193 lines
5.8 KiB
Odin
193 lines
5.8 KiB
Odin
package sectr
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import rl "vendor:raylib"
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// The points to pixels and pixels to points are our only reference to accurately converting
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// an object from world space to screen-space.
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// This prototype engine will have all its spacial unit base for distances in pixels.
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Inches_To_CM :: cast(f32) 2.54
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Points_Per_CM :: cast(f32) 28.3465
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CM_Per_Point :: cast(f32) 1.0 / DPT_DPCM
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CM_Per_Pixel :: cast(f32) 1.0 / DPT_PPCM
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DPT_DPCM :: cast(f32) 72.0 * Inches_To_CM // 182.88 points/dots per cm
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DPT_PPCM :: cast(f32) 96.0 * Inches_To_CM // 243.84 pixels per cm
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when ODIN_OS == OS_Type.Windows {
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op_default_dpcm :: 72.0 * Inches_To_CM
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os_default_ppcm :: 96.0 * Inches_To_CM
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// 1 inch = 2.54 cm, 96 inch * 2.54 = 243.84 DPCM
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}
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//region Unit Conversion Impl
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// cm_to_points :: proc( cm : f32 ) -> f32 {
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// }
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// points_to_cm :: proc( points : f32 ) -> f32 {
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// screen_dpc := get_state().app_window.dpc
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// cm_per_pixel := 1.0 / screen_dpc
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// pixels := points * DPT_DPC * cm_per_pixel
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// return points *
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// }
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f32_cm_to_pixels :: proc(cm: f32) -> f32 {
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screen_ppcm := get_state().app_window.ppcm
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return cm * screen_ppcm
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}
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f32_pixels_to_cm :: proc(pixels: f32) -> f32 {
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screen_ppcm := get_state().app_window.ppcm
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cm_per_pixel := 1.0 / screen_ppcm
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return pixels * cm_per_pixel
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}
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f32_points_to_pixels :: proc(points: f32) -> f32 {
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screen_ppcm := get_state().app_window.ppcm
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cm_per_pixel := 1.0 / screen_ppcm
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return points * DPT_PPCM * cm_per_pixel
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}
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f32_pixels_to_points :: proc(pixels: f32) -> f32 {
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screen_ppcm := get_state().app_window.ppcm
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cm_per_pixel := 1.0 / screen_ppcm
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return pixels * cm_per_pixel * Points_Per_CM
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}
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vec2_cm_to_pixels :: proc(v: Vec2) -> Vec2 {
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screen_ppcm := get_state().app_window.ppcm
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return v * screen_ppcm
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}
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vec2_pixels_to_cm :: proc(v: Vec2) -> Vec2 {
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screen_ppcm := get_state().app_window.ppcm
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cm_per_pixel := 1.0 / screen_ppcm
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return v * cm_per_pixel
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}
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vec2_points_to_pixels :: proc(vpoints: Vec2) -> Vec2 {
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screen_ppcm := get_state().app_window.ppcm
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cm_per_pixel := 1.0 / screen_ppcm
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return vpoints * DPT_PPCM * cm_per_pixel
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}
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range2_cm_to_pixels :: proc( range : Range2 ) -> Range2 {
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screen_ppcm := get_state().app_window.ppcm
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result := Range2 { pts = { range.min * screen_ppcm, range.max * screen_ppcm }}
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return result
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}
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range2_pixels_to_cm :: proc( range : Range2 ) -> Range2 {
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screen_ppcm := get_state().app_window.ppcm
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cm_per_pixel := 1.0 / screen_ppcm
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result := Range2 { pts = { range.min * cm_per_pixel, range.max * cm_per_pixel }}
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return result
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}
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// vec2_points_to_cm :: proc( vpoints : Vec2 ) -> Vec2 {
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// }
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//endregion
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Camera :: rl.Camera2D
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CameraZoomMode :: enum u32 {
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Digital,
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Smooth,
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}
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// TODO(Ed) : I'm not sure making the size and extent types distinct has made things easier or more difficult in Odin..
