_memory);
const dest: [*]T = @ptrCast(@alignCast(data));
@memcpy(dest, source);
}
try copyBuffer(dev, queue, pool, buffer, staging_buffer, size, vkd);
}
pub fn copyBuffer(
dev: vk.Device,
queue: vk.Queue,
pool: vk.CommandPool,
dst: vk.Buffer,
src: vk.Buffer,
size: vk.DeviceSize,
vkd: DeviceDispatch,
) !void {
var cmdbuf: vk.CommandBuffer = undefined;
try vkd.allocateCommandBuffers(dev, &.{
.command_pool = pool,
.level = .primary,
.command_buffer_count = 1,
}, @ptrCast(&cmdbuf));
defer vkd.freeCommandBuffers(dev, pool, 1, @ptrCast(&cmdbuf));
try vkd.beginCommandBuffer(cmdbuf, &.{
.flags = .{ .one_time_submit_bit = true },
});
const region = vk.BufferCopy{
.src_offset = 0,
.dst_offset = 0,
.size = size,
};
vkd.cmdCopyBuffer(cmdbuf, src, dst, 1, @ptrCast(&region));
try vkd.endCommandBuffer(cmdbuf);
const si = vk.SubmitInfo{
.command_buffer_count = 1,
.p_command_buffers = @ptrCast(&cmdbuf),
.p_wait_dst_stage_mask = undefined,
};
// creating and submitting a queue for every copy operation seems a bad idea for "streamed" data
// gonna want a way to send a copy operation WITH SYNCHRONIZATION PRIMITIVES on a particular queue
// see https://stackoverflow.com/a/62183243
//
// this may be a misunderstanding on how submission works...
try vkd.queueSubmit(queue, 1, @ptrCast(&si), .null_handle);
try vkd.queueWaitIdle(queue);
}
pub fn findMemoryTypeIndex(
pdev: vk.PhysicalDevice,
memory_type_bits: u32,
flags: vk.MemoryPropertyFlags,
vki: InstanceDispatch,
) !u32 {
const mem_props = vki.getPhysicalDeviceMemoryProperties(pdev);
for (mem_props.memory_types[0..mem_props.memory_type_count], 0..) |mem_type, i| {
if (memory_type_bits & (@as(u32, 1) << @truncate(i)) != 0 and mem_type.property_flags.contains(flags)) {
return @truncate(i);
}
}
return error.NoSuitableMemoryType;
}
pub fn allocate(
pdev: vk.PhysicalDevice,
vki: InstanceDispatch,
dev: vk.Device,
vkd: DeviceDispatch,
requirements: vk.MemoryRequirements,
flags: vk.MemoryPropertyFlags,
) !vk.DeviceMemory {
return try vkd.allocateMemory(dev, &.{
.allocation_size = requirements.size,
.memory_type_index = try findMemoryTypeIndex(pdev, requirements.memory_type_bits, flags, vki),
}, null);
}
pub const BaseDispatch = vk.BaseWrapper(.{ pub const BaseDispatch = vk.BaseWrapper(.{
.createInstance = true, .createInstance = true,
.getInstanceProcAddr = true, .getInstanceProcAddr = true,

566
src/main.zig
View File

@@ -50,271 +50,6 @@ const vertices = [_]Vertex{
const indices = [_]Index{ 4, 5, 6, 6, 5, 7 }; const indices = [_]Index{ 4, 5, 6, 6, 5, 7 };
const InstancePair = std.meta.Tuple(&.{ vk.Instance, gfx.InstanceDispatch, vk.DebugUtilsMessengerEXT });
/// note: destroy with vki.destroyInstance(instance, null)
fn create_instance(vkb: gfx.BaseDispatch) !InstancePair {
var exts = std.BoundedArray([*:0]const u8, 32){};
var layers = std.BoundedArray([*:0]const u8, 32){};
if (gfx.use_debug_messenger) {
try exts.appendSlice(&.{
vk.extension_info.ext_debug_utils.name,
});
try layers.appendSlice(&.{
"VK_LAYER_KHRONOS_validation",
