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use std ::{ borrow ::Cow , time ::Instant } ;
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use wgpu ::{ util ::DeviceExt , AstcBlock , AstcChannel } ;
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use model_graphics ::{ GraphicsVertex , ModelGraphicsInstance } ;
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use physics ::{ InputInstruction , PhysicsInstruction } ;
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use instruction ::{ TimedInstruction , InstructionConsumer } ;
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mod bvh ;
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mod aabb ;
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mod model ;
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mod model_graphics ;
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mod zeroes ;
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mod worker ;
mod physics ;
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mod settings ;
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mod framework ;
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mod primitives ;
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mod instruction ;
mod load_roblox ;
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mod integer ;
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struct Entity {
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index_count : u32 ,
index_buf : wgpu ::Buffer ,
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}
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struct ModelGraphics {
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instances : Vec < ModelGraphicsInstance > ,
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vertex_buf : wgpu ::Buffer ,
entities : Vec < Entity > ,
bind_group : wgpu ::BindGroup ,
model_buf : wgpu ::Buffer ,
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}
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pub struct GraphicsSamplers {
repeat : wgpu ::Sampler ,
}
pub struct GraphicsBindGroupLayouts {
model : wgpu ::BindGroupLayout ,
}
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pub struct GraphicsBindGroups {
camera : wgpu ::BindGroup ,
skybox_texture : wgpu ::BindGroup ,
}
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pub struct GraphicsPipelines {
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skybox : wgpu ::RenderPipeline ,
model : wgpu ::RenderPipeline ,
}
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pub struct GraphicsCamera {
screen_size : glam ::UVec2 ,
fov : glam ::Vec2 , //slope
//camera angles and such are extrapolated and passed in every time
}
#[ inline ]
fn perspective_rh ( fov_x_slope : f32 , fov_y_slope : f32 , z_near : f32 , z_far : f32 ) -> glam ::Mat4 {
//glam_assert!(z_near > 0.0 && z_far > 0.0);
let r = z_far / ( z_near - z_far ) ;
glam ::Mat4 ::from_cols (
glam ::Vec4 ::new ( 1.0 / fov_x_slope , 0.0 , 0.0 , 0.0 ) ,
glam ::Vec4 ::new ( 0.0 , 1.0 / fov_y_slope , 0.0 , 0.0 ) ,
glam ::Vec4 ::new ( 0.0 , 0.0 , r , - 1.0 ) ,
glam ::Vec4 ::new ( 0.0 , 0.0 , r * z_near , 0.0 ) ,
)
}
impl GraphicsCamera {
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pub fn new ( screen_size :glam ::UVec2 , fov :glam ::Vec2 ) ->Self {
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Self {
screen_size ,
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fov ,
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}
}
pub fn proj ( & self ) ->glam ::Mat4 {
perspective_rh ( self . fov . x , self . fov . y , 0.5 , 2000.0 )
}
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pub fn world ( & self , pos :glam ::Vec3 , angles :glam ::Vec2 ) ->glam ::Mat4 {
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//f32 good enough for view matrix
glam ::Mat4 ::from_translation ( pos ) * glam ::Mat4 ::from_euler ( glam ::EulerRot ::YXZ , angles . x , angles . y , 0 f32 )
}
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pub fn to_uniform_data ( & self , ( pos , angles ) : ( glam ::Vec3 , glam ::Vec2 ) ) -> [ f32 ; 16 * 4 ] {
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let proj = self . proj ( ) ;
let proj_inv = proj . inverse ( ) ;
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let view_inv = self . world ( pos , angles ) ;
let view = view_inv . inverse ( ) ;
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let mut raw = [ 0 f32 ; 16 * 4 ] ;
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raw [ .. 16 ] . copy_from_slice ( & AsRef ::< [ f32 ; 16 ] > ::as_ref ( & proj ) [ .. ] ) ;
raw [ 16 .. 32 ] . copy_from_slice ( & AsRef ::< [ f32 ; 16 ] > ::as_ref ( & proj_inv ) [ .. ] ) ;
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raw [ 32 .. 48 ] . copy_from_slice ( & AsRef ::< [ f32 ; 16 ] > ::as_ref ( & view ) [ .. ] ) ;
raw [ 48 .. 64 ] . copy_from_slice ( & AsRef ::< [ f32 ; 16 ] > ::as_ref ( & view_inv ) [ .. ] ) ;
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raw
}
}
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pub struct GraphicsState {
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pipelines : GraphicsPipelines ,
bind_groups : GraphicsBindGroups ,
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bind_group_layouts : GraphicsBindGroupLayouts ,
samplers : GraphicsSamplers ,
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camera :GraphicsCamera ,
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camera_buf : wgpu ::Buffer ,
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temp_squid_texture_view : wgpu ::TextureView ,
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models : Vec < ModelGraphics > ,
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depth_view : wgpu ::TextureView ,
staging_belt : wgpu ::util ::StagingBelt ,
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}
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impl GraphicsState {
pub fn clear ( & mut self ) {
self . models . clear ( ) ;
}
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pub fn load_user_settings ( & mut self , user_settings :& settings ::UserSettings ) {
self . camera . fov = user_settings . calculate_fov ( 1.0 , & self . camera . screen_size ) . as_vec2 ( ) ;
}
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}
pub struct GlobalState {
start_time : std ::time ::Instant ,
manual_mouse_lock :bool ,
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mouse :physics ::MouseState ,
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user_settings :settings ::UserSettings ,
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graphics :GraphicsState ,
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physics_thread :worker ::CompatWorker < TimedInstruction < InputInstruction > , physics ::PhysicsOutputState , Box < dyn FnMut ( TimedInstruction < InputInstruction > ) ->physics ::PhysicsOutputState > > ,
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}
impl GlobalState {
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const DEPTH_FORMAT : wgpu ::TextureFormat = wgpu ::TextureFormat ::Depth24Plus ;
fn create_depth_texture (
config : & wgpu ::SurfaceConfiguration ,
device : & wgpu ::Device ,
) -> wgpu ::TextureView {
let depth_texture = device . create_texture ( & wgpu ::TextureDescriptor {
size : wgpu ::Extent3d {
width : config . width ,
height : config . height ,
depth_or_array_layers : 1 ,
} ,
mip_level_count : 1 ,
sample_count : 1 ,
dimension : wgpu ::TextureDimension ::D2 ,
format : Self ::DEPTH_FORMAT ,
usage : wgpu ::TextureUsages ::RENDER_ATTACHMENT ,
label : None ,
view_formats : & [ ] ,
} ) ;
depth_texture . create_view ( & wgpu ::TextureViewDescriptor ::default ( ) )
}
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fn generate_model_graphics ( & mut self , device :& wgpu ::Device , queue :& wgpu ::Queue , indexed_models :model ::IndexedModelInstances ) {
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//generate texture view per texture
//idk how to do this gooder lol
let mut double_map = std ::collections ::HashMap ::< u32 , u32 > ::new ( ) ;
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let mut texture_loading_threads = Vec ::new ( ) ;
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let num_textures = indexed_models . textures . len ( ) ;
for ( i , texture_id ) in indexed_models . textures . into_iter ( ) . enumerate ( ) {
if let Ok ( mut file ) = std ::fs ::File ::open ( std ::path ::Path ::new ( & format! ( " textures/ {} .dds " , texture_id ) ) ) {
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double_map . insert ( i as u32 , texture_loading_threads . len ( ) as u32 ) ;
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texture_loading_threads . push ( ( texture_id , std ::thread ::spawn ( move | | {
ddsfile ::Dds ::read ( & mut file ) . unwrap ( )
} ) ) ) ;
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}
}
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let texture_views :Vec < wgpu ::TextureView > = texture_loading_threads . into_iter ( ) . map ( | ( texture_id , thread ) | {
let image = thread . join ( ) . unwrap ( ) ;
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let ( mut width , mut height ) = ( image . get_width ( ) , image . get_height ( ) ) ;
let format = match image . header10 . unwrap ( ) . dxgi_format {
ddsfile ::DxgiFormat ::R8G8B8A8_UNorm_sRGB = > wgpu ::TextureFormat ::Rgba8UnormSrgb ,
ddsfile ::DxgiFormat ::BC7_UNorm_sRGB = > {
//floor(w,4), should be ceil(w,4)
width = width / 4 * 4 ;
height = height / 4 * 4 ;
wgpu ::TextureFormat ::Bc7RgbaUnormSrgb
} ,
other = > panic! ( " unsupported format {:?} " , other ) ,
} ;
let size = wgpu ::Extent3d {
width ,
height ,
depth_or_array_layers : 1 ,
} ;
let layer_size = wgpu ::Extent3d {
depth_or_array_layers : 1 ,
.. size
} ;
let max_mips = layer_size . max_mips ( wgpu ::TextureDimension ::D2 ) ;
let texture = device . create_texture_with_data (
queue ,
& wgpu ::TextureDescriptor {
size ,
mip_level_count : max_mips ,
sample_count : 1 ,
dimension : wgpu ::TextureDimension ::D2 ,
format ,
usage : wgpu ::TextureUsages ::TEXTURE_BINDING | wgpu ::TextureUsages ::COPY_DST ,
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label : Some ( format! ( " Texture {} " , texture_id ) . as_str ( ) ) ,
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view_formats : & [ ] ,
} ,
& image . data ,
) ;
texture . create_view ( & wgpu ::TextureViewDescriptor {
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label : Some ( format! ( " Texture {} View " , texture_id ) . as_str ( ) ) ,
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dimension : Some ( wgpu ::TextureViewDimension ::D2 ) ,
.. wgpu ::TextureViewDescriptor ::default ( )
} )
} ) . collect ( ) ;
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//split groups with different textures into separate models
//the models received here are supposed to be tightly packed, i.e. no code needs to check if two models are using the same groups.
