doodle/pkg/level/types.go

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package level
2018-06-17 17:40:41 +00:00
import (
Zipfiles as File Format for Levels and Doodads Especially to further optimize memory for large levels, Levels and Doodads can now read and write to a ZIP file format on disk with chunks in external files within the zip. Existing doodads and levels can still load as normal, and will be converted into ZIP files on the next save: * The Chunker.ChunkMap which used to hold ALL chunks in the main json/gz file, now becomes the cache of "hot chunks" loaded from ZIP. If there is a ZIP file, chunks not accessed recently are flushed from the ChunkMap to save on memory. * During save, the ChunkMap is flushed to ZIP along with any non-loaded chunks from a previous zipfile. So legacy levels "just work" when saving, and levels loaded FROM Zip will manage their ChunkMap hot memory more carefully. Memory savings observed on "Azulian Tag - Forest.level": * Before: 1716 MB was loaded from the old level format into RAM along with a slow load screen. * After: only 243 MB memory was used by the game and it loaded with a VERY FAST load screen. Updates to the F3 Debug Overlay: * "Chunks: 20 in 45 out 20 cached" shows the count of chunks inside the viewport (having bitmaps and textures loaded) vs. chunks outside which have their textures freed (but data kept), and the number of chunks currently hot cached in the ChunkMap. The `doodad` tool has new commands to "touch" your existing levels and doodads, to upgrade them to the new format (or you can simply open and re-save them in-game): doodad edit-level --touch ./example.level doodad edit-doodad --touch ./example.doodad The output from that and `doodad show` should say "File format: zipfile" in the headers section. To do: * File attachments should also go in as ZIP files, e.g. wallpapers
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"archive/zip"
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"encoding/json"
"fmt"
Implement Chunk System for Pixel Data Starts the implementation of the chunk-based pixel storage system for levels and drawings. Previously the levels had a Pixels structure which was just an array of X,Y and palette index triplets. The new chunk system divides the map up into square chunks, and lets each chunk manage its own memory layout. The "MapAccessor" layout is implemented first which is a map of X,Y coordinates to their Swatches (pointer to an index of the palette). When serialized the MapAccessor maps the "X,Y": "index" similarly to the old Pixels array. The object hierarchy for the chunk system is like: * Chunker: the manager of the chunks who keeps track of the ChunkSize and a map of "chunk coordinates" to the chunk in charge of it. * Chunk: a part of the drawing ChunkSize length square. A chunk has a Type (of how it stores its data, 0 being a map[Point]Swatch and 1 being a [][]Swatch 2D array), and the chunk has an Accessor which implements the underlying type. * Accessor: an interface for a Chunk to provide access to its pixels. * MapAccessor: a "sparse map" of coordinates to their Swatches. * GridAccessor: TBD, will be a "dense" 2D grid of Swatches. The JSON files are loaded in two passes: 1. The chunks only load their swatch indexes from disk. 2. With the palette also loaded, the chunks are "inflated" and linked to their swatch pointers. Misc changes: * The `level.Canvas` UI widget switches from the old Grid data type to being able to directly use a `level.Chunker` * The Chunker is a shared data type between the on-disk level format and the actual renderer (level.Canvas), so saving the level is easy because you can just pull the Chunker out from the canvas. * ChunkSize is stored inside the level file and the default value is at balance/numbers.go: 1000
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"git.kirsle.net/SketchyMaze/doodle/pkg/balance"
"git.kirsle.net/SketchyMaze/doodle/pkg/drawtool"
"git.kirsle.net/SketchyMaze/doodle/pkg/enum"
"git.kirsle.net/SketchyMaze/doodle/pkg/log"
"git.kirsle.net/SketchyMaze/doodle/pkg/native"
"git.kirsle.net/go/render"
"git.kirsle.net/go/ui"
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)
Wallpapers and Bounded Levels Implement the Wallpaper system into the levels and the concept of Bounded and Unbounded levels. The first wallpaper image is notepad.png which looks like standard ruled notebook paper. On bounded levels, the top/left edges of the page look as you would expect and the blue lines tile indefinitely in the positive directions. On unbounded levels, you only get the repeating blue lines but not the edge pieces. A wallpaper is just a rectangular image file. The image is divided into four equal quadrants to be the Corner, Top, Left and Repeat textures for the wallpaper. The Repeat texture is ALWAYS used and fills all the empty space behind the drawing. (Doodads draw with blank canvases as before because only levels have wallpapers!) Levels have four options of a "Page Type": - Unbounded (default, infinite space) - NoNegativeSpace (has a top left edge but can grow infinitely) - Bounded (has a top left edge and bounded size) - Bordered (bounded with bordered texture; NOT IMPLEMENTED!) The scrollable viewport of a Canvas will respect the wallpaper and page type settings of a Level loaded into it. That is, if the level has a top left edge (not Unbounded) you can NOT scroll to see negative coordinates below (0,0) -- and if the level has a max dimension set, you can't scroll to see pixels outside those dimensions. The Canvas property NoLimitScroll=true will override the scroll locking and let you see outside the bounds, for debugging. - Default map settings for New Level are now: - Page Type: NoNegativeSpace - Wallpaper: notepad.png (default) - MaxWidth: 2550 (8.5" * 300 ppi) - MaxHeight: 3300 ( 11" * 300 ppi)
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// Useful variables.