});
}
var glfw_exts_count: u32 = 0;
const glfw_exts: [*]const [*:0]const u8 =
@ptrCast(c.glfwGetRequiredInstanceExtensions(&glfw_exts_count));
try exts.appendSlice(glfw_exts[0..glfw_exts_count]);
const dumci: vk.DebugUtilsMessengerCreateInfoEXT = .{
.message_severity = .{
.error_bit_ext = true,
.info_bit_ext = true,
.verbose_bit_ext = true,
.warning_bit_ext = true,
},
.message_type = .{
.device_address_binding_bit_ext = true,
.general_bit_ext = false,
.performance_bit_ext = true,
.validation_bit_ext = true,
},
.pfn_user_callback = &gfx.debug_callback,
.p_user_data = null,
};
const instance = try vkb.createInstance(&vk.InstanceCreateInfo{
.p_application_info = &vk.ApplicationInfo{
.p_application_name = app_name,
.application_version = vk.makeApiVersion(0, 0, 0, 0),
.p_engine_name = app_name,
.engine_version = vk.makeApiVersion(0, 0, 0, 0),
.api_version = vk.API_VERSION_1_3,
},
.enabled_extension_count = @intCast(exts.len),
.pp_enabled_extension_names = &exts.buffer,
.enabled_layer_count = @intCast(layers.len),
.pp_enabled_layer_names = &layers.buffer,
.p_next = if (gfx.use_debug_messenger) &dumci else null,
}, null);
const vki = try gfx.InstanceDispatch.load(instance, vkb.dispatch.vkGetInstanceProcAddr);
errdefer vki.destroyInstance(instance, null);
const messenger: vk.DebugUtilsMessengerEXT = if (gfx.use_debug_messenger)
try vki.createDebugUtilsMessengerEXT(instance, &dumci, null)
else
.null_handle;
errdefer if (gfx.use_debug_messenger)
vki.destroyDebugUtilsMessengerEXT(instance, messenger, null);
return .{ instance, vki, messenger };
}
/// note: destroy with vki.destroySurfaceKHR(instance, surface, null)
fn create_surface(instance: vk.Instance, window: *c.GLFWwindow) !vk.SurfaceKHR {
var surface: vk.SurfaceKHR = undefined;
if (c.glfwCreateWindowSurface(instance, window, null, &surface) != .success) {
return error.SurfaceInitFailed;
}
return surface;
}
/// note: destroy with c.glfwDestroyWindow(window)
fn create_window(extent: vk.Extent2D, title: [*:0]const u8) !*c.GLFWwindow {
c.glfwWindowHintString(c.GLFW_X11_CLASS_NAME, "floating_window");
c.glfwWindowHintString(c.GLFW_X11_INSTANCE_NAME, "floating_window");
c.glfwWindowHint(c.GLFW_CLIENT_API, c.GLFW_NO_API);
return c.glfwCreateWindow(
@intCast(extent.width),
@intCast(extent.height),
title,
null,
null,
) orelse error.WindowInitFailed;
}
const DevicePair = std.meta.Tuple(&.{ vk.PhysicalDevice, vk.Device, gfx.DeviceDispatch, u32 });
/// note: destroy with vkd.destroyDevice(dev, null)
fn create_device(
ally: std.mem.Allocator,
instance: vk.Instance,
surface: vk.SurfaceKHR,
vki: gfx.InstanceDispatch,
) !DevicePair {
const required_device_extensions: []const [*:0]const u8 = &.{
vk.extension_info.khr_swapchain.name,
vk.extension_info.khr_dynamic_rendering.name,
};
var pdev_count: u32 = undefined;
_ = try vki.enumeratePhysicalDevices(instance, &pdev_count, null);
const pdevs = try ally.alloc(vk.PhysicalDevice, pdev_count);
defer ally.free(pdevs);
_ = try vki.enumeratePhysicalDevices(instance, &pdev_count, pdevs.ptr);
