doodle/lib/render/point.go

package render

import (
	"fmt"
	"strconv"
	"strings"
)

// Point holds an X,Y coordinate value.
type Point struct {
	X int32
	Y int32
}

// Common points.
var (
	Origin Point
)

// NewPoint makes a new Point at an X,Y coordinate.
func NewPoint(x, y int32) Point {
	return Point{
		X: x,
		Y: y,
	}
}

func (p Point) String() string {
	return fmt.Sprintf("%d,%d", p.X, p.Y)
}

// ParsePoint to parse a point from its string representation.
func ParsePoint(v string) (Point, error) {
	halves := strings.Split(v, ",")
	if len(halves) != 2 {
		return Point{}, fmt.Errorf("'%s': not a valid coordinate string", v)
	}
	x, errX := strconv.Atoi(halves[0])
	y, errY := strconv.Atoi(halves[1])
	if errX != nil || errY != nil {
		return Point{}, fmt.Errorf("invalid coordinate string (X: %v; Y: %v)",
			errX,
			errY,
		)
	}
	return Point{
		X: int32(x),
		Y: int32(y),
	}, nil
}

// IsZero returns if the point is the zero value.
func (p Point) IsZero() bool {
	return p.X == 0 && p.Y == 0
}

// Inside returns whether the Point falls inside the rect.
//
// NOTICE: the W and H are zero-relative, so a 100x100 box at coordinate
// X,Y would still have W,H of 100.
func (p Point) Inside(r Rect) bool {
	var (
		x1 = r.X
		y1 = r.Y
		x2 = r.X + r.W
		y2 = r.Y + r.H
	)
	return ((p.X >= x1 && p.X <= x2) &&
		(p.Y >= y1 && p.Y <= y2))
}

// Add (or subtract) the other point to your current point. This is usually
// the one you want: if the other Point has negative values it will subtract
// them from this Point, or if they are positive it will add them.
func (p *Point) Add(other Point) {
	p.X += other.X
	p.Y += other.Y
}

// Subtract is the inverse of Add. Use this if you want to force a subtraction
// operation (i.e. to invert a Point before adding it).
func (p *Point) Subtract(other Point) {
	p.X -= other.X
	p.Y -= other.Y
}

// MarshalText to convert the point into text so that a render.Point may be used
// as a map key and serialized to JSON.
func (p *Point) MarshalText() ([]byte, error) {
	return []byte(fmt.Sprintf("%d,%d", p.X, p.Y)), nil
}

// UnmarshalText to restore it from text.
func (p *Point) UnmarshalText(b []byte) error {
	halves := strings.Split(strings.Trim(string(b), `"`), ",")
	if len(halves) != 2 {
		return fmt.Errorf("'%s': not a valid coordinate string", b)
	}

	x, errX := strconv.Atoi(halves[0])
	y, errY := strconv.Atoi(halves[1])
	if errX != nil || errY != nil {
		return fmt.Errorf("Point.UnmarshalJSON: Atoi errors (X=%s Y=%s)",
			errX,
			errY,
		)
	}

	p.X = int32(x)
	p.Y = int32(y)
	return nil
}
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 2018-09-23 22:20:45 +00:00			`package render`

			`import (`
			`"fmt"`
			`"strconv"`
			`"strings"`
			`)`

			`// Point holds an X,Y coordinate value.`
			`type Point struct {`
			`X int32`
			`Y int32`
			`}`

Fix Play Mode, Level Handover & Collision Detection * Edit Mode now uses the Level object itself to keep the drawing data rather than pull its Palette and Chunks out, so it can hang on to more information. The Canvas widget is given references to the Level.Palette and Level.Chunker via Canvas.LoadLevel() * Fix the handoff between Edit Mode and Play Mode. They pass the Level object back and forth and the Filename, because it's not part of the Level. You can save the map with its original settings after returning from Play Mode. * Fix the collision detection in Play Mode. It broke previously when palettes were added because of the difference between a render.Point and a level.Pixel and it couldn't easily look up coordinates. The new Chunker system provides a render.Point lookup API. * All pixels are solid for collision right now, TODO is to return Swatch information from the pixels touching the player character and react accordingly (non-solid, fire flag, etc.) * Remove the level.Grid type as it has been replaced by the Chunker. * Clean up some unused variables and functions. 2018-09-25 16:40:34 +00:00			`// Common points.`
			`var (`
			`Origin Point`
			`)`