var (
DefaultWallpaper = "notebook.png"
)
// Base provides the common struct keys that are shared between Levels and
// Doodads.
type Base struct {
Version int `json:"version"` // File format version spec.
GameVersion string `json:"gameVersion"` // Game version that created the level.
Title string `json:"title"`
Author string `json:"author"`
Locked bool `json:"locked"`
Draw Actors Embedded in Levels in Edit Mode Add the JSON format for embedding Actors (Doodad instances) inside of a Level. I made a test map that manually inserted a couple of actors. Actors are given to the Canvas responsible for the Level via the function `InstallActors()`. So it means you'll call LoadLevel and then InstallActors to hook everything up. The Canvas creates sub-Canvas widgets from each Actor. After drawing the main level geometry from the Canvas.Chunker, it calls the drawActors() function which does the same but for Actors. Levels keep a global map of all Actors that exist. For any Actors that are visible within the Viewport, their sub-Canvas widgets are presented appropriately on top of the parent Canvas. In case their sub-Canvas overlaps the parent's boundaries, their sub-Canvas is resized and moved appropriately. - Allow the MainWindow to be resized at run time, and the UI recalculates its sizing and position. - Made the in-game Shell properties editable via environment variables. The kirsle.env file sets a blue and pink color scheme. - Begin the ground work for Levels and Doodads to embed files inside their data via the level.FileSystem type. - UI: Labels can now contain line break characters. It will appropriately render multiple lines of render.Text and take into account the proper BoxSize to contain them all. - Add environment variable DOODLE_DEBUG_ALL=true that will turn on ALL debug overlay and visualization options. - Add debug overlay to "tag" each Canvas widget with some of its details, like its Name and World Position. Can be enabled with the environment variable DEBUG_CANVAS_LABEL=true - Improved the FPS debug overlay to show in labeled columns and multiple colors, with easy ability to add new data points to it.
2018-10-19 20:31:58 +00:00
Zipfiles as File Format for Levels and Doodads Especially to further optimize memory for large levels, Levels and Doodads can now read and write to a ZIP file format on disk with chunks in external files within the zip. Existing doodads and levels can still load as normal, and will be converted into ZIP files on the next save: * The Chunker.ChunkMap which used to hold ALL chunks in the main json/gz file, now becomes the cache of "hot chunks" loaded from ZIP. If there is a ZIP file, chunks not accessed recently are flushed from the ChunkMap to save on memory. * During save, the ChunkMap is flushed to ZIP along with any non-loaded chunks from a previous zipfile. So legacy levels "just work" when saving, and levels loaded FROM Zip will manage their ChunkMap hot memory more carefully. Memory savings observed on "Azulian Tag - Forest.level": * Before: 1716 MB was loaded from the old level format into RAM along with a slow load screen. * After: only 243 MB memory was used by the game and it loaded with a VERY FAST load screen. Updates to the F3 Debug Overlay: * "Chunks: 20 in 45 out 20 cached" shows the count of chunks inside the viewport (having bitmaps and textures loaded) vs. chunks outside which have their textures freed (but data kept), and the number of chunks currently hot cached in the ChunkMap. The `doodad` tool has new commands to "touch" your existing levels and doodads, to upgrade them to the new format (or you can simply open and re-save them in-game): doodad edit-level --touch ./example.level doodad edit-doodad --touch ./example.doodad The output from that and `doodad show` should say "File format: zipfile" in the headers section. To do: * File attachments should also go in as ZIP files, e.g. wallpapers
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// v2 level format: zip files with external chunks.
// (v0 was json text, v1 was gzip compressed json text).