pdev_search: for (pdevs) |pdev| {
const props = vki.getPhysicalDeviceProperties(pdev);
if (props.device_type != .discrete_gpu) continue :pdev_search;
var format_count: u32 = undefined;
_ = try vki.getPhysicalDeviceSurfaceFormatsKHR(pdev, surface, &format_count, null);
if (format_count == 0) continue :pdev_search;
var mode_count: u32 = undefined;
_ = try vki.getPhysicalDeviceSurfacePresentModesKHR(pdev, surface, &mode_count, null);
if (mode_count == 0) continue :pdev_search;
var ext_count: u32 = undefined;
_ = try vki.enumerateDeviceExtensionProperties(pdev, null, &ext_count, null);
const exts = try ally.alloc(vk.ExtensionProperties, ext_count);
defer ally.free(exts);
_ = try vki.enumerateDeviceExtensionProperties(pdev, null, &ext_count, exts.ptr);
for (required_device_extensions) |name| {
for (exts) |ext| {
if (std.mem.eql(
u8,
std.mem.span(name),
std.mem.sliceTo(&ext.extension_name, 0),
)) {
break;
}
} else {
continue :pdev_search;
}
}
var family_count: u32 = undefined;
vki.getPhysicalDeviceQueueFamilyProperties(pdev, &family_count, null);
const families = try ally.alloc(vk.QueueFamilyProperties, family_count);
defer ally.free(families);
vki.getPhysicalDeviceQueueFamilyProperties(pdev, &family_count, families.ptr);
// just find one family that does graphics and present, so we can use exclusive sharing
// on the swapchain. apparently most hardware supports this. logic for queue allocation
// and swapchain creation is so much simpler this way. swapchain creation needs to know
// the list of queue family indices which will have access to the images, and there's a
// performance penalty to allow concurrent access to multiple queue families.
//
// multiple _queues_ may have exclusive access, but only if they're in the smae family.
const graphics_family: u32 = for (families, 0..) |family, idx| {
const graphics = family.queue_flags.graphics_bit;
const present = try vki.getPhysicalDeviceSurfaceSupportKHR(pdev, @intCast(idx), surface) == vk.TRUE;
if (graphics and present) {
break @intCast(idx);
}
} else {
continue :pdev_search;
};
std.log.debug("selecting device {s}", .{std.mem.sliceTo(&props.device_name, 0)});
const qci: []const vk.DeviceQueueCreateInfo = &.{
vk.DeviceQueueCreateInfo{
.queue_family_index = graphics_family,
.queue_count = 1,
.p_queue_priorities = &[_]f32{1.0},
},
};
const dev = try vki.createDevice(pdev, &.{
.queue_create_info_count = @intCast(qci.len),
.p_queue_create_infos = qci.ptr,
.enabled_extension_count = @intCast(required_device_extensions.len),
.pp_enabled_extension_names = required_device_extensions.ptr,
.p_next = &vk.PhysicalDeviceDynamicRenderingFeaturesKHR{
.dynamic_rendering = vk.TRUE,
},
}, null);
const vkd = try gfx.DeviceDispatch.load(dev, vki.dispatch.vkGetDeviceProcAddr);
errdefer vkd.destroyDevice(dev, null);
return .{ pdev, dev, vkd, graphics_family };
}
return error.NoSuitableDevice;
}
fn find_surface_format(
pdev: vk.PhysicalDevice,
vki: gfx.InstanceDispatch,
surface: vk.SurfaceKHR,
preferred: vk.SurfaceFormatKHR,