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// The lack of operator overloads is going to make any sort of nice typesystem
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// for doing lots of math or phyiscs more error prone or filled with proc wrappers
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AreaSize :: distinct Vec2
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Bounds2 :: struct {
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top_left, bottom_right: Vec2,
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}
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BoundsCorners2 :: struct {
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top_left, top_right, bottom_left, bottom_right: Vec2,
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}
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Extents2 :: distinct Vec2
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Extents2i :: distinct Vec2i
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WS_Pos :: struct {
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tile_id : Vec2i,
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rel : Vec2,
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}
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bounds2_radius :: proc(bounds: Bounds2) -> f32 {
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return max( bounds.bottom_right.x, bounds.top_left.y )
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}
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extent_from_size :: proc(size: AreaSize) -> Extents2 {
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return transmute(Extents2) size * 2.0
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}
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screen_size :: proc "contextless" () -> AreaSize {
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extent := get_state().app_window.extent
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return transmute(AreaSize) ( extent * 2.0 )
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}
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screen_get_corners :: proc() -> BoundsCorners2 {
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state := get_state(); using state
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screen_extent := state.app_window.extent
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top_left := Vec2 { -screen_extent.x, screen_extent.y }
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top_right := Vec2 { screen_extent.x, screen_extent.y }
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bottom_left := Vec2 { -screen_extent.x, -screen_extent.y }
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bottom_right := Vec2 { screen_extent.x, -screen_extent.y }
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return { top_left, top_right, bottom_left, bottom_right }
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}
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view_get_bounds :: proc() -> Range2 {
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state := get_state(); using state
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cam := & project.workspace.cam
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screen_extent := state.app_window.extent
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top_left := Vec2 { cam.target.x, -cam.target.y } + Vec2 { -screen_extent.x, screen_extent.y} * (1/cam.zoom)
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bottom_right := Vec2 { cam.target.x, -cam.target.y } + Vec2 { screen_extent.x, -screen_extent.y} * (1/cam.zoom)
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return range2(top_left, bottom_right)
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}
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view_get_corners :: proc() -> BoundsCorners2 {
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state := get_state(); using state
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cam := & project.workspace.cam
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cam_zoom_ratio := 1.0 / cam.zoom
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screen_extent := state.app_window.extent * cam_zoom_ratio
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top_left := cam.target + Vec2 { -screen_extent.x, screen_extent.y }
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top_right := cam.target + Vec2 { screen_extent.x, screen_extent.y }
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bottom_left := cam.target + Vec2 { -screen_extent.x, -screen_extent.y }
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bottom_right := cam.target + Vec2 { screen_extent.x, -screen_extent.y }
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return { top_left, top_right, bottom_left, bottom_right }
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}
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screen_to_world :: #force_inline proc "contextless" (pos: Vec2) -> Vec2 {
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state := get_state(); using state
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cam := & project.workspace.cam
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result := Vec2 { cam.target.x, -cam.target.y} + Vec2 { pos.x, -pos.y } * (1 / cam.zoom)
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return result
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}
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screen_to_render :: proc(pos: Vec2) -> Vec2 {
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screen_extent := transmute(Vec2) get_state().project.workspace.cam.offset
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return pos + { screen_extent.x, -screen_extent.y }
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}
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world_screen_extent :: proc() -> Extents2 {
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state := get_state(); using state
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cam_zoom_ratio := 1.0 / project.workspace.cam.zoom
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return app_window.extent * cam_zoom_ratio
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}
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world_to_screen_pos :: proc(position: Vec2) -> Vec2 {
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return { position.x, position.y * -1 }
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}
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world_to_screen_no_zoom :: proc(position: Vec2) -> Vec2 {
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state := get_state(); using state
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cam_zoom_ratio := 1.0 / state.project.workspace.cam.zoom
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return { position.x, position.y * -1 } * cam_zoom_ratio
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}
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