// The game must load levels created using the previous
// formats, they will not have a Zipfile and will have
// Chunkers in memory from their (gz) json.
Zipfile *zip.Reader `json:"-"`
Draw Actors Embedded in Levels in Edit Mode Add the JSON format for embedding Actors (Doodad instances) inside of a Level. I made a test map that manually inserted a couple of actors. Actors are given to the Canvas responsible for the Level via the function `InstallActors()`. So it means you'll call LoadLevel and then InstallActors to hook everything up. The Canvas creates sub-Canvas widgets from each Actor. After drawing the main level geometry from the Canvas.Chunker, it calls the drawActors() function which does the same but for Actors. Levels keep a global map of all Actors that exist. For any Actors that are visible within the Viewport, their sub-Canvas widgets are presented appropriately on top of the parent Canvas. In case their sub-Canvas overlaps the parent's boundaries, their sub-Canvas is resized and moved appropriately. - Allow the MainWindow to be resized at run time, and the UI recalculates its sizing and position. - Made the in-game Shell properties editable via environment variables. The kirsle.env file sets a blue and pink color scheme. - Begin the ground work for Levels and Doodads to embed files inside their data via the level.FileSystem type. - UI: Labels can now contain line break characters. It will appropriately render multiple lines of render.Text and take into account the proper BoxSize to contain them all. - Add environment variable DOODLE_DEBUG_ALL=true that will turn on ALL debug overlay and visualization options. - Add debug overlay to "tag" each Canvas widget with some of its details, like its Name and World Position. Can be enabled with the environment variable DEBUG_CANVAS_LABEL=true - Improved the FPS debug overlay to show in labeled columns and multiple colors, with easy ability to add new data points to it.
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// Every drawing type is able to embed other files inside of itself.
Files *FileSystem `json:"files,omitempty"`
}
// Level is the container format for Doodle map drawings.
type Level struct {
Base
Password string `json:"passwd"`
Update savegame format, Allow out-of-bounds camera Updates the savegame.json file format: * Levels now have a UUID value assigned at first save. * The savegame.json will now track level completion/score based on UUID, making it robust to filename changes in either levels or levelpacks. * The savegame file is auto-migrated on startup - for any levels not found or have no UUID, no change is made, it's backwards compatible. * Level Properties window adds an "Advanced" tab to show/re-roll UUID. New JavaScript API for doodad scripts: * `Actors.CameraFollowPlayer()` tells the camera to return focus to the player character. Useful for "cutscene" doodads that freeze the player, call `Self.CameraFollowMe()` and do a thing before unfreezing and sending the camera back to the player. (Or it will follow them at their next directional input control). * `Self.MoveBy(Point(x, y int))` to move the current actor a bit. New option for the `doodad` command-line tool: * `doodad resave <.level or .doodad>` will load and re-save a drawing, to migrate it to the newest file format versions. Small tweaks: * On bounded levels, allow the camera to still follow the player if the player finds themselves WELL far out of bounds (40 pixels margin). So on bounded levels you can create "interior rooms" out-of-bounds to Warp Door into. * New wallpaper: "Atmosphere" has a black starscape pattern that fades into a solid blue atmosphere. * Camera strictly follows the player the first 20 ticks, not 60 of level start * If player is frozen, directional inputs do not take the camera focus back.
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UUID string `json:"uuid"` // unique level IDs, especially for the savegame.json
GameRule GameRule `json:"rules"`
Implement Chunk System for Pixel Data Starts the implementation of the chunk-based pixel storage system for levels and drawings. Previously the levels had a Pixels structure which was just an array of X,Y and palette index triplets. The new chunk system divides the map up into square chunks, and lets each chunk manage its own memory layout. The "MapAccessor" layout is implemented first which is a map of X,Y coordinates to their Swatches (pointer to an index of the palette). When serialized the MapAccessor maps the "X,Y": "index" similarly to the old Pixels array. The object hierarchy for the chunk system is like: * Chunker: the manager of the chunks who keeps track of the ChunkSize and a map of "chunk coordinates" to the chunk in charge of it. * Chunk: a part of the drawing ChunkSize length square. A chunk has a Type (of how it stores its data, 0 being a map[Point]Swatch and 1 being a [][]Swatch 2D array), and the chunk has an Accessor which implements the underlying type. * Accessor: an interface for a Chunk to provide access to its pixels. * MapAccessor: a "sparse map" of coordinates to their Swatches. * GridAccessor: TBD, will be a "dense" 2D grid of Swatches. The JSON files are loaded in two passes: 1. The chunks only load their swatch indexes from disk. 2. With the palette also loaded, the chunks are "inflated" and linked to their swatch pointers. Misc changes: * The `level.Canvas` UI widget switches from the old Grid data type to being able to directly use a `level.Chunker` * The Chunker is a shared data type between the on-disk level format and the actual renderer (level.Canvas), so saving the level is easy because you can just pull the Chunker out from the canvas. * ChunkSize is stored inside the level file and the default value is at balance/numbers.go: 1000
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// Chunked pixel data.
