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mach/examples/sprite/App.zig
Stephen Gutekanst 69ff2e027f all: rename mod.entities -> mod.__entities (private) 
Signed-off-by: Stephen Gutekanst <stephen@hexops.com>
2024-05-07 23:40:56 -07:00

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// TODO(important): review all code in this file in-depth
const std = @import("std");
const zigimg = @import("zigimg");
const assets = @import("assets");
const mach = @import("mach");
const gpu = mach.gpu;
const gfx = mach.gfx;
const math = mach.math;
const vec2 = math.vec2;
const vec3 = math.vec3;
const Vec2 = math.Vec2;
const Vec3 = math.Vec3;
const Mat3x3 = math.Mat3x3;
const Mat4x4 = math.Mat4x4;
var gpa = std.heap.GeneralPurposeAllocator(.{}){};
timer: mach.Timer,
player: mach.EntityID,
direction: Vec2 = vec2(0, 0),
spawning: bool = false,
spawn_timer: mach.Timer,
fps_timer: mach.Timer,
frame_count: usize,
sprites: usize,
rand: std.rand.DefaultPrng,
time: f32,
allocator: std.mem.Allocator,
pipeline: mach.EntityID,
frame_encoder: *gpu.CommandEncoder = undefined,
frame_render_pass: *gpu.RenderPassEncoder = undefined,
// Define the globally unique name of our module. You can use any name here, but keep in mind no
// two modules in the program can have the same name.
pub const name = .app;
pub const Mod = mach.Mod(@This());
pub const events = .{
.init = .{ .handler = init },
.deinit = .{ .handler = deinit },
.tick = .{ .handler = tick },
.end_frame = .{ .handler = endFrame },
};
fn deinit(
core: *mach.Core.Mod,
sprite_pipeline: *gfx.SpritePipeline.Mod,
) !void {
sprite_pipeline.send(.init, .{});
core.send(.deinit, .{});
}
fn init(
core: *mach.Core.Mod,
sprite: *gfx.Sprite.Mod,
sprite_pipeline: *gfx.SpritePipeline.Mod,
game: *Mod,
) !void {
sprite_pipeline.send(.init, .{});
// We can create entities, and set components on them. Note that components live in a module
// namespace, e.g. the `.mach_gfx_sprite` module could have a 3D `.location` component with a different
// type than the `.physics2d` module's `.location` component if you desire.
// Create a sprite rendering pipeline
const allocator = gpa.allocator();
const pipeline = try core.newEntity();
try sprite_pipeline.set(pipeline, .texture, try loadTexture(core, allocator));
sprite_pipeline.send(.update, .{});
// Create our player sprite
const player = try core.newEntity();
try sprite.set(player, .transform, Mat4x4.translate(vec3(-0.02, 0, 0)));
try sprite.set(player, .size, vec2(32, 32));
try sprite.set(player, .uv_transform, Mat3x3.translate(vec2(0, 0)));
try sprite.set(player, .pipeline, pipeline);
sprite.send(.update, .{});
game.init(.{
.timer = try mach.Timer.start(),
.spawn_timer = try mach.Timer.start(),
.player = player,
.fps_timer = try mach.Timer.start(),
.frame_count = 0,
.sprites = 0,
.rand = std.rand.DefaultPrng.init(1337),
.time = 0,
.allocator = allocator,
.pipeline = pipeline,
});
core.send(.start, .{});
}
fn tick(
core: *mach.Core.Mod,
sprite: *gfx.Sprite.Mod,
sprite_pipeline: *gfx.SpritePipeline.Mod,
game: *Mod,
) !void {
// TODO(important): event polling should occur in mach.Core module and get fired as ECS events.
// TODO(Core)
var iter = mach.core.pollEvents();
var direction = game.state().direction;
var spawning = game.state().spawning;
while (iter.next()) |event| {
switch (event) {
.key_press => |ev| {
switch (ev.key) {
.left => direction.v[0] -= 1,
.right => direction.v[0] += 1,
.up => direction.v[1] += 1,
.down => direction.v[1] -= 1,
.space => spawning = true,
else => {},
}
},
.key_release => |ev| {
switch (ev.key) {
.left => direction.v[0] += 1,
.right => direction.v[0] -= 1,
.up => direction.v[1] -= 1,
.down => direction.v[1] += 1,
.space => spawning = false,
else => {},
}
},
.close => core.send(.exit, .{}),
else => {},
}
}
game.state().direction = direction;
game.state().spawning = spawning;
var player_transform = sprite.get(game.state().player, .transform).?;
var player_pos = player_transform.translation();
if (spawning and game.state().spawn_timer.read() > 1.0 / 60.0) {
// Spawn new entities
_ = game.state().spawn_timer.lap();
for (0..100) |_| {
var new_pos = player_pos;
new_pos.v[0] += game.state().rand.random().floatNorm(f32) * 25;
new_pos.v[1] += game.state().rand.random().floatNorm(f32) * 25;
const new_entity = try core.newEntity();
try sprite.set(new_entity, .transform, Mat4x4.translate(new_pos).mul(&Mat4x4.scale(Vec3.splat(0.3))));
try sprite.set(new_entity, .size, vec2(32, 32));
try sprite.set(new_entity, .uv_transform, Mat3x3.translate(vec2(0, 0)));
try sprite.set(new_entity, .pipeline, game.state().pipeline);
game.state().sprites += 1;
}
}
// Multiply by delta_time to ensure that movement is the same speed regardless of the frame rate.
