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  1. 153
      src/main.zig
  2. 44
      src/shader.wgsl

@ -6,136 +6,66 @@ const zm = @import("zmath");
const vec = zm.f32x4;
const Mat = zm.Mat;
const VertexData = struct {
position: [3]f32,
};
const SceneUniformBuffer = struct {
view_proj_matrix: zm.Mat,
};
const ModelUniformBuffer = struct {
matrix: zm.Mat,
color: [3]f32,
};
pub const App = @This();
app_timer: core.Timer,
title_timer: core.Timer,
pipeline: *gpu.RenderPipeline,
scene_uniform_buffer: *gpu.Buffer,
scene_bind_group: *gpu.BindGroup,
model_uniform_buffers: [3]*gpu.Buffer,
model_bind_groups: [3]*gpu.BindGroup,
vertex_count: u32,
vertex_buffer: *gpu.Buffer,
mvp_uniform_buffer: *gpu.Buffer,
mvp_bind_group: *gpu.BindGroup,
pub fn init(app: *App) !void {
try core.init(.{});
app.app_timer = try core.Timer.start();
app.title_timer = try core.Timer.start();
const shader_module = core.device.createShaderModuleWGSL("shader.wgsl", @embedFile("shader.wgsl"));
defer shader_module.release();
// Set up rendering pipeline.
app.pipeline = core.device.createRenderPipeline(&.{
.vertex = gpu.VertexState.init(.{
.module = shader_module,
.entry_point = "vertex_main",
.buffers = &.{
gpu.VertexBufferLayout.init(.{
.array_stride = @sizeOf(VertexData),
.step_mode = .vertex,
.attributes = &.{
.{ .format = .float32x3, .shader_location = 0, .offset = @offsetOf(VertexData, "position") },
},
}),
},
}),
.fragment = &gpu.FragmentState.init(.{
const blend = gpu.BlendState{};
const color_target = gpu.ColorTargetState{
.format = core.descriptor.format,
.blend = &blend,
.write_mask = gpu.ColorWriteMaskFlags.all,
};
const fragment = gpu.FragmentState.init(.{
.module = shader_module,
.entry_point = "frag_main",
.targets = &.{.{ .format = core.descriptor.format }},
}),
.targets = &.{color_target},
});
const pipeline_descriptor = gpu.RenderPipeline.Descriptor{
.vertex = gpu.VertexState{
.module = shader_module,
.entry_point = "vertex_main",
},
.fragment = &fragment,
};
app.app_timer = try core.Timer.start();
app.title_timer = try core.Timer.start();
// Set up uniform buffers and bind groups.
app.pipeline = core.device.createRenderPipeline(&pipeline_descriptor);
// The "scene" uniform contains information for each rendered scene.
app.scene_uniform_buffer = core.device.createBuffer(&.{
app.mvp_uniform_buffer = core.device.createBuffer(&.{
.usage = .{ .copy_dst = true, .uniform = true },
.size = @sizeOf(SceneUniformBuffer),
.size = @sizeOf(zm.Mat),
.mapped_at_creation = .false,
});
app.scene_bind_group = core.device.createBindGroup(
&gpu.BindGroup.Descriptor.init(.{
.layout = app.pipeline.getBindGroupLayout(0),
.entries = &.{
gpu.BindGroup.Entry.buffer(0, app.scene_uniform_buffer, 0, @sizeOf(SceneUniformBuffer)),
},
}),
);
// The "model" uniforms contain information about how to render each model.
for (0..3) |i| {
app.model_uniform_buffers[i] = core.device.createBuffer(&.{
.usage = .{ .copy_dst = true, .uniform = true },
.size = @sizeOf(ModelUniformBuffer),
.mapped_at_creation = .false,
});
app.model_bind_groups[i] = core.device.createBindGroup(
app.mvp_bind_group = core.device.createBindGroup(
&gpu.BindGroup.Descriptor.init(.{
.layout = app.pipeline.getBindGroupLayout(1),
.layout = app.pipeline.getBindGroupLayout(0),
.entries = &.{
gpu.BindGroup.Entry.buffer(0, app.model_uniform_buffers[i], 0, @sizeOf(ModelUniformBuffer)),
gpu.BindGroup.Entry.buffer(0, app.mvp_uniform_buffer, 0, @sizeOf(zm.Mat)),
},
}),
);
}
// Upload model render information (matrix + color) to the GPU.
core.queue.writeBuffer(app.model_uniform_buffers[0], 0, &[_]ModelUniformBuffer{.{
.matrix = zm.transpose(zm.translation(-1.0, 0.25, 0.0)),
.color = .{ 1.0, 0.0, 0.0 },
}});
core.queue.writeBuffer(app.model_uniform_buffers[1], 0, &[_]ModelUniformBuffer{.{
.matrix = zm.transpose(zm.translation(0.0, -0.25, 0.0)),
.color = .{ 0.0, 1.0, 0.0 },
}});
core.queue.writeBuffer(app.model_uniform_buffers[2], 0, &[_]ModelUniformBuffer{.{
.matrix = zm.transpose(zm.translation(1.0, 0.0, 0.0)),
.color = .{ 0.0, 0.0, 1.0 },
}});
// Set up vertex buffer, containing the vertex data we want to draw.
const vertices = [_]VertexData{
.{ .position = .{ 0.0, 0.5, 0.0 } },
.{ .position = .{ -0.5, -0.5, 0.0 } },
.{ .position = .{ 0.5, -0.5, 0.0 } },
};
app.vertex_count = vertices.len;
app.vertex_buffer = core.device.createBuffer(&.{
.size = app.vertex_count * @sizeOf(VertexData),
.usage = .{ .vertex = true, .copy_dst = true },
.mapped_at_creation = .false,
});
// Upload vertex buffer to the GPU.
core.queue.writeBuffer(app.vertex_buffer, 0, &vertices);
}
pub fn deinit(app: *App) void {
// Using `defer` here, so we can specify them
// in the order they were created in `init`.
defer core.deinit();
defer app.pipeline.release();
defer app.scene_uniform_buffer.release();
defer app.scene_bind_group.release();
defer for (app.model_uniform_buffers) |b| b.release();
defer for (app.model_bind_groups) |g| g.release();
defer app.vertex_buffer.release();
defer app.mvp_uniform_buffer.release();
defer app.mvp_bind_group.release();
}
pub fn update(app: *App) !bool {
@ -171,25 +101,21 @@ pub fn update(app: *App) !bool {
// Once rendering is done (hence `defer`), swap back buffer to the front to display.
defer core.swap_chain.present();
const render_pass_info = gpu.RenderPassDescriptor.init(.{
.color_attachments = &.{.{
const color_attachment = gpu.RenderPassColorAttachment{
.view = back_buffer_view,
.clear_value = std.mem.zeroes(gpu.Color),
.load_op = .clear,
.store_op = .store,
}},
};
const render_pass_info = gpu.RenderPassDescriptor.init(.{
.color_attachments = &.{color_attachment},
});
// Create a `WGPUCommandEncoder` which provides an interface for recording GPU commands.
const encoder = core.device.createCommandEncoder(null);
defer encoder.release();
// Write to the scene uniform buffer for this set of commands.
encoder.writeBuffer(app.scene_uniform_buffer, 0, &[_]SceneUniformBuffer{.{
// All matrices the GPU has to work with need to be transposed,
// because WebGPU uses column-major matrices while zmath is row-major.
.view_proj_matrix = zm.transpose(view_proj_matrix),
}});
encoder.writeBuffer(app.mvp_uniform_buffer, 0, &[_]zm.Mat{zm.transpose(view_proj_matrix)});
{
const pass = encoder.beginRenderPass(&render_pass_info);
@ -197,15 +123,10 @@ pub fn update(app: *App) !bool {
defer pass.end();
pass.setPipeline(app.pipeline);
pass.setBindGroup(0, app.scene_bind_group, &.{});
pass.setVertexBuffer(0, app.vertex_buffer, 0, app.vertex_count * @sizeOf(VertexData));
for (app.model_bind_groups) |model_bind_group| {
// Set the model bind group for a specific model we want to render.
pass.setBindGroup(1, model_bind_group, &.{});
// Draw the vertices in `vertex_buffer`.
pass.draw(app.vertex_count, 1, 0, 0);
}
pass.setBindGroup(0, app.mvp_bind_group, &.{});
// Draw three triangles with the help of a specialized shader.
pass.draw(9, 1, 0, 0);
}
// Finish recording commands, creating a `WGPUCommandBuffer`.