Chunker *Chunker `json:"chunks"`
Implement Chunk System for Pixel Data Starts the implementation of the chunk-based pixel storage system for levels and drawings. Previously the levels had a Pixels structure which was just an array of X,Y and palette index triplets. The new chunk system divides the map up into square chunks, and lets each chunk manage its own memory layout. The "MapAccessor" layout is implemented first which is a map of X,Y coordinates to their Swatches (pointer to an index of the palette). When serialized the MapAccessor maps the "X,Y": "index" similarly to the old Pixels array. The object hierarchy for the chunk system is like: * Chunker: the manager of the chunks who keeps track of the ChunkSize and a map of "chunk coordinates" to the chunk in charge of it. * Chunk: a part of the drawing ChunkSize length square. A chunk has a Type (of how it stores its data, 0 being a map[Point]Swatch and 1 being a [][]Swatch 2D array), and the chunk has an Accessor which implements the underlying type. * Accessor: an interface for a Chunk to provide access to its pixels. * MapAccessor: a "sparse map" of coordinates to their Swatches. * GridAccessor: TBD, will be a "dense" 2D grid of Swatches. The JSON files are loaded in two passes: 1. The chunks only load their swatch indexes from disk. 2. With the palette also loaded, the chunks are "inflated" and linked to their swatch pointers. Misc changes: * The `level.Canvas` UI widget switches from the old Grid data type to being able to directly use a `level.Chunker` * The Chunker is a shared data type between the on-disk level format and the actual renderer (level.Canvas), so saving the level is easy because you can just pull the Chunker out from the canvas. * ChunkSize is stored inside the level file and the default value is at balance/numbers.go: 1000
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// The Palette holds the unique "colors" used in this map file, and their
// properties (solid, fire, slippery, etc.)
Palette *Palette `json:"palette"`
Draw Actors Embedded in Levels in Edit Mode Add the JSON format for embedding Actors (Doodad instances) inside of a Level. I made a test map that manually inserted a couple of actors. Actors are given to the Canvas responsible for the Level via the function `InstallActors()`. So it means you'll call LoadLevel and then InstallActors to hook everything up. The Canvas creates sub-Canvas widgets from each Actor. After drawing the main level geometry from the Canvas.Chunker, it calls the drawActors() function which does the same but for Actors. Levels keep a global map of all Actors that exist. For any Actors that are visible within the Viewport, their sub-Canvas widgets are presented appropriately on top of the parent Canvas. In case their sub-Canvas overlaps the parent's boundaries, their sub-Canvas is resized and moved appropriately. - Allow the MainWindow to be resized at run time, and the UI recalculates its sizing and position. - Made the in-game Shell properties editable via environment variables. The kirsle.env file sets a blue and pink color scheme. - Begin the ground work for Levels and Doodads to embed files inside their data via the level.FileSystem type. - UI: Labels can now contain line break characters. It will appropriately render multiple lines of render.Text and take into account the proper BoxSize to contain them all. - Add environment variable DOODLE_DEBUG_ALL=true that will turn on ALL debug overlay and visualization options. - Add debug overlay to "tag" each Canvas widget with some of its details, like its Name and World Position. Can be enabled with the environment variable DEBUG_CANVAS_LABEL=true - Improved the FPS debug overlay to show in labeled columns and multiple colors, with easy ability to add new data points to it.