) !vk.SurfaceFormatKHR {
var formats_buf: [64]vk.SurfaceFormatKHR = undefined;
var formats_count: u32 = @intCast(formats_buf.len);
_ = try vki.getPhysicalDeviceSurfaceFormatsKHR(pdev, surface, &formats_count, &formats_buf);
const formats = formats_buf[0..formats_count];
for (formats) |format| {
if (std.meta.eql(format, preferred)) {
return format;
}
}
return formats[0];
}
fn find_present_mode(
pdev: vk.PhysicalDevice,
vki: gfx.InstanceDispatch,
surface: vk.SurfaceKHR,
preferred: vk.PresentModeKHR,
) !vk.PresentModeKHR {
var modes_buf: [8]vk.PresentModeKHR = undefined;
var modes_count: u32 = @intCast(modes_buf.len);
_ = try vki.getPhysicalDeviceSurfacePresentModesKHR(pdev, surface, &modes_count, &modes_buf);
const modes = modes_buf[0..modes_count];
for (modes) |mode| {
if (std.meta.eql(mode, preferred)) {
return mode;
}
}
return .mailbox_khr;
}
fn find_swap_extent(
pdev: vk.PhysicalDevice,
vki: gfx.InstanceDispatch,
surface: vk.SurfaceKHR,
window: *c.GLFWwindow,
) !vk.Extent2D {
const caps = try vki.getPhysicalDeviceSurfaceCapabilitiesKHR(pdev, surface);
var extent = caps.current_extent;
if (extent.width == std.math.maxInt(u32)) {
c.glfwGetFramebufferSize(window, @ptrCast(&extent.width), @ptrCast(&extent.height));
extent.width = std.math.clamp(extent.width, caps.min_image_extent.width, caps.max_image_extent.width);
extent.height = std.math.clamp(extent.height, caps.min_image_extent.height, caps.max_image_extent.height);
}
return extent;
}
fn find_swap_image_count(
pdev: vk.PhysicalDevice,
vki: gfx.InstanceDispatch,
surface: vk.SurfaceKHR,
) !u32 {
const caps = try vki.getPhysicalDeviceSurfaceCapabilitiesKHR(pdev, surface);
var count = caps.min_image_count + 1;
if (caps.max_image_count > 0) {
count = @min(count, caps.max_image_count);
}
return count;
}
pub fn main() !void { pub fn main() !void {
var gpa = std.heap.GeneralPurposeAllocator(.{}){}; var gpa = std.heap.GeneralPurposeAllocator(.{}){};
defer _ = gpa.deinit(); defer _ = gpa.deinit();
@@ -330,21 +65,21 @@ pub fn main() !void {
var extent = vk.Extent2D{ .width = 800, .height = 600 }; var extent = vk.Extent2D{ .width = 800, .height = 600 };
const window = try create_window(extent, app_name); const window = try gfx.create_window(extent, app_name);
defer c.glfwDestroyWindow(window); defer c.glfwDestroyWindow(window);
const vkb = try gfx.BaseDispatch.load(c.glfwGetInstanceProcAddress); const vkb = try gfx.BaseDispatch.load(c.glfwGetInstanceProcAddress);
const instance, const vki, const messenger = try create_instance(vkb); const instance, const vki, const messenger = try gfx.create_instance(vkb, app_name);
defer vki.destroyInstance(instance, null); defer vki.destroyInstance(instance, null);
defer if (gfx.use_debug_messenger) defer if (gfx.use_debug_messenger)
vki.destroyDebugUtilsMessengerEXT(instance, messenger, null); vki.destroyDebugUtilsMessengerEXT(instance, messenger, null);
const surface = try create_surface(instance, window); const surface = try gfx.create_surface(instance, window);