@ -1,18 +1,4 @@
struct SceneUniformBuffer {
view_proj_matrix: mat4x4<f32>,
};
struct ModelUniformBuffer {
matrix: mat4x4<f32>,
color: vec3<f32>,
};
@group(0) @binding(0) var<uniform> scene: SceneUniformBuffer;
@group(1) @binding(0) var<uniform> model: ModelUniformBuffer;
struct VertexInput {
@location(0) position: vec3<f32>,
};
@group(0) @binding(0) var<uniform> mvp_matrix: mat4x4<f32>;
struct VertexOutput {
@builtin(position) position: vec4<f32>,
@ -23,11 +9,31 @@ struct FragmentOutput {
@location(0) pixel_color: vec4<f32>
};
@vertex fn vertex_main(in: VertexInput) -> VertexOutput {
@vertex fn vertex_main(
@builtin(vertex_index) index: u32
) -> VertexOutput {
let color = array<vec3<f32>, 3>(
vec3<f32>(1.0, 0.0, 0.0),
vec3<f32>(0.0, 1.0, 0.0),
vec3<f32>(0.0, 0.0, 1.0),
);
let pos = array<vec2<f32>, 9>(
vec2<f32>(-1.0, 0.5 + 0.25),
vec2<f32>(-1.5, -0.5 + 0.25),
vec2<f32>(-0.5, -0.5 + 0.25),
vec2<f32>( 0.0, 0.5 - 0.25),
vec2<f32>(-0.5, -0.5 - 0.25),
vec2<f32>( 0.5, -0.5 - 0.25),
vec2<f32>( 1.0, 0.5),
vec2<f32>( 0.5, -0.5),
vec2<f32>( 1.5, -0.5),
);
var out: VertexOutput;
let mvp = model.matrix * scene.view_proj_matrix;
out.position = vec4<f32>(in.position, 1.0) * mvp;
out.color = vec4<f32>(model.color, 1.0);
out.position = vec4<f32>(pos[index], 0.0, 1.0) * mvp_matrix;
out.color = vec4<f32>(color[index / 3], 1.0);
return out;
}

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