2018-10-19 20:31:58 +00:00
Wallpapers and Bounded Levels Implement the Wallpaper system into the levels and the concept of Bounded and Unbounded levels. The first wallpaper image is notepad.png which looks like standard ruled notebook paper. On bounded levels, the top/left edges of the page look as you would expect and the blue lines tile indefinitely in the positive directions. On unbounded levels, you only get the repeating blue lines but not the edge pieces. A wallpaper is just a rectangular image file. The image is divided into four equal quadrants to be the Corner, Top, Left and Repeat textures for the wallpaper. The Repeat texture is ALWAYS used and fills all the empty space behind the drawing. (Doodads draw with blank canvases as before because only levels have wallpapers!) Levels have four options of a "Page Type": - Unbounded (default, infinite space) - NoNegativeSpace (has a top left edge but can grow infinitely) - Bounded (has a top left edge and bounded size) - Bordered (bounded with bordered texture; NOT IMPLEMENTED!) The scrollable viewport of a Canvas will respect the wallpaper and page type settings of a Level loaded into it. That is, if the level has a top left edge (not Unbounded) you can NOT scroll to see negative coordinates below (0,0) -- and if the level has a max dimension set, you can't scroll to see pixels outside those dimensions. The Canvas property NoLimitScroll=true will override the scroll locking and let you see outside the bounds, for debugging. - Default map settings for New Level are now: - Page Type: NoNegativeSpace - Wallpaper: notepad.png (default) - MaxWidth: 2550 (8.5" * 300 ppi) - MaxHeight: 3300 ( 11" * 300 ppi)
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// Page boundaries and wallpaper settings.
PageType PageType `json:"pageType"`
MaxWidth int64 `json:"boundedWidth"` // only if bounded or bordered
MaxHeight int64 `json:"boundedHeight"`
Wallpaper string `json:"wallpaper"`
Wallpapers and Bounded Levels Implement the Wallpaper system into the levels and the concept of Bounded and Unbounded levels. The first wallpaper image is notepad.png which looks like standard ruled notebook paper. On bounded levels, the top/left edges of the page look as you would expect and the blue lines tile indefinitely in the positive directions. On unbounded levels, you only get the repeating blue lines but not the edge pieces. A wallpaper is just a rectangular image file. The image is divided into four equal quadrants to be the Corner, Top, Left and Repeat textures for the wallpaper. The Repeat texture is ALWAYS used and fills all the empty space behind the drawing. (Doodads draw with blank canvases as before because only levels have wallpapers!) Levels have four options of a "Page Type": - Unbounded (default, infinite space) - NoNegativeSpace (has a top left edge but can grow infinitely) - Bounded (has a top left edge and bounded size) - Bordered (bounded with bordered texture; NOT IMPLEMENTED!) The scrollable viewport of a Canvas will respect the wallpaper and page type settings of a Level loaded into it. That is, if the level has a top left edge (not Unbounded) you can NOT scroll to see negative coordinates below (0,0) -- and if the level has a max dimension set, you can't scroll to see pixels outside those dimensions. The Canvas property NoLimitScroll=true will override the scroll locking and let you see outside the bounds, for debugging. - Default map settings for New Level are now: - Page Type: NoNegativeSpace - Wallpaper: notepad.png (default) - MaxWidth: 2550 (8.5" * 300 ppi) - MaxHeight: 3300 ( 11" * 300 ppi)
2018-10-28 05:22:13 +00:00
// The last scrolled position in the editor.
ScrollPosition render.Point `json:"scroll"`
Draw Actors Embedded in Levels in Edit Mode Add the JSON format for embedding Actors (Doodad instances) inside of a Level. I made a test map that manually inserted a couple of actors. Actors are given to the Canvas responsible for the Level via the function `InstallActors()`. So it means you'll call LoadLevel and then InstallActors to hook everything up. The Canvas creates sub-Canvas widgets from each Actor. After drawing the main level geometry from the Canvas.Chunker, it calls the drawActors() function which does the same but for Actors. Levels keep a global map of all Actors that exist. For any Actors that are visible within the Viewport, their sub-Canvas widgets are presented appropriately on top of the parent Canvas. In case their sub-Canvas overlaps the parent's boundaries, their sub-Canvas is resized and moved appropriately. - Allow the MainWindow to be resized at run time, and the UI recalculates its sizing and position. - Made the in-game Shell properties editable via environment variables. The kirsle.env file sets a blue and pink color scheme. - Begin the ground work for Levels and Doodads to embed files inside their data via the level.FileSystem type. - UI: Labels can now contain line break characters. It will appropriately render multiple lines of render.Text and take into account the proper BoxSize to contain them all. - Add environment variable DOODLE_DEBUG_ALL=true that will turn on ALL debug overlay and visualization options. - Add debug overlay to "tag" each Canvas widget with some of its details, like its Name and World Position. Can be enabled with the environment variable DEBUG_CANVAS_LABEL=true - Improved the FPS debug overlay to show in labeled columns and multiple colors, with easy ability to add new data points to it.
2018-10-19 20:31:58 +00:00
// Actors keep a list of the doodad instances in this map.