const delta_time = game.state().timer.lap();
// Rotate entities
var archetypes_iter = core.__entities.queryDeprecated(.{ .all = &.{
.{ .mach_gfx_sprite = &.{.transform} },
} });
while (archetypes_iter.next()) |archetype| {
const ids = archetype.slice(.entity, .id);
const transforms = archetype.slice(.mach_gfx_sprite, .transform);
for (ids, transforms) |id, *old_transform| {
_ = id;
const location = old_transform.*.translation();
// var transform = old_transform.mul(&Mat4x4.translate(-location));
// transform = mat.rotateZ(0.3 * delta_time).mul(&transform);
// transform = transform.mul(&Mat4x4.translate(location));
var transform = Mat4x4.ident;
transform = transform.mul(&Mat4x4.translate(location));
transform = transform.mul(&Mat4x4.rotateZ(2 * math.pi * game.state().time));
transform = transform.mul(&Mat4x4.scaleScalar(@min(math.cos(game.state().time / 2.0), 0.5)));
// TODO: .set() API is substantially slower due to internals
// try sprite.set(id, .transform, transform);
old_transform.* = transform;
}
}
// Calculate the player position, by moving in the direction the player wants to go
// by the speed amount.
const speed = 200.0;
player_pos.v[0] += direction.x() * speed * delta_time;
player_pos.v[1] += direction.y() * speed * delta_time;
try sprite.set(game.state().player, .transform, Mat4x4.translate(player_pos));
sprite.send(.update, .{});
// Perform pre-render work
sprite_pipeline.send(.pre_render, .{});
// Create a command encoder for this frame
const label = @tagName(name) ++ ".tick";
game.state().frame_encoder = core.state().device.createCommandEncoder(&.{ .label = label });
// Grab the back buffer of the swapchain
// TODO(Core)
const back_buffer_view = mach.core.swap_chain.getCurrentTextureView().?;
defer back_buffer_view.release();
// Begin render pass
const sky_blue = gpu.Color{ .r = 0.776, .g = 0.988, .b = 1, .a = 1 };
const color_attachments = [_]gpu.RenderPassColorAttachment{.{
.view = back_buffer_view,
.clear_value = sky_blue,
.load_op = .clear,
.store_op = .store,
}};
game.state().frame_render_pass = game.state().frame_encoder.beginRenderPass(&gpu.RenderPassDescriptor.init(.{
.label = label,
.color_attachments = &color_attachments,
}));
// Render our sprite batch
sprite_pipeline.state().render_pass = game.state().frame_render_pass;
sprite_pipeline.send(.render, .{});
// Finish the frame once rendering is done.
game.send(.end_frame, .{});
game.state().time += delta_time;
}
fn endFrame(game: *Mod, core: *mach.Core.Mod) !void {
// Finish render pass
game.state().frame_render_pass.end();
const label = @tagName(name) ++ ".endFrame";
var command = game.state().frame_encoder.finish(&.{ .label = label });
game.state().frame_encoder.release();
defer command.release();
core.state().queue.submit(&[_]*gpu.CommandBuffer{command});
// Present the frame
core.send(.present_frame, .{});
// Every second, update the window title with the FPS
if (game.state().fps_timer.read() >= 1.0) {
try mach.Core.printTitle(
core,
core.state().main_window,
"sprite [ FPS: {d} ] [ Sprites: {d} ]",
.{ game.state().frame_count, game.state().sprites },
);
core.send(.update, .{});
game.state().fps_timer.reset();
game.state().frame_count = 0;
}
game.state().frame_count += 1;
}
// TODO: move this helper into gfx module
fn loadTexture(core: *mach.Core.Mod, allocator: std.mem.Allocator) !*gpu.Texture {
const device = core.state().device;
const queue = device.getQueue();
// Load the image from memory
var img = try zigimg.Image.fromMemory(allocator, assets.sprites_sheet_png);
defer img.deinit();
const img_size = gpu.Extent3D{ .width = @as(u32, @intCast(img.width)), .height = @as(u32, @intCast(img.height)) };
// Create a GPU texture
const label = @tagName(name) ++ ".loadTexture";
const texture = device.createTexture(&.{
.label = label,
.size = img_size,
.format = .rgba8_unorm,
.usage = .{
.texture_binding = true,
.copy_dst = true,
.render_attachment = true,
},
});
const data_layout = gpu.Texture.DataLayout{
.bytes_per_row = @as(u32, @intCast(img.width * 4)),
.rows_per_image = @as(u32, @intCast(img.height)),
};
switch (img.pixels) {
.rgba32 => |pixels| queue.writeTexture(&.{ .texture = texture }, &data_layout, &img_size, pixels),
.rgb24 => |pixels| {
const data = try rgb24ToRgba32(allocator, pixels);
defer data.deinit(allocator);
queue.writeTexture(&.{ .texture = texture }, &data_layout, &img_size, data.rgba32);
},
else => @panic("unsupported image color format"),
}
return texture;
}
fn rgb24ToRgba32(allocator: std.mem.Allocator, in: []zigimg.color.Rgb24) !zigimg.color.PixelStorage {
const out = try zigimg.color.PixelStorage.init(allocator, .rgba32, in.len);
var i: usize = 0;
while (i < in.len) : (i += 1) {
out.rgba32[i] = zigimg.color.Rgba32{ .r = in[i].r, .g = in[i].g, .b = in[i].b, .a = 255 };
}
return out;
}
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