SectrPrototype/code/env_env.odin
Ed_ 595de438af WIP: Persistent order support for rooted boxes (top-most boxes)
I wasn't expecting it to be this to bad to support it...

Also:
* I renamed some of the files to group better with the virtual codebase view
2024-05-13 01:53:19 -04:00

260 lines
7.1 KiB
Odin

package sectr
import "base:runtime"
import "core:fmt"
import "core:mem"
import "core:mem/virtual"
import "core:os"
import rl "vendor:raylib"
Str_App_State := "App State"
#region("Memory")
Memory_App : Memory
Memory_Base_Address_Persistent :: Terabyte * 1
Memory_Base_Address_Frame :: Memory_Base_Address_Persistent + Memory_Reserve_Persistent * 2
Memory_Base_Address_Transient :: Memory_Base_Address_Frame + Memory_Reserve_Frame * 2
Memory_Base_Address_Files_Buffer :: Memory_Base_Address_Transient + Memory_Reserve_Transient * 2
// This reserve goes beyond the typical amount of ram the user has,
// TODO(Ed): Setup warnings when the amount is heading toward half the ram size
Memory_Reserve_Persistent :: 32 * Gigabyte
Memory_Reserve_Frame :: 16 * Gigabyte
Memory_Reserve_Transient :: 16 * Gigabyte
Memory_Reserve_FilesBuffer :: 64 * Gigabyte
Memory_Commit_Initial_Persistent :: 4 * Kilobyte
Memory_Commit_Initial_Frame :: 4 * Kilobyte
Memory_Commit_Initial_Transient :: 4 * Kilobyte
Memory_Commit_Initial_Filebuffer :: 4 * Kilobyte
MemorySnapshot :: struct {
persistent : []u8,
frame : []u8,
transient : []u8,
// files_buffer cannot be restored from snapshot
}
Memory :: struct {
persistent : ^VArena,
frame : ^VArena,
transient : ^VArena,
files_buffer : ^VArena,
state : ^State,
// Should only be used for small memory allocation iterations
// Not for large memory env states
snapshot : MemorySnapshot,
replay : ReplayState,
logger : Logger,
profiler : ^SpallProfiler
}
persistent_allocator :: proc() -> Allocator {
result := varena_allocator( Memory_App.persistent )
return result
}
frame_allocator :: proc() -> Allocator {
result := varena_allocator( Memory_App.frame )
return result
}
transient_allocator :: proc() -> Allocator {
result := varena_allocator( Memory_App.transient )
return result
}
files_buffer_allocator :: proc() -> Allocator {
result := varena_allocator( Memory_App.files_buffer )
return result
}
persistent_slab_allocator :: proc() -> Allocator {
state := get_state()
result := slab_allocator( state.persistent_slab )
return result
}
frame_slab_allocator :: proc() -> Allocator {
result := slab_allocator( get_state().frame_slab )
return result
}
transient_slab_allocator :: proc() -> Allocator {
result := slab_allocator( get_state().transient_slab )
return result
}
// TODO(Ed) : Implment host memory mapping api
save_snapshot :: proc( snapshot : ^MemorySnapshot )
{
// Make sure the snapshot size is able to hold the current size of the arenas
// Grow the files & mapping otherwise
{
// TODO(Ed) : Implement eventually
}
persistent := Memory_App.persistent
mem.copy_non_overlapping( & snapshot.persistent[0], persistent.reserve_start, int(persistent.commit_used) )
frame := Memory_App.frame
mem.copy_non_overlapping( & snapshot.frame[0], frame.reserve_start, int(frame.commit_used) )
transient := Memory_App.transient
mem.copy_non_overlapping( & snapshot.transient[0], transient.reserve_start, int(transient.commit_used) )
}
// TODO(Ed) : Implment host memory mapping api
load_snapshot :: proc( snapshot : ^MemorySnapshot ) {
persistent := Memory_App.persistent
mem.copy_non_overlapping( persistent.reserve_start, & snapshot.persistent[0], int(persistent.commit_used) )
frame := Memory_App.frame