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let indexed_models_len = indexed_models . models . len ( ) ;
let mut unique_texture_models = Vec ::with_capacity ( indexed_models_len ) ;
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for model in indexed_models . models . into_iter ( ) {
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//convert ModelInstance into ModelGraphicsInstance
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let instances :Vec < ModelGraphicsInstance > = model . instances . into_iter ( ) . filter_map ( | instance | {
if instance . color . w = = 0.0 {
None
} else {
Some ( ModelGraphicsInstance {
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transform : instance . transform . into ( ) ,
normal_transform : Into ::< glam ::Mat3 > ::into ( instance . transform . matrix3 ) . inverse ( ) . transpose ( ) ,
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color :model_graphics ::ModelGraphicsColor4 ::from ( instance . color ) ,
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} )
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}
} ) . collect ( ) ;
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//check each group, if it's using a new texture then make a new clone of the model
let id = unique_texture_models . len ( ) ;
let mut unique_textures = Vec ::new ( ) ;
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for group in model . groups . into_iter ( ) {
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//ignore zero copy optimization for now
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let texture_index = if let Some ( texture_index ) = unique_textures . iter ( ) . position ( | & texture | texture = = group . texture ) {
texture_index
} else {
//create new texture_index
let texture_index = unique_textures . len ( ) ;
unique_textures . push ( group . texture ) ;
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unique_texture_models . push ( model_graphics ::IndexedModelGraphicsSingleTexture {
unique_pos :model . unique_pos . iter ( ) . map ( | & v | * Into ::< glam ::Vec3 > ::into ( v ) . as_ref ( ) ) . collect ( ) ,
unique_tex :model . unique_tex . iter ( ) . map ( | v | * v . as_ref ( ) ) . collect ( ) ,
unique_normal :model . unique_normal . iter ( ) . map ( | & v | * Into ::< glam ::Vec3 > ::into ( v ) . as_ref ( ) ) . collect ( ) ,
unique_color :model . unique_color . iter ( ) . map ( | v | * v . as_ref ( ) ) . collect ( ) ,
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unique_vertices :model . unique_vertices . clone ( ) ,
texture :group . texture ,
groups :Vec ::new ( ) ,
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instances :instances . clone ( ) ,
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} ) ;
texture_index
} ;
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unique_texture_models [ id + texture_index ] . groups . push ( model_graphics ::IndexedGroupFixedTexture {
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polys :group . polys ,
} ) ;
}
}
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//check every model to see if it's using the same (texture,color) but has few instances, if it is combine it into one model
//1. collect unique instances of texture and color, note model id
//2. for each model id, check if removing it from the pool decreases both the model count and instance count by more than one
//3. transpose all models that stay in the set
//best plan: benchmark set_bind_group, set_vertex_buffer, set_index_buffer and draw_indexed
//check if the estimated render performance is better by transposing multiple model instances into one model instance
//for now: just deduplicate single models...
let mut deduplicated_models = Vec ::with_capacity ( indexed_models_len ) ; //use indexed_models_len because the list will likely get smaller instead of bigger
let mut unique_texture_color = std ::collections ::HashMap ::new ( ) ; //texture->color->vec![(model_id,instance_id)]
for ( model_id , model ) in unique_texture_models . iter ( ) . enumerate ( ) {
//for now: filter out models with more than one instance
if 1 < model . instances . len ( ) {
continue ;
}
//populate hashmap
let unique_color = if let Some ( unique_color ) = unique_texture_color . get_mut ( & model . texture ) {
unique_color
} else {
//make new hashmap
let unique_color = std ::collections ::HashMap ::new ( ) ;
unique_texture_color . insert ( model . texture , unique_color ) ;
unique_texture_color . get_mut ( & model . texture ) . unwrap ( )
} ;
//separate instances by color
for ( instance_id , instance ) in model . instances . iter ( ) . enumerate ( ) {
let model_instance_list = if let Some ( model_instance_list ) = unique_color . get_mut ( & instance . color ) {
model_instance_list
} else {
//make new hashmap
let model_instance_list = Vec ::new ( ) ;
unique_color . insert ( instance . color . clone ( ) , model_instance_list ) ;
unique_color . get_mut ( & instance . color ) . unwrap ( )
} ;
//add model instance to list
model_instance_list . push ( ( model_id , instance_id ) ) ;
}
}
//populate a hashset of models selected for transposition
//construct transposed models
let mut selected_model_instances = std ::collections ::HashSet ::new ( ) ;
for ( texture , unique_color ) in unique_texture_color . into_iter ( ) {
for ( color , model_instance_list ) in unique_color . into_iter ( ) {
//world transforming one model does not meet the definition of deduplicaiton
if 1 < model_instance_list . len ( ) {
//create model
let mut unique_pos = Vec ::new ( ) ;
let mut pos_id_from = std ::collections ::HashMap ::new ( ) ;
let mut unique_tex = Vec ::new ( ) ;
let mut tex_id_from = std ::collections ::HashMap ::new ( ) ;
let mut unique_normal = Vec ::new ( ) ;
let mut normal_id_from = std ::collections ::HashMap ::new ( ) ;
let mut unique_color = Vec ::new ( ) ;
let mut color_id_from = std ::collections ::HashMap ::new ( ) ;
let mut unique_vertices = Vec ::new ( ) ;
let mut vertex_id_from = std ::collections ::HashMap ::new ( ) ;
let mut polys = Vec ::new ( ) ;
//transform instance vertices
for ( model_id , instance_id ) in model_instance_list . into_iter ( ) {
//populate hashset to prevent these models from being copied
selected_model_instances . insert ( model_id ) ;
//there is only one instance per model
let model = & unique_texture_models [ model_id ] ;
let instance = & model . instances [ instance_id ] ;
//just hash word slices LOL
let map_pos_id :Vec < u32 > = model . unique_pos . iter ( ) . map ( | untransformed_pos | {
let pos = instance . transform . transform_point3 ( glam ::Vec3 ::from_array ( untransformed_pos . clone ( ) ) ) . to_array ( ) ;
let h = pos . map ( | v | bytemuck ::cast ::< f32 , u32 > ( v ) ) ;
( if let Some ( & pos_id ) = pos_id_from . get ( & h ) {
pos_id
} else {
let pos_id = unique_pos . len ( ) ;
unique_pos . push ( pos . clone ( ) ) ;
pos_id_from . insert ( h , pos_id ) ;
pos_id
} ) as u32
} ) . collect ( ) ;
let map_tex_id :Vec < u32 > = model . unique_tex . iter ( ) . map ( | tex | {
let h = tex . map ( | v | bytemuck ::cast ::< f32 , u32 > ( v ) ) ;
( if let Some ( & tex_id ) = tex_id_from . get ( & h ) {
tex_id
} else {
let tex_id = unique_tex . len ( ) ;
unique_tex . push ( tex . clone ( ) ) ;
tex_id_from . insert ( h , tex_id ) ;
tex_id
} ) as u32
} ) . collect ( ) ;
let map_normal_id :Vec < u32 > = model . unique_normal . iter ( ) . map ( | untransformed_normal | {
let normal = ( instance . normal_transform * glam ::Vec3 ::from_array ( untransformed_normal . clone ( ) ) ) . to_array ( ) ;
let h = normal . map ( | v | bytemuck ::cast ::< f32 , u32 > ( v ) ) ;
( if let Some ( & normal_id ) = normal_id_from . get ( & h ) {
normal_id
} else {
let normal_id = unique_normal . len ( ) ;
unique_normal . push ( normal . clone ( ) ) ;
normal_id_from . insert ( h , normal_id ) ;
normal_id
} ) as u32
} ) . collect ( ) ;
let map_color_id :Vec < u32 > = model . unique_color . iter ( ) . map ( | color | {
let h = color . map ( | v | bytemuck ::cast ::< f32 , u32 > ( v ) ) ;
( if let Some ( & color_id ) = color_id_from . get ( & h ) {
color_id
} else {
let color_id = unique_color . len ( ) ;
unique_color . push ( color . clone ( ) ) ;
color_id_from . insert ( h , color_id ) ;