Actors ActorMap `json:"actors"`
// Publishing: attach any custom doodads the map uses on save.
SaveDoodads bool `json:"saveDoodads"`
SaveBuiltins bool `json:"saveBuiltins"`
// Signature for a level with embedded doodads to still play in free mode.
Signature []byte `json:"signature,omitempty"`
// Undo history, temporary live data not persisted to the level file.
UndoHistory *drawtool.History `json:"-"`
// Cache of loaded images (e.g. screenshots).
cacheImages map[string]*ui.Image
}
// GameRule
type GameRule struct {
Difficulty enum.Difficulty `json:"difficulty"`
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Survival bool `json:"survival,omitempty"`
}
// New creates a blank level object with all its members initialized.
func New() *Level {
return &Level{
Base: Base{
Version: 1,
Title: "Untitled",
Author: native.DefaultAuthor,
Files: NewFileSystem(),
},
Implement Chunk System for Pixel Data Starts the implementation of the chunk-based pixel storage system for levels and drawings. Previously the levels had a Pixels structure which was just an array of X,Y and palette index triplets. The new chunk system divides the map up into square chunks, and lets each chunk manage its own memory layout. The "MapAccessor" layout is implemented first which is a map of X,Y coordinates to their Swatches (pointer to an index of the palette). When serialized the MapAccessor maps the "X,Y": "index" similarly to the old Pixels array. The object hierarchy for the chunk system is like: * Chunker: the manager of the chunks who keeps track of the ChunkSize and a map of "chunk coordinates" to the chunk in charge of it. * Chunk: a part of the drawing ChunkSize length square. A chunk has a Type (of how it stores its data, 0 being a map[Point]Swatch and 1 being a [][]Swatch 2D array), and the chunk has an Accessor which implements the underlying type. * Accessor: an interface for a Chunk to provide access to its pixels. * MapAccessor: a "sparse map" of coordinates to their Swatches. * GridAccessor: TBD, will be a "dense" 2D grid of Swatches. The JSON files are loaded in two passes: 1. The chunks only load their swatch indexes from disk. 2. With the palette also loaded, the chunks are "inflated" and linked to their swatch pointers. Misc changes: * The `level.Canvas` UI widget switches from the old Grid data type to being able to directly use a `level.Chunker` * The Chunker is a shared data type between the on-disk level format and the actual renderer (level.Canvas), so saving the level is easy because you can just pull the Chunker out from the canvas. * ChunkSize is stored inside the level file and the default value is at balance/numbers.go: 1000
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Chunker: NewChunker(balance.ChunkSize),
Palette: &Palette{},
Actors: ActorMap{},
Wallpapers and Bounded Levels Implement the Wallpaper system into the levels and the concept of Bounded and Unbounded levels. The first wallpaper image is notepad.png which looks like standard ruled notebook paper. On bounded levels, the top/left edges of the page look as you would expect and the blue lines tile indefinitely in the positive directions. On unbounded levels, you only get the repeating blue lines but not the edge pieces. A wallpaper is just a rectangular image file. The image is divided into four equal quadrants to be the Corner, Top, Left and Repeat textures for the wallpaper. The Repeat texture is ALWAYS used and fills all the empty space behind the drawing. (Doodads draw with blank canvases as before because only levels have wallpapers!) Levels have four options of a "Page Type": - Unbounded (default, infinite space) - NoNegativeSpace (has a top left edge but can grow infinitely) - Bounded (has a top left edge and bounded size) - Bordered (bounded with bordered texture; NOT IMPLEMENTED!) The scrollable viewport of a Canvas will respect the wallpaper and page type settings of a Level loaded into it. That is, if the level has a top left edge (not Unbounded) you can NOT scroll to see negative coordinates below (0,0) -- and if the level has a max dimension set, you can't scroll to see pixels outside those dimensions. The Canvas property NoLimitScroll=true will override the scroll locking and let you see outside the bounds, for debugging. - Default map settings for New Level are now: - Page Type: NoNegativeSpace - Wallpaper: notepad.png (default) - MaxWidth: 2550 (8.5" * 300 ppi) - MaxHeight: 3300 ( 11" * 300 ppi)
2018-10-28 05:22:13 +00:00
PageType: NoNegativeSpace,
Wallpaper: DefaultWallpaper,
MaxWidth: 2550,
MaxHeight: 3300,
UndoHistory: drawtool.NewHistory(balance.UndoHistory),
}
}
Optimize memory by freeing up SDL2 textures * Added to the F3 Debug Overlay is a "Texture:" label that counts the number of textures currently loaded by the (SDL2) render engine. * Added Teardown() functions to Level, Doodad and the Chunker they both use to free up SDL2 textures for all their cached graphics. * The Canvas.Destroy() function now cleans up all textures that the Canvas is responsible for: calling the Teardown() of the Level or Doodad, calling Destroy() on all level actors, and cleaning up Wallpaper textures. * The Destroy() method of the game's various Scenes will properly Destroy() their canvases to clean up when transitioning to another scene. The MainScene, MenuScene, EditorScene and PlayScene. * Fix the sprites package to actually cache the ui.Image widgets. The game has very few sprites so no need to free them just yet. Some tricky places that were leaking textures have been cleaned up: * Canvas.InstallActors() destroys the canvases of existing actors before it reinitializes the list and installs the replacements. * The DraggableActor when the user is dragging an actor around their level cleans up the blueprint masked drag/drop actor before nulling it out. Misc changes: * The player character cheats during Play Mode will immediately swap out the player character on the current level. * Properly call the Close() function instead of Hide() to dismiss popup windows. The Close() function itself calls Hide() but also triggers WindowClose event handlers. The Doodad Dropper subscribes to its close event to free textures for all its doodad canvases.