defer vki.destroySurfaceKHR(instance, surface, null); defer vki.destroySurfaceKHR(instance, surface, null);
const pdev: vk.PhysicalDevice, const dev: vk.Device, const vkd: gfx.DeviceDispatch, const family: u32 = const pdev: vk.PhysicalDevice, const dev: vk.Device, const vkd: gfx.DeviceDispatch, const family: u32 =
try create_device(ally, instance, surface, vki); try gfx.create_device(ally, instance, surface, vki);
defer vkd.destroyDevice(dev, null); defer vkd.destroyDevice(dev, null);
const queue = vkd.getDeviceQueue(dev, family, 0); const queue = vkd.getDeviceQueue(dev, family, 0);
@@ -353,12 +88,12 @@ pub fn main() !void {
.format = .b8g8r8a8_srgb, .format = .b8g8r8a8_srgb,
.color_space = .srgb_nonlinear_khr, .color_space = .srgb_nonlinear_khr,
}; };
const format = try find_surface_format(pdev, vki, surface, preferred_format); const format = try gfx.find_surface_format(pdev, vki, surface, preferred_format);
extent = try find_swap_extent(pdev, vki, surface, window); extent = try gfx.find_swap_extent(pdev, vki, surface, window);
const present_mode = try find_present_mode(pdev, vki, surface, .mailbox_khr); const present_mode = try gfx.find_present_mode(pdev, vki, surface, .mailbox_khr);
const swap_image_count = try find_swap_image_count(pdev, vki, surface); const swap_image_count = try gfx.find_swap_image_count(pdev, vki, surface);
var swapchain: vk.SwapchainKHR = .null_handle; var swapchain: vk.SwapchainKHR = .null_handle;
defer vkd.destroySwapchainKHR(dev, swapchain, null); defer vkd.destroySwapchainKHR(dev, swapchain, null);
@@ -432,11 +167,11 @@ pub fn main() !void {
}, null); }, null);
defer vkd.destroyBuffer(dev, vertex_buffer, null); defer vkd.destroyBuffer(dev, vertex_buffer, null);
const vertex_mem_reqs = vkd.getBufferMemoryRequirements(dev, vertex_buffer); const vertex_mem_reqs = vkd.getBufferMemoryRequirements(dev, vertex_buffer);
const vertex_memory = try allocate(pdev, vki, dev, vkd, vertex_mem_reqs, .{ .device_local_bit = true }); const vertex_memory = try gfx.allocate(pdev, vki, dev, vkd, vertex_mem_reqs, .{ .device_local_bit = true });
defer vkd.freeMemory(dev, vertex_memory, null); defer vkd.freeMemory(dev, vertex_memory, null);
try vkd.bindBufferMemory(dev, vertex_buffer, vertex_memory, 0); try vkd.bindBufferMemory(dev, vertex_buffer, vertex_memory, 0);
try uploadData(Vertex, pdev, vki, dev, vkd, queue, pool, vertex_buffer, &vertices); try gfx.uploadData(Vertex, pdev, vki, dev, vkd, queue, pool, vertex_buffer, &vertices);
const index_buffer = try vkd.createBuffer(dev, &.{ const index_buffer = try vkd.createBuffer(dev, &.{
.size = @sizeOf(@TypeOf(indices)), .size = @sizeOf(@TypeOf(indices)),
@@ -445,11 +180,11 @@ pub fn main() !void {
}, null); }, null);
defer vkd.destroyBuffer(dev, index_buffer, null); defer vkd.destroyBuffer(dev, index_buffer, null);
const index_mem_reqs = vkd.getBufferMemoryRequirements(dev, index_buffer); const index_mem_reqs = vkd.getBufferMemoryRequirements(dev, index_buffer);