color_id
} ) as u32
} ) . collect ( ) ;
//map the indexed vertices onto new indices
//creating the vertex map is slightly different because the vertices are directly hashable
let map_vertex_id :Vec < u32 > = model . unique_vertices . iter ( ) . map ( | unmapped_vertex | {
let vertex = model ::IndexedVertex {
pos :map_pos_id [ unmapped_vertex . pos as usize ] as u32 ,
tex :map_tex_id [ unmapped_vertex . tex as usize ] as u32 ,
normal :map_normal_id [ unmapped_vertex . normal as usize ] as u32 ,
color :map_color_id [ unmapped_vertex . color as usize ] as u32 ,
} ;
( if let Some ( & vertex_id ) = vertex_id_from . get ( & vertex ) {
vertex_id
} else {
let vertex_id = unique_vertices . len ( ) ;
unique_vertices . push ( vertex . clone ( ) ) ;
vertex_id_from . insert ( vertex , vertex_id ) ;
vertex_id
} ) as u32
} ) . collect ( ) ;
for group in & model . groups {
for poly in & group . polys {
polys . push ( model ::IndexedPolygon { vertices :poly . vertices . iter ( ) . map ( | & vertex_id | map_vertex_id [ vertex_id as usize ] ) . collect ( ) } ) ;
}
}
}
//push model into dedup
deduplicated_models . push ( model_graphics ::IndexedModelGraphicsSingleTexture {
unique_pos ,
unique_tex ,
unique_normal ,
unique_color ,
unique_vertices ,
texture ,
groups :vec ! [ model_graphics ::IndexedGroupFixedTexture {
polys
} ] ,
instances :vec ! [ model_graphics ::ModelGraphicsInstance {
transform :glam ::Mat4 ::IDENTITY ,
normal_transform :glam ::Mat3 ::IDENTITY ,
color
} ] ,
} ) ;
}
}
}
//fill untouched models
for ( model_id , model ) in unique_texture_models . into_iter ( ) . enumerate ( ) {
if ! selected_model_instances . contains ( & model_id ) {
deduplicated_models . push ( model ) ;
}
}
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//de-index models
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let deduplicated_models_len = deduplicated_models . len ( ) ;
let mut models = Vec ::with_capacity ( deduplicated_models_len ) ;
for model in deduplicated_models . into_iter ( ) {
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let mut vertices = Vec ::new ( ) ;
let mut index_from_vertex = std ::collections ::HashMap ::new ( ) ; //::<IndexedVertex,usize>
let mut entities = Vec ::new ( ) ;
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//this mut be combined in a more complex way if the models use different render patterns per group
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let mut indices = Vec ::new ( ) ;
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for group in model . groups {
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for poly in group . polys {
for end_index in 2 .. poly . vertices . len ( ) {
for & index in & [ 0 , end_index - 1 , end_index ] {
let vertex_index = poly . vertices [ index ] ;
if let Some ( & i ) = index_from_vertex . get ( & vertex_index ) {
indices . push ( i ) ;
} else {
let i = vertices . len ( ) as u16 ;
let vertex = & model . unique_vertices [ vertex_index as usize ] ;
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vertices . push ( model_graphics ::GraphicsVertex {
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pos : model . unique_pos [ vertex . pos as usize ] ,
tex : model . unique_tex [ vertex . tex as usize ] ,
normal : model . unique_normal [ vertex . normal as usize ] ,
color :model . unique_color [ vertex . color as usize ] ,
} ) ;
index_from_vertex . insert ( vertex_index , i ) ;
indices . push ( i ) ;
}
}
}
}
}
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entities . push ( indices ) ;
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models . push ( model_graphics ::ModelGraphicsSingleTexture {
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instances :model . instances ,
vertices ,
entities ,
texture :model . texture ,
} ) ;
}
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//.into_iter() the modeldata vec so entities can be /moved/ to models.entities
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let mut model_count = 0 ;
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let mut instance_count = 0 ;
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let uniform_buffer_binding_size = < GlobalState as framework ::Example > ::required_limits ( ) . max_uniform_buffer_binding_size as usize ;
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let chunk_size = uniform_buffer_binding_size / MODEL_BUFFER_SIZE_BYTES ;
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self . graphics . models . reserve ( models . len ( ) ) ;
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for model in models . into_iter ( ) {
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instance_count + = model . instances . len ( ) ;
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for instances_chunk in model . instances . rchunks ( chunk_size ) {
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model_count + = 1 ;
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let model_uniforms = get_instances_buffer_data ( instances_chunk ) ;
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let model_buf = device . create_buffer_init ( & wgpu ::util ::BufferInitDescriptor {
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label : Some ( format! ( " Model {} Buf " , model_count ) . as_str ( ) ) ,
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contents : bytemuck ::cast_slice ( & model_uniforms ) ,
usage : wgpu ::BufferUsages ::UNIFORM | wgpu ::BufferUsages ::COPY_DST ,
} ) ;
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let texture_view = match model . texture {
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Some ( texture_id ) = > {
match double_map . get ( & texture_id ) {
Some ( & mapped_texture_id ) = > & texture_views [ mapped_texture_id as usize ] ,
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None = > & self . graphics . temp_squid_texture_view ,
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}
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} ,
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None = > & self . graphics . temp_squid_texture_view ,
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} ;
let model_bind_group = device . create_bind_group ( & wgpu ::BindGroupDescriptor {
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layout : & self . graphics . bind_group_layouts . model ,
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entries : & [
wgpu ::BindGroupEntry {
binding : 0 ,
resource : model_buf . as_entire_binding ( ) ,
} ,
wgpu ::BindGroupEntry {
binding : 1 ,
resource : wgpu ::BindingResource ::TextureView ( texture_view ) ,
} ,
wgpu ::BindGroupEntry {
binding : 2 ,
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resource : wgpu ::BindingResource ::Sampler ( & self . graphics . samplers . repeat ) ,
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} ,
] ,
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label : Some ( format! ( " Model {} Bind Group " , model_count ) . as_str ( ) ) ,
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} ) ;
let vertex_buf = device . create_buffer_init ( & wgpu ::util ::BufferInitDescriptor {
label : Some ( " Vertex " ) ,
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contents : bytemuck ::cast_slice ( & model . vertices ) ,
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usage : wgpu ::BufferUsages ::VERTEX ,
} ) ;
//all of these are being moved here
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self . graphics . models . push ( ModelGraphics {
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instances :instances_chunk . to_vec ( ) ,
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vertex_buf ,
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entities : model . entities . iter ( ) . map ( | indices | {
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let index_buf = device . create_buffer_init ( & wgpu ::util ::BufferInitDescriptor {
label : Some ( " Index " ) ,
contents : bytemuck ::cast_slice ( & indices ) ,
usage : wgpu ::BufferUsages ::INDEX ,
} ) ;
Entity {
index_buf ,
index_count : indices . len ( ) as u32 ,
}
} ) . collect ( ) ,
bind_group : model_bind_group ,
model_buf ,
} ) ;
}
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}