2022-04-09 21:41:24 +00:00
// Teardown the level when the game is done with it. This frees up SDL2 cached
// texture chunks and reclaims memory in ways the Go garbage collector can not.
func (m *Level) Teardown() {
var (
chunks int
textures int
)
Zipfiles as File Format for Levels and Doodads Especially to further optimize memory for large levels, Levels and Doodads can now read and write to a ZIP file format on disk with chunks in external files within the zip. Existing doodads and levels can still load as normal, and will be converted into ZIP files on the next save: * The Chunker.ChunkMap which used to hold ALL chunks in the main json/gz file, now becomes the cache of "hot chunks" loaded from ZIP. If there is a ZIP file, chunks not accessed recently are flushed from the ChunkMap to save on memory. * During save, the ChunkMap is flushed to ZIP along with any non-loaded chunks from a previous zipfile. So legacy levels "just work" when saving, and levels loaded FROM Zip will manage their ChunkMap hot memory more carefully. Memory savings observed on "Azulian Tag - Forest.level": * Before: 1716 MB was loaded from the old level format into RAM along with a slow load screen. * After: only 243 MB memory was used by the game and it loaded with a VERY FAST load screen. Updates to the F3 Debug Overlay: * "Chunks: 20 in 45 out 20 cached" shows the count of chunks inside the viewport (having bitmaps and textures loaded) vs. chunks outside which have their textures freed (but data kept), and the number of chunks currently hot cached in the ChunkMap. The `doodad` tool has new commands to "touch" your existing levels and doodads, to upgrade them to the new format (or you can simply open and re-save them in-game): doodad edit-level --touch ./example.level doodad edit-doodad --touch ./example.doodad The output from that and `doodad show` should say "File format: zipfile" in the headers section. To do: * File attachments should also go in as ZIP files, e.g. wallpapers
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// Free any CACHED chunks' memory.
for chunk := range m.Chunker.IterCachedChunks() {
freed := chunk.Teardown()
chunks++
textures += freed
Optimize memory by freeing up SDL2 textures * Added to the F3 Debug Overlay is a "Texture:" label that counts the number of textures currently loaded by the (SDL2) render engine. * Added Teardown() functions to Level, Doodad and the Chunker they both use to free up SDL2 textures for all their cached graphics. * The Canvas.Destroy() function now cleans up all textures that the Canvas is responsible for: calling the Teardown() of the Level or Doodad, calling Destroy() on all level actors, and cleaning up Wallpaper textures. * The Destroy() method of the game's various Scenes will properly Destroy() their canvases to clean up when transitioning to another scene. The MainScene, MenuScene, EditorScene and PlayScene. * Fix the sprites package to actually cache the ui.Image widgets. The game has very few sprites so no need to free them just yet. Some tricky places that were leaking textures have been cleaned up: * Canvas.InstallActors() destroys the canvases of existing actors before it reinitializes the list and installs the replacements. * The DraggableActor when the user is dragging an actor around their level cleans up the blueprint masked drag/drop actor before nulling it out. Misc changes: * The player character cheats during Play Mode will immediately swap out the player character on the current level. * Properly call the Close() function instead of Hide() to dismiss popup windows. The Close() function itself calls Hide() but also triggers WindowClose event handlers. The Doodad Dropper subscribes to its close event to free textures for all its doodad canvases.