const index_memory = try allocate(pdev, vki, dev, vkd, index_mem_reqs, .{ .device_local_bit = true }); const index_memory = try gfx.allocate(pdev, vki, dev, vkd, index_mem_reqs, .{ .device_local_bit = true });
defer vkd.freeMemory(dev, index_memory, null); defer vkd.freeMemory(dev, index_memory, null);
try vkd.bindBufferMemory(dev, index_buffer, index_memory, 0); try vkd.bindBufferMemory(dev, index_buffer, index_memory, 0);
try uploadData(Index, pdev, vki, dev, vkd, queue, pool, index_buffer, &indices); try gfx.uploadData(Index, pdev, vki, dev, vkd, queue, pool, index_buffer, &indices);
// var cmdbufs = try createCommandBuffers( // var cmdbufs = try createCommandBuffers(
// &gc, // &gc,
@@ -505,92 +240,6 @@ pub fn main() !void {
try vkd.deviceWaitIdle(dev); try vkd.deviceWaitIdle(dev);
} }
fn uploadData(
comptime T: type,
pdev: vk.PhysicalDevice,
vki: gfx.InstanceDispatch,
dev: vk.Device,
vkd: gfx.DeviceDispatch,
queue: vk.Queue,
pool: vk.CommandPool,
buffer: vk.Buffer,
source: []const T,
) !void {
// if (@typeInfo(T) == .Struct and @typeInfo(T).Struct.layout == .auto) @compileError("Requires defined T layout");
const size = @sizeOf(T) * source.len;
const staging_buffer = try vkd.createBuffer(dev, &.{
.size = size,
.usage = .{ .transfer_src_bit = true },
.sharing_mode = .exclusive,
}, null);
defer vkd.destroyBuffer(dev, staging_buffer, null);
const mem_reqs = vkd.getBufferMemoryRequirements(dev, staging_buffer);
const staging_memory = try allocate(pdev, vki, dev, vkd, mem_reqs, .{
.host_visible_bit = true,
.host_coherent_bit = true,
});
defer vkd.freeMemory(dev, staging_memory, null);
try vkd.bindBufferMemory(dev, staging_buffer, staging_memory, 0);
{
const data = try vkd.mapMemory(dev, staging_memory, 0, vk.WHOLE_SIZE, .{});
defer vkd.unmapMemory(dev, staging_memory);
const dest: [*]T = @ptrCast(@alignCast(data));
@memcpy(dest, source);
}
try copyBuffer(dev, queue, pool, buffer, staging_buffer, size, vkd);
}
fn copyBuffer(
dev: vk.Device,
queue: vk.Queue,
pool: vk.CommandPool,
dst: vk.Buffer,
src: vk.Buffer,
size: vk.DeviceSize,
vkd: gfx.DeviceDispatch,
) !void {
var cmdbuf: vk.CommandBuffer = undefined;
try vkd.allocateCommandBuffers(dev, &.{
.command_pool = pool,
.level = .primary,
.command_buffer_count = 1,
}, @ptrCast(&cmdbuf));
defer vkd.freeCommandBuffers(dev, pool, 1, @ptrCast(&cmdbuf));
try vkd.beginCommandBuffer(cmdbuf, &.{
.flags = .{ .one_time_submit_bit = true },
});
const region = vk.BufferCopy{
.src_offset = 0,
.dst_offset = 0,
.size = size,
};
vkd.cmdCopyBuffer(cmdbuf, src, dst, 1, @ptrCast(&region));
try vkd.endCommandBuffer(cmdbuf);
const si = vk.SubmitInfo{
.command_buffer_count = 1,
.p_command_buffers = @ptrCast(&cmdbuf),
.p_wait_dst_stage_mask = undefined,
};
// creating and submitting a queue for every copy operation seems a bad idea for "streamed" data
// gonna want a way to send a copy operation WITH SYNCHRONIZATION PRIMITIVES on a particular queue
// see https://stackoverflow.com/a/62183243
//
// this may be a misunderstanding on how submission works...