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println! ( " Texture References= {} " , num_textures ) ;
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println! ( " Textures Loaded= {} " , texture_views . len ( ) ) ;
println! ( " Indexed Models= {} " , indexed_models_len ) ;
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println! ( " Deduplicated Models= {} " , deduplicated_models_len ) ;
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println! ( " Graphics Objects: {} " , self . graphics . models . len ( ) ) ;
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println! ( " Graphics Instances: {} " , instance_count ) ;
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}
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}
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const MODEL_BUFFER_SIZE :usize = 4 * 4 + 12 + 4 ; //let size=std::mem::size_of::<ModelInstance>();
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const MODEL_BUFFER_SIZE_BYTES :usize = MODEL_BUFFER_SIZE * 4 ;
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fn get_instances_buffer_data ( instances :& [ ModelGraphicsInstance ] ) -> Vec < f32 > {
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let mut raw = Vec ::with_capacity ( MODEL_BUFFER_SIZE * instances . len ( ) ) ;
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for ( i , mi ) in instances . iter ( ) . enumerate ( ) {
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let mut v = raw . split_off ( MODEL_BUFFER_SIZE * i ) ;
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//model transform
raw . extend_from_slice ( & AsRef ::< [ f32 ; 4 * 4 ] > ::as_ref ( & mi . transform ) [ .. ] ) ;
//normal transform
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raw . extend_from_slice ( AsRef ::< [ f32 ; 3 ] > ::as_ref ( & mi . normal_transform . x_axis ) ) ;
raw . extend_from_slice ( & [ 0.0 ] ) ;
raw . extend_from_slice ( AsRef ::< [ f32 ; 3 ] > ::as_ref ( & mi . normal_transform . y_axis ) ) ;
raw . extend_from_slice ( & [ 0.0 ] ) ;
raw . extend_from_slice ( AsRef ::< [ f32 ; 3 ] > ::as_ref ( & mi . normal_transform . z_axis ) ) ;
raw . extend_from_slice ( & [ 0.0 ] ) ;
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//color
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raw . extend_from_slice ( AsRef ::< [ f32 ; 4 ] > ::as_ref ( & mi . color . get ( ) ) ) ;
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raw . append ( & mut v ) ;
}
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raw
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}
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impl framework ::Example for GlobalState {
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fn optional_features ( ) -> wgpu ::Features {
wgpu ::Features ::TEXTURE_COMPRESSION_ASTC
| wgpu ::Features ::TEXTURE_COMPRESSION_ETC2
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}
fn required_features ( ) -> wgpu ::Features {
wgpu ::Features ::TEXTURE_COMPRESSION_BC
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}
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fn required_limits ( ) -> wgpu ::Limits {
wgpu ::Limits ::default ( ) //framework.rs was using goofy limits that caused me a multi-day headache
}
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fn init (
config : & wgpu ::SurfaceConfiguration ,
_adapter : & wgpu ::Adapter ,
device : & wgpu ::Device ,
queue : & wgpu ::Queue ,
) -> Self {
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//wee
let user_settings = settings ::read_user_settings ( ) ;
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let mut indexed_models = Vec ::new ( ) ;
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indexed_models . append ( & mut model ::generate_indexed_model_list_from_obj ( obj ::ObjData ::load_buf ( & include_bytes! ( " ../models/teslacyberv3.0.obj " ) [ .. ] ) . unwrap ( ) , glam ::Vec4 ::ONE ) ) ;
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indexed_models . push ( primitives ::unit_sphere ( ) ) ;
indexed_models . push ( primitives ::unit_cylinder ( ) ) ;
indexed_models . push ( primitives ::unit_cube ( ) ) ;
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println! ( " models.len = {:?} " , indexed_models . len ( ) ) ;
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indexed_models [ 0 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 10. , 0. , - 10. ) ) ) . unwrap ( ) ,
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.. Default ::default ( )
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} ) ;
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//quad monkeys
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indexed_models [ 1 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 10. , 5. , 10. ) ) ) . unwrap ( ) ,
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.. Default ::default ( )
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} ) ;
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indexed_models [ 1 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 20. , 5. , 10. ) ) ) . unwrap ( ) ,
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color :glam ::vec4 ( 1.0 , 0.0 , 0.0 , 1.0 ) ,
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.. Default ::default ( )
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} ) ;
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indexed_models [ 1 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 10. , 5. , 20. ) ) ) . unwrap ( ) ,
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color :glam ::vec4 ( 0.0 , 1.0 , 0.0 , 1.0 ) ,
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.. Default ::default ( )
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} ) ;
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indexed_models [ 1 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 20. , 5. , 20. ) ) ) . unwrap ( ) ,
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color :glam ::vec4 ( 0.0 , 0.0 , 1.0 , 1.0 ) ,
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.. Default ::default ( )
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} ) ;
//decorative monkey
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indexed_models [ 1 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 15. , 10. , 15. ) ) ) . unwrap ( ) ,
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color :glam ::vec4 ( 0.5 , 0.5 , 0.5 , 0.5 ) ,
attributes :model ::CollisionAttributes ::Decoration ,
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.. Default ::default ( )
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} ) ;
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//teapot
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indexed_models [ 2 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_scale_rotation_translation ( glam ::vec3 ( 0.5 , 1.0 , 0.2 ) , glam ::quat ( - 0.22248298016985793 , - 0.839457167990537 , - 0.05603504040830783 , - 0.49261857546227916 ) , glam ::vec3 ( - 10. , 7. , 10. ) ) ) . unwrap ( ) ,
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.. Default ::default ( )
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} ) ;
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//ground
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indexed_models [ 3 ] . instances . push ( model ::ModelInstance {
transform :integer ::Planar64Affine3 ::try_from ( glam ::Affine3A ::from_translation ( glam ::vec3 ( 0. , 0. , 0. ) ) * glam ::Affine3A ::from_scale ( glam ::vec3 ( 160.0 , 1.0 , 160.0 ) ) ) . unwrap ( ) ,
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.. Default ::default ( )
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} ) ;
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let camera_bind_group_layout = device . create_bind_group_layout ( & wgpu ::BindGroupLayoutDescriptor {
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label : None ,
entries : & [
wgpu ::BindGroupLayoutEntry {
binding : 0 ,
visibility : wgpu ::ShaderStages ::VERTEX ,
ty : wgpu ::BindingType ::Buffer {
ty : wgpu ::BufferBindingType ::Uniform ,
has_dynamic_offset : false ,
min_binding_size : None ,
} ,
count : None ,
} ,
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] ,