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}
// Free any cached images (screenshots)
if m.cacheImages != nil {
for _, img := range m.cacheImages {
img.Destroy()
}
}
Optimize memory by freeing up SDL2 textures * Added to the F3 Debug Overlay is a "Texture:" label that counts the number of textures currently loaded by the (SDL2) render engine. * Added Teardown() functions to Level, Doodad and the Chunker they both use to free up SDL2 textures for all their cached graphics. * The Canvas.Destroy() function now cleans up all textures that the Canvas is responsible for: calling the Teardown() of the Level or Doodad, calling Destroy() on all level actors, and cleaning up Wallpaper textures. * The Destroy() method of the game's various Scenes will properly Destroy() their canvases to clean up when transitioning to another scene. The MainScene, MenuScene, EditorScene and PlayScene. * Fix the sprites package to actually cache the ui.Image widgets. The game has very few sprites so no need to free them just yet. Some tricky places that were leaking textures have been cleaned up: * Canvas.InstallActors() destroys the canvases of existing actors before it reinitializes the list and installs the replacements. * The DraggableActor when the user is dragging an actor around their level cleans up the blueprint masked drag/drop actor before nulling it out. Misc changes: * The player character cheats during Play Mode will immediately swap out the player character on the current level. * Properly call the Close() function instead of Hide() to dismiss popup windows. The Close() function itself calls Hide() but also triggers WindowClose event handlers. The Doodad Dropper subscribes to its close event to free textures for all its doodad canvases.
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log.Debug("Teardown level (%s): Freed %d textures across %d level chunks", m.Title, textures, chunks)
}
// Pixel associates a coordinate with a palette index.
type Pixel struct {
X int `json:"x"`
Y int `json:"y"`
PaletteIndex int `json:"p"`
// Private runtime values.
Swatch *Swatch `json:"-"` // pointer to its swatch, for when rendered.
}
func (p Pixel) String() string {
return fmt.Sprintf("Pixel<%s '%s' (%d,%d)>", p.Swatch.Color, p.Swatch.Name, p.X, p.Y)
}
Implement Chunk System for Pixel Data Starts the implementation of the chunk-based pixel storage system for levels and drawings. Previously the levels had a Pixels structure which was just an array of X,Y and palette index triplets. The new chunk system divides the map up into square chunks, and lets each chunk manage its own memory layout. The "MapAccessor" layout is implemented first which is a map of X,Y coordinates to their Swatches (pointer to an index of the palette). When serialized the MapAccessor maps the "X,Y": "index" similarly to the old Pixels array. The object hierarchy for the chunk system is like: * Chunker: the manager of the chunks who keeps track of the ChunkSize and a map of "chunk coordinates" to the chunk in charge of it. * Chunk: a part of the drawing ChunkSize length square. A chunk has a Type (of how it stores its data, 0 being a map[Point]Swatch and 1 being a [][]Swatch 2D array), and the chunk has an Accessor which implements the underlying type. * Accessor: an interface for a Chunk to provide access to its pixels. * MapAccessor: a "sparse map" of coordinates to their Swatches. * GridAccessor: TBD, will be a "dense" 2D grid of Swatches. The JSON files are loaded in two passes: 1. The chunks only load their swatch indexes from disk. 2. With the palette also loaded, the chunks are "inflated" and linked to their swatch pointers. Misc changes: * The `level.Canvas` UI widget switches from the old Grid data type to being able to directly use a `level.Chunker` * The Chunker is a shared data type between the on-disk level format and the actual renderer (level.Canvas), so saving the level is easy because you can just pull the Chunker out from the canvas. * ChunkSize is stored inside the level file and the default value is at balance/numbers.go: 1000
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// Point returns the pixel's point.
func (p Pixel) Point() render.Point {
return render.Point{
X: p.X,
Y: p.Y,
}
}
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// MarshalJSON serializes a Pixel compactly as a simple list.
func (p Pixel) MarshalJSON() ([]byte, error) {
return []byte(fmt.Sprintf(
`[%d, %d, %d]`,
p.X, p.Y, p.PaletteIndex,
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)), nil
}
// UnmarshalJSON loads a Pixel from JSON again.
func (p *Pixel) UnmarshalJSON(text []byte) error {
var triplet []int
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err := json.Unmarshal(text, &triplet)
if err != nil {
return err
}
p.X = triplet[0]
p.Y = triplet[1]
if len(triplet) > 2 {
p.PaletteIndex = triplet[2]
}
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return nil
}