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 2018-09-23 22:20:45 +00:00			`// NewPoint makes a new Point at an X,Y coordinate.`
			`func NewPoint(x, y int32) Point {`
			`return Point{`
			`X: x,`
			`Y: y,`
			`}`
			`}`

			`func (p Point) String() string {`
			`return fmt.Sprintf("%d,%d", p.X, p.Y)`
			`}`

			`// ParsePoint to parse a point from its string representation.`
			`func ParsePoint(v string) (Point, error) {`
			`halves := strings.Split(v, ",")`
			`if len(halves) != 2 {`
			`return Point{}, fmt.Errorf("'%s': not a valid coordinate string", v)`
			`}`
			`x, errX := strconv.Atoi(halves[0])`
			`y, errY := strconv.Atoi(halves[1])`
			`if errX != nil \|\| errY != nil {`
			`return Point{}, fmt.Errorf("invalid coordinate string (X: %v; Y: %v)",`
			`errX,`
			`errY,`
			`)`
			`}`
			`return Point{`
			`X: int32(x),`
			`Y: int32(y),`
			`}, nil`
			`}`

			`// IsZero returns if the point is the zero value.`
			`func (p Point) IsZero() bool {`
			`return p.X == 0 && p.Y == 0`
			`}`

			`// Inside returns whether the Point falls inside the rect.`
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			`//`
			`// NOTICE: the W and H are zero-relative, so a 100x100 box at coordinate`
			`// X,Y would still have W,H of 100.`
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 2018-09-23 22:20:45 +00:00			`func (p Point) Inside(r Rect) bool {`
			`var (`
			`x1 = r.X`
			`y1 = r.Y`
			`x2 = r.X + r.W`
			`y2 = r.Y + r.H`
			`)`
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			`return ((p.X >= x1 && p.X <= x2) &&`
			`(p.Y >= y1 && p.Y <= y2))`
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 2018-09-23 22:20:45 +00:00			`}`

Add test wallpaper and minor code tweaks 2018-12-30 21:50:24 +00:00			`// Add (or subtract) the other point to your current point. This is usually`
			`// the one you want: if the other Point has negative values it will subtract`
			`// them from this Point, or if they are positive it will add them.`
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 2018-09-23 22:20:45 +00:00			`func (p *Point) Add(other Point) {`
			`p.X += other.X`
			`p.Y += other.Y`
			`}`

Add test wallpaper and minor code tweaks 2018-12-30 21:50:24 +00:00			`// Subtract is the inverse of Add. Use this if you want to force a subtraction`
			`// operation (i.e. to invert a Point before adding it).`
			`func (p *Point) Subtract(other Point) {`
			`p.X -= other.X`
			`p.Y -= other.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 2018-09-23 22:20:45 +00:00			`// MarshalText to convert the point into text so that a render.Point may be used`
			`// as a map key and serialized to JSON.`
			`func (p *Point) MarshalText() ([]byte, error) {`
			`return []byte(fmt.Sprintf("%d,%d", p.X, p.Y)), nil`
			`}`

			`// UnmarshalText to restore it from text.`
			`func (p *Point) UnmarshalText(b []byte) error {`
			halves := strings.Split(strings.Trim(string(b), `"`), ",")
			`if len(halves) != 2 {`
			`return fmt.Errorf("'%s': not a valid coordinate string", b)`
			`}`

			`x, errX := strconv.Atoi(halves[0])`
			`y, errY := strconv.Atoi(halves[1])`
			`if errX != nil \|\| errY != nil {`
			`return fmt.Errorf("Point.UnmarshalJSON: Atoi errors (X=%s Y=%s)",`
			`errX,`
			`errY,`
			`)`
			`}`

			`p.X = int32(x)`
			`p.Y = int32(y)`
			`return nil`
			`}`