} ) ;
let skybox_texture_bind_group_layout = device . create_bind_group_layout ( & wgpu ::BindGroupLayoutDescriptor {
label : Some ( " Skybox Texture Bind Group Layout " ) ,
entries : & [
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wgpu ::BindGroupLayoutEntry {
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binding : 0 ,
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visibility : wgpu ::ShaderStages ::FRAGMENT ,
ty : wgpu ::BindingType ::Texture {
sample_type : wgpu ::TextureSampleType ::Float { filterable : true } ,
multisampled : false ,
view_dimension : wgpu ::TextureViewDimension ::Cube ,
} ,
count : None ,
} ,
wgpu ::BindGroupLayoutEntry {
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binding : 1 ,
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visibility : wgpu ::ShaderStages ::FRAGMENT ,
ty : wgpu ::BindingType ::Sampler ( wgpu ::SamplerBindingType ::Filtering ) ,
count : None ,
} ,
] ,
} ) ;
let model_bind_group_layout = device . create_bind_group_layout ( & wgpu ::BindGroupLayoutDescriptor {
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label : Some ( " Model Bind Group Layout " ) ,
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entries : & [
wgpu ::BindGroupLayoutEntry {
binding : 0 ,
visibility : wgpu ::ShaderStages ::VERTEX ,
ty : wgpu ::BindingType ::Buffer {
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ty : wgpu ::BufferBindingType ::Uniform ,
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has_dynamic_offset : false ,
min_binding_size : None ,
} ,
count : None ,
} ,
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wgpu ::BindGroupLayoutEntry {
binding : 1 ,
visibility : wgpu ::ShaderStages ::FRAGMENT ,
ty : wgpu ::BindingType ::Texture {
sample_type : wgpu ::TextureSampleType ::Float { filterable : true } ,
multisampled : false ,
view_dimension : wgpu ::TextureViewDimension ::D2 ,
} ,
count : None ,
} ,
wgpu ::BindGroupLayoutEntry {
binding : 2 ,
visibility : wgpu ::ShaderStages ::FRAGMENT ,
ty : wgpu ::BindingType ::Sampler ( wgpu ::SamplerBindingType ::Filtering ) ,
count : None ,
} ,
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] ,
} ) ;
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let clamp_sampler = device . create_sampler ( & wgpu ::SamplerDescriptor {
label : Some ( " Clamp Sampler " ) ,
address_mode_u : wgpu ::AddressMode ::ClampToEdge ,
address_mode_v : wgpu ::AddressMode ::ClampToEdge ,
address_mode_w : wgpu ::AddressMode ::ClampToEdge ,
mag_filter : wgpu ::FilterMode ::Linear ,
min_filter : wgpu ::FilterMode ::Linear ,
mipmap_filter : wgpu ::FilterMode ::Linear ,
.. Default ::default ( )
} ) ;
let repeat_sampler = device . create_sampler ( & wgpu ::SamplerDescriptor {
label : Some ( " Repeat Sampler " ) ,
address_mode_u : wgpu ::AddressMode ::Repeat ,
address_mode_v : wgpu ::AddressMode ::Repeat ,
address_mode_w : wgpu ::AddressMode ::Repeat ,
mag_filter : wgpu ::FilterMode ::Linear ,
min_filter : wgpu ::FilterMode ::Linear ,
mipmap_filter : wgpu ::FilterMode ::Linear ,
.. Default ::default ( )
} ) ;
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// Create the render pipeline
let shader = device . create_shader_module ( wgpu ::ShaderModuleDescriptor {
label : None ,
source : wgpu ::ShaderSource ::Wgsl ( Cow ::Borrowed ( include_str! ( " shader.wgsl " ) ) ) ,
} ) ;
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//load textures
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let device_features = device . features ( ) ;
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let skybox_texture_view = {
let skybox_format = if device_features . contains ( wgpu ::Features ::TEXTURE_COMPRESSION_ASTC ) {
log ::info! ( " Using ASTC " ) ;
wgpu ::TextureFormat ::Astc {
block : AstcBlock ::B4x4 ,
channel : AstcChannel ::UnormSrgb ,
}
} else if device_features . contains ( wgpu ::Features ::TEXTURE_COMPRESSION_ETC2 ) {
log ::info! ( " Using ETC2 " ) ;
wgpu ::TextureFormat ::Etc2Rgb8UnormSrgb
} else if device_features . contains ( wgpu ::Features ::TEXTURE_COMPRESSION_BC ) {
log ::info! ( " Using BC " ) ;
wgpu ::TextureFormat ::Bc1RgbaUnormSrgb
} else {
log ::info! ( " Using plain " ) ;
wgpu ::TextureFormat ::Bgra8UnormSrgb
} ;
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let bytes = match skybox_format {
wgpu ::TextureFormat ::Astc {
block : AstcBlock ::B4x4 ,
channel : AstcChannel ::UnormSrgb ,
} = > & include_bytes! ( " ../images/astc.dds " ) [ .. ] ,
wgpu ::TextureFormat ::Etc2Rgb8UnormSrgb = > & include_bytes! ( " ../images/etc2.dds " ) [ .. ] ,
wgpu ::TextureFormat ::Bc1RgbaUnormSrgb = > & include_bytes! ( " ../images/bc1.dds " ) [ .. ] ,
wgpu ::TextureFormat ::Bgra8UnormSrgb = > & include_bytes! ( " ../images/bgra.dds " ) [ .. ] ,
_ = > unreachable! ( ) ,
} ;
let skybox_image = ddsfile ::Dds ::read ( & mut std ::io ::Cursor ::new ( bytes ) ) . unwrap ( ) ;
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let size = wgpu ::Extent3d {
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width : skybox_image . get_width ( ) ,
height : skybox_image . get_height ( ) ,
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depth_or_array_layers : 6 ,
} ;
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let layer_size = wgpu ::Extent3d {
depth_or_array_layers : 1 ,
.. size
} ;
let max_mips = layer_size . max_mips ( wgpu ::TextureDimension ::D2 ) ;
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log ::debug! (
" Copying {:?} skybox images of size {}, {}, 6 with {} mips to gpu " ,
skybox_format ,
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size . width ,
size . height ,
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max_mips ,
) ;
let skybox_texture = device . create_texture_with_data (
queue ,
& wgpu ::TextureDescriptor {
size ,
mip_level_count : max_mips ,
sample_count : 1 ,
dimension : wgpu ::TextureDimension ::D2 ,
format : skybox_format ,
usage : wgpu ::TextureUsages ::TEXTURE_BINDING | wgpu ::TextureUsages ::COPY_DST ,
label : Some ( " Skybox Texture " ) ,
view_formats : & [ ] ,
} ,
& skybox_image . data ,
) ;
skybox_texture . create_view ( & wgpu ::TextureViewDescriptor {
label : Some ( " Skybox Texture View " ) ,
dimension : Some ( wgpu ::TextureViewDimension ::Cube ) ,
.. wgpu ::TextureViewDescriptor ::default ( )
} )
} ;
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//squid
let squid_texture_view = {
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let bytes = include_bytes! ( " ../images/squid.dds " ) ;
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let image = ddsfile ::Dds ::read ( & mut std ::io ::Cursor ::new ( bytes ) ) . unwrap ( ) ;
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let size = wgpu ::Extent3d {
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width : image . get_width ( ) ,
height : image . get_height ( ) ,
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depth_or_array_layers : 1 ,
} ;
let layer_size = wgpu ::Extent3d {
depth_or_array_layers : 1 ,
.. size
} ;
let max_mips = layer_size . max_mips ( wgpu ::TextureDimension ::D2 ) ;
let texture = device . create_texture_with_data (
queue ,
& wgpu ::TextureDescriptor {
size ,
mip_level_count : max_mips ,
sample_count : 1 ,
dimension : wgpu ::TextureDimension ::D2 ,
format : wgpu ::TextureFormat ::Bc7RgbaUnorm ,
usage : wgpu ::TextureUsages ::TEXTURE_BINDING | wgpu ::TextureUsages ::COPY_DST ,
label : Some ( " Squid Texture " ) ,
view_formats : & [ ] ,
} ,
& image . data ,
) ;
texture . create_view ( & wgpu ::TextureViewDescriptor {
label : Some ( " Squid Texture View " ) ,
dimension : Some ( wgpu ::TextureViewDimension ::D2 ) ,
.. wgpu ::TextureViewDescriptor ::default ( )
} )
} ;
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let model_pipeline_layout = device . create_pipeline_layout ( & wgpu ::PipelineLayoutDescriptor {
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label : None ,
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bind_group_layouts : & [
& camera_bind_group_layout ,
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& skybox_texture_bind_group_layout ,
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& model_bind_group_layout ,
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] ,