try vkd.queueSubmit(queue, 1, @ptrCast(&si), .null_handle);
try vkd.queueWaitIdle(queue);
}
fn createCommandBuffers( fn createCommandBuffers(
views: []const vk.Image, views: []const vk.Image,
images: []const vk.ImageView, images: []const vk.ImageView,
@@ -767,118 +416,95 @@ fn createPipeline(dev: vk.Device, layout: vk.PipelineLayout, format: vk.SurfaceF
}, },
}; };
const pcbas = vk.PipelineColorBlendAttachmentState{ const color_blend_attachment_states = [_]vk.PipelineColorBlendAttachmentState{
.blend_enable = vk.FALSE, vk.PipelineColorBlendAttachmentState{
.src_color_blend_factor = .one, .blend_enable = vk.FALSE,
.dst_color_blend_factor = .zero, .src_color_blend_factor = .one,
.color_blend_op = .add, .dst_color_blend_factor = .zero,
.src_alpha_blend_factor = .one, .color_blend_op = .add,
.dst_alpha_blend_factor = .zero, .src_alpha_blend_factor = .one,
.alpha_blend_op = .add, .dst_alpha_blend_factor = .zero,
.color_write_mask = .{ .r_bit = true, .g_bit = true, .b_bit = true, .a_bit = true }, .alpha_blend_op = .add,
.color_write_mask = .{ .r_bit = true, .g_bit = true, .b_bit = true, .a_bit = true },
},
}; };
const dynstate = [_]vk.DynamicState{ .viewport, .scissor }; const dynamic_states = [_]vk.DynamicState{
.viewport,
.scissor,
};
const gpci = vk.GraphicsPipelineCreateInfo{ const create_infos = [_]vk.GraphicsPipelineCreateInfo{
.flags = .{}, .{
.stage_count = @intCast(pssci.len),
.p_stages = &pssci,
.p_vertex_input_state = &vk.PipelineVertexInputStateCreateInfo{
.vertex_binding_description_count = 1,
.p_vertex_binding_descriptions = @ptrCast(&Vertex.binding_description),
.vertex_attribute_description_count = Vertex.attribute_description.len,
.p_vertex_attribute_descriptions = &Vertex.attribute_description,
},
.p_input_assembly_state = &vk.PipelineInputAssemblyStateCreateInfo{
.topology = .triangle_list,
.primitive_restart_enable = vk.FALSE,
},
.p_tessellation_state = null,
.p_viewport_state = &vk.PipelineViewportStateCreateInfo{
.viewport_count = 1,
.p_viewports = undefined, // set in createCommandBuffers with cmdSetViewport
.scissor_count = 1,
.p_scissors = undefined, // set in createCommandBuffers with cmdSetScissor
},
.p_rasterization_state = &vk.PipelineRasterizationStateCreateInfo{
.depth_clamp_enable = vk.FALSE,
.rasterizer_discard_enable = vk.FALSE,
.polygon_mode = .fill,
.cull_mode = .{ .back_bit = true },
.front_face = .counter_clockwise,
.depth_bias_enable = vk.FALSE,
.depth_bias_constant_factor = 0,
.depth_bias_clamp = 0,
.depth_bias_slope_factor = 0,
.line_width = 1,
},
.p_multisample_state = &vk.PipelineMultisampleStateCreateInfo{
.rasterization_samples = .{ .@"1_bit" = true },
.sample_shading_enable = vk.FALSE,
.min_sample_shading = 1,
.alpha_to_coverage_enable = vk.FALSE,
.alpha_to_one_enable = vk.FALSE,
},
.p_depth_stencil_state = null,
.p_color_blend_state = &vk.PipelineColorBlendStateCreateInfo{
.logic_op_enable = vk.FALSE,
.logic_op = .copy,
.attachment_count = 1,
.p_attachments = @ptrCast(&pcbas),
.blend_constants = [_]f32{ 0, 0, 0, 0 },
},
.p_dynamic_state = &vk.PipelineDynamicStateCreateInfo{
.flags = .{}, .flags = .{},
.dynamic_state_count = dynstate.len, .stage_count = @intCast(pssci.len),
.p_dynamic_states = &dynstate, .p_stages = &pssci,
}, .p_vertex_input_state = &vk.PipelineVertexInputStateCreateInfo{
.layout = layout, .vertex_binding_description_count = 1,
.render_pass = .null_handle, .p_vertex_binding_descriptions = @ptrCast(&Vertex.binding_description),