mem.copy_non_overlapping( frame.reserve_start, & snapshot.frame[0], int(frame.commit_used) )
transient := Memory_App.transient
mem.copy_non_overlapping( transient.reserve_start, & snapshot.transient[0], int(transient.commit_used) )
}
// TODO(Ed) : Implement usage of this
MemoryConfig :: struct {
reserve_persistent : uint,
reserve_frame : uint,
reserve_transient : uint,
reserve_filebuffer : uint,
commit_initial_persistent : uint,
commit_initial_frame : uint,
commit_initial_transient : uint,
commit_initial_filebuffer : uint,
}
#endregion("Memory")
#region("State")
// ALl nobs available for this application
AppConfig :: struct {
using memory : MemoryConfig,
resolution_width : uint,
resolution_height : uint,
refresh_rate : uint,
cam_min_zoom : f32,
cam_max_zoom : f32,
cam_zoom_mode : CameraZoomMode,
cam_zoom_smooth_snappiness : f32,
cam_zoom_sensitivity_smooth : f32,
cam_zoom_sensitivity_digital : f32,
engine_refresh_hz : uint,
timing_fps_moving_avg_alpha : f32,
ui_resize_border_width : f32,
}
AppWindow :: struct {
extent : Extents2, // Window half-size
dpi_scale : f32, // Dots per inch scale (provided by raylib via glfw)
ppcm : f32, // Dots per centimetre
}
FontData :: struct {
provider : FontProviderData,
// TODO(Ed): We can have font constants here I guess but eventually
// I rather have fonts configurable for a 'theme' combo
// So that way which IDs are picked depends on runtime
firacode : FontID,
squidgy_slimes : FontID,
rec_mono_semicasual_reg : FontID,
default_font : FontID,
}
FrameTime :: struct {
sleep_is_granular : b32,
delta_seconds : f64,
delta_ms : f64,
delta_ns : Duration,
target_ms : f64,
elapsed_ms : f64,
avg_ms : f64,
fps_avg : f64,
}
// Global Singleton stored in the persistent virtual arena, the first allocated data.
// Use get_state() to conviently retrieve at any point for the program's lifetime
State :: struct {
default_slab_policy : SlabPolicy,
persistent_slab : Slab,
frame_slab : Slab,
transient_slab : Slab, // TODO(Ed): This needs to be recreated per transient wipe
transinet_clear_lock : b32, // Pravents auto-free of transient at designated intervals
transient_clear_time : f32, // Time in seconds for the usual period to clear transient
transient_clear_elapsed : f32, // Time since last clear
string_cache : StringCache,
input_data : [2]InputState,
input_prev : ^InputState,
input : ^InputState,
debug : DebugData,
project : Project,
config : AppConfig,
app_window : AppWindow,
screen_ui : UI_ScreenState,
monitor_id : i32,
monitor_refresh_hz : i32,
// using frametime : FrameTime,
sleep_is_granular : b32,
frametime_delta_seconds : f64,
frametime_delta_ms : f64,
frametime_delta_ns : Duration,
frametime_target_ms : f64,
frametime_elapsed_ms : f64,
frametime_avg_ms : f64,
fps_avg : f64,
// fonts : FontData,
font_provider_data : FontProviderData,
font_firacode : FontID,
font_squidgy_slimes : FontID,
font_rec_mono_semicasual_reg : FontID,
default_font : FontID,
// There are two potential UI contextes for this prototype so far,
// the screen-space UI and the current workspace UI.
// This is used so that the ui api doesn't need to have the user pass the context every single time.
ui_context : ^UI_State,
// The camera is considered the "context" for coodrinate space operations in rendering
cam_context : Camera,
}
get_state :: #force_inline proc "contextless" () -> ^ State {
return cast( ^ State ) Memory_App.persistent.reserve_start
}
// get_frametime :: #force_inline proc "contextless" () -> FrameTime {
// return get_state().frametime
// }
#endregion("State")