push_constant_ranges : & [ ] ,
} ) ;
let sky_pipeline_layout = device . create_pipeline_layout ( & wgpu ::PipelineLayoutDescriptor {
label : None ,
bind_group_layouts : & [
& camera_bind_group_layout ,
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& skybox_texture_bind_group_layout ,
] ,
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push_constant_ranges : & [ ] ,
} ) ;
// Create the render pipelines
let sky_pipeline = device . create_render_pipeline ( & wgpu ::RenderPipelineDescriptor {
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label : Some ( " Sky Pipeline " ) ,
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layout : Some ( & sky_pipeline_layout ) ,
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vertex : wgpu ::VertexState {
module : & shader ,
entry_point : " vs_sky " ,
buffers : & [ ] ,
} ,
fragment : Some ( wgpu ::FragmentState {
module : & shader ,
entry_point : " fs_sky " ,
targets : & [ Some ( config . view_formats [ 0 ] . into ( ) ) ] ,
} ) ,
primitive : wgpu ::PrimitiveState {
front_face : wgpu ::FrontFace ::Cw ,
.. Default ::default ( )
} ,
depth_stencil : Some ( wgpu ::DepthStencilState {
format : Self ::DEPTH_FORMAT ,
depth_write_enabled : false ,
depth_compare : wgpu ::CompareFunction ::LessEqual ,
stencil : wgpu ::StencilState ::default ( ) ,
bias : wgpu ::DepthBiasState ::default ( ) ,
} ) ,
multisample : wgpu ::MultisampleState ::default ( ) ,
multiview : None ,
} ) ;
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let model_pipeline = device . create_render_pipeline ( & wgpu ::RenderPipelineDescriptor {
label : Some ( " Model Pipeline " ) ,
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layout : Some ( & model_pipeline_layout ) ,
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vertex : wgpu ::VertexState {
module : & shader ,
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entry_point : " vs_entity_texture " ,
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buffers : & [ wgpu ::VertexBufferLayout {
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array_stride : std ::mem ::size_of ::< GraphicsVertex > ( ) as wgpu ::BufferAddress ,
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step_mode : wgpu ::VertexStepMode ::Vertex ,
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attributes : & wgpu ::vertex_attr_array! [ 0 = > Float32x3 , 1 = > Float32x2 , 2 = > Float32x3 , 3 = > Float32x4 ] ,
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} ] ,
} ,
fragment : Some ( wgpu ::FragmentState {
module : & shader ,
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entry_point : " fs_entity_texture " ,
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targets : & [ Some ( config . view_formats [ 0 ] . into ( ) ) ] ,
} ) ,
primitive : wgpu ::PrimitiveState {
front_face : wgpu ::FrontFace ::Cw ,
.. Default ::default ( )
} ,
depth_stencil : Some ( wgpu ::DepthStencilState {
format : Self ::DEPTH_FORMAT ,
depth_write_enabled : true ,
depth_compare : wgpu ::CompareFunction ::LessEqual ,
stencil : wgpu ::StencilState ::default ( ) ,
bias : wgpu ::DepthBiasState ::default ( ) ,
} ) ,
multisample : wgpu ::MultisampleState ::default ( ) ,
multiview : None ,
} ) ;
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let mut physics = physics ::PhysicsState ::default ( ) ;
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physics . load_user_settings ( & user_settings ) ;
let screen_size = glam ::uvec2 ( config . width , config . height ) ;
let camera = GraphicsCamera ::new ( screen_size , user_settings . calculate_fov ( 1.0 , & screen_size ) . as_vec2 ( ) ) ;
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let camera_uniforms = camera . to_uniform_data ( physics . output ( ) . adjust_mouse ( & physics . next_mouse ) ) ;
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let camera_buf = device . create_buffer_init ( & wgpu ::util ::BufferInitDescriptor {
label : Some ( " Camera " ) ,
contents : bytemuck ::cast_slice ( & camera_uniforms ) ,
usage : wgpu ::BufferUsages ::UNIFORM | wgpu ::BufferUsages ::COPY_DST ,
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} ) ;
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let camera_bind_group = device . create_bind_group ( & wgpu ::BindGroupDescriptor {
layout : & camera_bind_group_layout ,
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entries : & [
wgpu ::BindGroupEntry {
binding : 0 ,
resource : camera_buf . as_entire_binding ( ) ,
} ,
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] ,
label : Some ( " Camera " ) ,
} ) ;
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let skybox_texture_bind_group = device . create_bind_group ( & wgpu ::BindGroupDescriptor {
layout : & skybox_texture_bind_group_layout ,
entries : & [
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wgpu ::BindGroupEntry {
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binding : 0 ,
resource : wgpu ::BindingResource ::TextureView ( & skybox_texture_view ) ,
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} ,
wgpu ::BindGroupEntry {
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binding : 1 ,
resource : wgpu ::BindingResource ::Sampler ( & clamp_sampler ) ,
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} ,
] ,
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label : Some ( " Sky Texture " ) ,
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} ) ;
let depth_view = Self ::create_depth_texture ( config , device ) ;
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let mut graphics = GraphicsState {
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pipelines :GraphicsPipelines {
skybox :sky_pipeline ,
model :model_pipeline
} ,
bind_groups :GraphicsBindGroups {
camera :camera_bind_group ,
skybox_texture :skybox_texture_bind_group ,
} ,
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camera ,
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camera_buf ,
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models : Vec ::new ( ) ,
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depth_view ,
staging_belt : wgpu ::util ::StagingBelt ::new ( 0x100 ) ,
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bind_group_layouts : GraphicsBindGroupLayouts { model : model_bind_group_layout } ,
samplers : GraphicsSamplers { repeat : repeat_sampler } ,
temp_squid_texture_view : squid_texture_view ,
} ;
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graphics . load_user_settings ( & user_settings ) ;
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let indexed_model_instances = model ::IndexedModelInstances {
textures :Vec ::new ( ) ,
models :indexed_models ,
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spawn_point :integer ::Planar64Vec3 ::Y * 50 ,
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modes :Vec ::new ( ) ,
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} ;
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//how to multithread
//1. build
physics . generate_models ( & indexed_model_instances ) ;
//2. move
let physics_thread = physics . into_worker ( ) ;
//3. forget
let mut state = GlobalState {
start_time :Instant ::now ( ) ,
manual_mouse_lock :false ,
mouse :physics ::MouseState ::default ( ) ,
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user_settings ,
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graphics ,
physics_thread ,
} ;
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state . generate_model_graphics ( & device , & queue , indexed_model_instances ) ;
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let args :Vec < String > = std ::env ::args ( ) . collect ( ) ;
if args . len ( ) = = 2 {
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state . load_file ( std ::path ::PathBuf ::from ( & args [ 1 ] ) , device , queue ) ;
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}
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return state ;
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}
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fn load_file ( & mut self , path : std ::path ::PathBuf , device : & wgpu ::Device , queue : & wgpu ::Queue ) {
println! ( " Loading file: {:?} " , & path ) ;
//oh boy! let's load the map!