.subpass = 0, .vertex_attribute_description_count = Vertex.attribute_description.len,
.base_pipeline_handle = .null_handle, .p_vertex_attribute_descriptions = &Vertex.attribute_description,
.base_pipeline_index = -1, },
.p_next = &vk.PipelineRenderingCreateInfoKHR{ .p_input_assembly_state = &vk.PipelineInputAssemblyStateCreateInfo{
.color_attachment_count = 1, .topology = .triangle_list,
.p_color_attachment_formats = @ptrCast(&format), .primitive_restart_enable = vk.FALSE,
.depth_attachment_format = .undefined, },
.stencil_attachment_format = .undefined, .p_tessellation_state = null,
.view_mask = 0, .p_viewport_state = &vk.PipelineViewportStateCreateInfo{
.viewport_count = 1,
.p_viewports = undefined, // set in createCommandBuffers with cmdSetViewport
.scissor_count = 1,
.p_scissors = undefined, // set in createCommandBuffers with cmdSetScissor
},
.p_rasterization_state = &vk.PipelineRasterizationStateCreateInfo{
.depth_clamp_enable = vk.FALSE,
.rasterizer_discard_enable = vk.FALSE,
.polygon_mode = .fill,
.cull_mode = .{ .back_bit = true },
.front_face = .counter_clockwise,
.depth_bias_enable = vk.FALSE,
.depth_bias_constant_factor = 0,
.depth_bias_clamp = 0,
.depth_bias_slope_factor = 0,
.line_width = 1,
},
.p_multisample_state = &vk.PipelineMultisampleStateCreateInfo{
.rasterization_samples = .{ .@"1_bit" = true },
.sample_shading_enable = vk.FALSE,
.min_sample_shading = 1,
.alpha_to_coverage_enable = vk.FALSE,
.alpha_to_one_enable = vk.FALSE,
},
.p_depth_stencil_state = null,
.p_color_blend_state = &vk.PipelineColorBlendStateCreateInfo{
.logic_op_enable = vk.FALSE,
.logic_op = .copy,
.attachment_count = @intCast(color_blend_attachment_states.len),
.p_attachments = &color_blend_attachment_states,
.blend_constants = [_]f32{ 0, 0, 0, 0 },
},
.p_dynamic_state = &vk.PipelineDynamicStateCreateInfo{
.flags = .{},
.dynamic_state_count = @intCast(dynamic_states.len),
.p_dynamic_states = &dynamic_states,
},
.layout = layout,
.render_pass = .null_handle,
.subpass = 0,
.base_pipeline_handle = .null_handle,
.base_pipeline_index = -1,
.p_next = &vk.PipelineRenderingCreateInfoKHR{
.color_attachment_count = 1,
.p_color_attachment_formats = @ptrCast(&format),
.depth_attachment_format = .undefined,
.stencil_attachment_format = .undefined,
.view_mask = 0,
},
}, },
}; };
var pipeline: vk.Pipeline = undefined; var pipelines: [create_infos.len]vk.Pipeline = undefined;
_ = try vkd.createGraphicsPipelines(dev, .null_handle, 1, @ptrCast(&gpci), null, @ptrCast(&pipeline)); _ = try vkd.createGraphicsPipelines(dev, .null_handle, @intCast(create_infos.len), &create_infos, null, &pipelines);
return pipeline; std.debug.assert(pipelines.len == 1);
} return pipelines[0];
pub fn findMemoryTypeIndex(
pdev: vk.PhysicalDevice,
memory_type_bits: u32,
flags: vk.MemoryPropertyFlags,
vki: gfx.InstanceDispatch,
) !u32 {
const mem_props = vki.getPhysicalDeviceMemoryProperties(pdev);
for (mem_props.memory_types[0..mem_props.memory_type_count], 0..) |mem_type, i| {
if (memory_type_bits & (@as(u32, 1) << @truncate(i)) != 0 and mem_type.property_flags.contains(flags)) {
return @truncate(i);
}
}
return error.NoSuitableMemoryType;
}
pub fn allocate(
pdev: vk.PhysicalDevice,
vki: gfx.InstanceDispatch,
dev: vk.Device,
vkd: gfx.DeviceDispatch,
requirements: vk.MemoryRequirements,
flags: vk.MemoryPropertyFlags,
) !vk.DeviceMemory {
return try vkd.allocateMemory(dev, &.{
.allocation_size = requirements.size,
.memory_type_index = try findMemoryTypeIndex(pdev, requirements.memory_type_bits, flags, vki),
}, null);
} }