if let Ok ( file ) = std ::fs ::File ::open ( path ) {
let mut input = std ::io ::BufReader ::new ( file ) ;
let mut first_8 = [ 0 u8 ; 8 ] ;
//.rbxm roblox binary = "<roblox!"
//.rbxmx roblox xml = "<roblox "
//.bsp = "VBSP"
//.vmf =
//.snf = "SNMF"
//.snf = "SNBF"
if let ( Ok ( ( ) ) , Ok ( ( ) ) ) = ( std ::io ::Read ::read_exact ( & mut input , & mut first_8 ) , std ::io ::Seek ::rewind ( & mut input ) ) {
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if let Some ( indexed_model_instances ) = {
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match & first_8 [ 0 .. 4 ] {
b " <rob " = > {
match match & first_8 [ 4 .. 8 ] {
b " lox! " = > rbx_binary ::from_reader ( input ) . map_err ( | e | format! ( " {:?} " , e ) ) ,
b " lox " = > rbx_xml ::from_reader ( input , rbx_xml ::DecodeOptions ::default ( ) ) . map_err ( | e | format! ( " {:?} " , e ) ) ,
other = > Err ( format! ( " Unknown Roblox file type {:?} " , other ) ) ,
} {
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Ok ( dom ) = > Some ( load_roblox ::generate_indexed_models ( dom ) ) ,
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Err ( e ) = > {
println! ( " Error loading roblox file: {:?} " , e ) ;
None
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} ,
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}
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} ,
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//b"VBSP"=>Some(load_bsp::generate_indexed_models(input)),
//b"SNFM"=>Some(sniffer::generate_indexed_models(input)),
//b"SNFB"=>Some(sniffer::load_bot(input)),
other = > {
println! ( " loser file {:?} " , other ) ;
None
} ,
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}
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} {
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let spawn_point = indexed_model_instances . spawn_point ;
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//if generate_indexed_models succeeds, clear the previous ones
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self . graphics . clear ( ) ;
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let mut physics = physics ::PhysicsState ::default ( ) ;
physics . game . stage_id = 0 ;
physics . spawn_point = spawn_point ;
physics . process_instruction ( instruction ::TimedInstruction {
time :physics . time ,
instruction : PhysicsInstruction ::Input ( physics ::PhysicsInputInstruction ::Reset ) ,
} ) ;
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physics . load_user_settings ( & self . user_settings ) ;
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physics . generate_models ( & indexed_model_instances ) ;
self . physics_thread = physics . into_worker ( ) ;
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//graphics.load_user_settings(&self.user_settings);
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self . generate_model_graphics ( device , queue , indexed_model_instances ) ;
//manual reset
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} else {
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println! ( " No modeldatas were generated " ) ;
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}
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} else {
println! ( " Failed to read first 8 bytes and seek back to beginning of file. " ) ;
}
} else {
println! ( " Could not open file " ) ;
}
}
#[ allow(clippy::single_match) ]
fn update ( & mut self , window : & winit ::window ::Window , device : & wgpu ::Device , queue : & wgpu ::Queue , event : winit ::event ::WindowEvent ) {
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let time = integer ::Time ::from_nanos ( self . start_time . elapsed ( ) . as_nanos ( ) as i64 ) ;
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match event {
winit ::event ::WindowEvent ::DroppedFile ( path ) = > self . load_file ( path , device , queue ) ,
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winit ::event ::WindowEvent ::Focused ( state ) = > {
//pause unpause
//recalculate pressed keys on focus
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} ,
winit ::event ::WindowEvent ::KeyboardInput {
input :winit ::event ::KeyboardInput { state , virtual_keycode , .. } ,
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..
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} = > {
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let s = match state {
winit ::event ::ElementState ::Pressed = > true ,
winit ::event ::ElementState ::Released = > false ,
} ;
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match virtual_keycode {
Some ( winit ::event ::VirtualKeyCode ::Tab ) = > {
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if s {
self . manual_mouse_lock = false ;
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match window . set_cursor_position ( winit ::dpi ::PhysicalPosition ::new ( self . graphics . camera . screen_size . x as f32 / 2.0 , self . graphics . camera . screen_size . y as f32 / 2.0 ) ) {
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Ok ( ( ) ) = > ( ) ,
Err ( e ) = > println! ( " Could not set cursor position: {:?} " , e ) ,
}
match window . set_cursor_grab ( winit ::window ::CursorGrabMode ::None ) {
Ok ( ( ) ) = > ( ) ,
Err ( e ) = > println! ( " Could not release cursor: {:?} " , e ) ,
}
} else {
//if cursor is outside window don't lock but apparently there's no get pos function
//let pos=window.get_cursor_pos();
match window . set_cursor_grab ( winit ::window ::CursorGrabMode ::Locked ) {
Ok ( ( ) ) = > ( ) ,
Err ( _ ) = > {
match window . set_cursor_grab ( winit ::window ::CursorGrabMode ::Confined ) {
Ok ( ( ) ) = > ( ) ,
Err ( e ) = > {
self . manual_mouse_lock = true ;
println! ( " Could not confine cursor: {:?} " , e )
} ,
}
}
}
}
window . set_cursor_visible ( s ) ;
} ,
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Some ( winit ::event ::VirtualKeyCode ::F11 ) = > {
if s {
if window . fullscreen ( ) . is_some ( ) {
window . set_fullscreen ( None ) ;
} else {
window . set_fullscreen ( Some ( winit ::window ::Fullscreen ::Borderless ( None ) ) ) ;
}
}
} ,
Some ( winit ::event ::VirtualKeyCode ::Escape ) = > {
if s {
self . manual_mouse_lock = false ;
match window . set_cursor_grab ( winit ::window ::CursorGrabMode ::None ) {
Ok ( ( ) ) = > ( ) ,
Err ( e ) = > println! ( " Could not release cursor: {:?} " , e ) ,
}
window . set_cursor_visible ( true ) ;
}
} ,
Some ( keycode ) = > {
if let Some ( input_instruction ) = match keycode {
winit ::event ::VirtualKeyCode ::W = > Some ( InputInstruction ::MoveForward ( s ) ) ,
winit ::event ::VirtualKeyCode ::A = > Some ( InputInstruction ::MoveLeft ( s ) ) ,
winit ::event ::VirtualKeyCode ::S = > Some ( InputInstruction ::MoveBack ( s ) ) ,
winit ::event ::VirtualKeyCode ::D = > Some ( InputInstruction ::MoveRight ( s ) ) ,
winit ::event ::VirtualKeyCode ::E = > Some ( InputInstruction ::MoveUp ( s ) ) ,
winit ::event ::VirtualKeyCode ::Q = > Some ( InputInstruction ::MoveDown ( s ) ) ,
winit ::event ::VirtualKeyCode ::Space = > Some ( InputInstruction ::Jump ( s ) ) ,
winit ::event ::VirtualKeyCode ::Z = > Some ( InputInstruction ::Zoom ( s ) ) ,
winit ::event ::VirtualKeyCode ::R = > if s { Some ( InputInstruction ::Reset ) } else { None } ,
_ = > None ,
} {
self . physics_thread . send ( TimedInstruction {
time ,
instruction :input_instruction ,
} ) . unwrap ( ) ;
}
} ,
_ = > ( ) ,
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}
} ,
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_ = > ( ) ,
}
}
fn device_event ( & mut self , window : & winit ::window ::Window , event : winit ::event ::DeviceEvent ) {
//there's no way this is the best way get a timestamp.
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let time = integer ::Time ::from_nanos ( self . start_time . elapsed ( ) . as_nanos ( ) as i64 ) ;
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match event {
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winit ::event ::DeviceEvent ::MouseMotion {
delta , //these (f64,f64) are integers on my machine
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} = > {
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if self . manual_mouse_lock {
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match window . set_cursor_position ( winit ::dpi ::PhysicalPosition ::new ( self . graphics . camera . screen_size . x as f32 / 2.0 , self . graphics . camera . screen_size . y as f32 / 2.0 ) ) {
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Ok ( ( ) ) = > ( ) ,
Err ( e ) = > println! ( " Could not set cursor position: {:?} " , e ) ,
}
}
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//do not step the physics because the mouse polling rate is higher than the physics can run.
//essentially the previous input will be overwritten until a true step runs
//which is fine because they run all the time.
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let delta = glam ::ivec2 ( delta . 0 as i32 , delta . 1 as i32 ) ;
self . mouse . pos + = delta ;
self . physics_thread . send ( TimedInstruction {
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time ,
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instruction :InputInstruction ::MoveMouse ( self . mouse . pos ) ,
} ) . unwrap ( ) ;
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} ,
winit ::event ::DeviceEvent ::MouseWheel {
delta ,
} = > {
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println! ( " mousewheel {:?} " , delta ) ;
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if false { //self.physics.style.use_scroll{
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self . physics_thread . send ( TimedInstruction {
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time ,
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instruction :InputInstruction ::Jump ( true ) , //activates the immediate jump path, but the style modifier prevents controls&CONTROL_JUMP bit from being set to auto jump
} ) . unwrap ( ) ;
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}
}
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_ = > ( ) ,
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}
}
fn resize (
& mut self ,
config : & wgpu ::SurfaceConfiguration ,
device : & wgpu ::Device ,
_queue : & wgpu ::Queue ,
) {
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self . graphics . depth_view = Self ::create_depth_texture ( config , device ) ;
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self . graphics . camera . screen_size = glam ::uvec2 ( config . width , config . height ) ;
self . graphics . load_user_settings ( & self . user_settings ) ;
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}
fn render (
& mut self ,
view : & wgpu ::TextureView ,
device : & wgpu ::Device ,
queue : & wgpu ::Queue ,
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_spawner : & framework ::Spawner ,
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) {
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//ideally this would be scheduled to execute and finish right before the render.
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let time = integer ::Time ::from_nanos ( self . start_time . elapsed ( ) . as_nanos ( ) as i64 ) ;
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self . physics_thread . send ( TimedInstruction {
time ,
instruction :InputInstruction ::Idle ,
} ) . unwrap ( ) ;
//update time lol
self . mouse . time = time ;
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let mut encoder =
device . create_command_encoder ( & wgpu ::CommandEncoderDescriptor { label : None } ) ;
// update rotation
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let camera_uniforms = self . graphics . camera . to_uniform_data ( self . physics_thread . grab_clone ( ) . adjust_mouse ( & self . mouse ) ) ;
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self . graphics . staging_belt
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. write_buffer (
& mut encoder ,
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& self . graphics . camera_buf ,
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0 ,
wgpu ::BufferSize ::new ( ( camera_uniforms . len ( ) * 4 ) as wgpu ::BufferAddress ) . unwrap ( ) ,
device ,
)
. copy_from_slice ( bytemuck ::cast_slice ( & camera_uniforms ) ) ;
//This code only needs to run when the uniforms change
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/*
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for model in self . graphics . models . iter ( ) {
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let model_uniforms = get_instances_buffer_data ( & model . instances ) ;
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self . graphics . staging_belt
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. write_buffer (
& mut encoder ,
& model . model_buf , //description of where data will be written when command is executed
0 , //offset in staging belt?
wgpu ::BufferSize ::new ( ( model_uniforms . len ( ) * 4 ) as wgpu ::BufferAddress ) . unwrap ( ) ,
device ,
)
. copy_from_slice ( bytemuck ::cast_slice ( & model_uniforms ) ) ;
}
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* /
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self . graphics . staging_belt . finish ( ) ;
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{
let mut rpass = encoder . begin_render_pass ( & wgpu ::RenderPassDescriptor {
label : None ,
color_attachments : & [ Some ( wgpu ::RenderPassColorAttachment {
view ,
resolve_target : None ,
ops : wgpu ::Operations {
load : wgpu ::LoadOp ::Clear ( wgpu ::Color {
r : 0.1 ,
g : 0.2 ,
b : 0.3 ,
a : 1.0 ,
} ) ,
store : true ,
} ,
} ) ] ,
depth_stencil_attachment : Some ( wgpu ::RenderPassDepthStencilAttachment {
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view : & self . graphics . depth_view ,
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depth_ops : Some ( wgpu ::Operations {
load : wgpu ::LoadOp ::Clear ( 1.0 ) ,
store : false ,
} ) ,
stencil_ops : None ,
} ) ,
} ) ;
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rpass . set_bind_group ( 0 , & self . graphics . bind_groups . camera , & [ ] ) ;
rpass . set_bind_group ( 1 , & self . graphics . bind_groups . skybox_texture , & [ ] ) ;
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rpass . set_pipeline ( & self . graphics . pipelines . model ) ;
for model in self . graphics . models . iter ( ) {
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rpass . set_bind_group ( 2 , & model . bind_group , & [ ] ) ;
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rpass . set_vertex_buffer ( 0 , model . vertex_buf . slice ( .. ) ) ;
for entity in model . entities . iter ( ) {
rpass . set_index_buffer ( entity . index_buf . slice ( .. ) , wgpu ::IndexFormat ::Uint16 ) ;
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rpass . draw_indexed ( 0 .. entity . index_count , 0 , 0 .. model . instances . len ( ) as u32 ) ;
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}
}
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rpass . set_pipeline ( & self . graphics . pipelines . skybox ) ;
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rpass . draw ( 0 .. 3 , 0 .. 1 ) ;
}
queue . submit ( std ::iter ::once ( encoder . finish ( ) ) ) ;
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self . graphics . staging_belt . recall ( ) ;
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}
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}
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fn main ( ) {
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framework ::run ::< GlobalState > (
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format! ( " Strafe Client v {} " ,
env! ( " CARGO_PKG_VERSION " )
) . as_str ( )
) ;
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}