doodle/shell.go

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package doodle
import (
"bytes"
"fmt"
"strings"
"git.kirsle.net/apps/doodle/balance"
"git.kirsle.net/apps/doodle/events"
"git.kirsle.net/apps/doodle/render"
"github.com/robertkrimen/otto"
)
// Flash a message to the user.
func (d *Doodle) Flash(template string, v ...interface{}) {
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
log.Warn(template, v...)
d.shell.Write(fmt.Sprintf(template, v...))
}
// Prompt the user for a question in the dev console.
func (d *Doodle) Prompt(question string, callback func(string)) {
d.shell.Prompt = question
d.shell.callback = callback
d.shell.Open = true
}
// Shell implements the developer console in-game.
type Shell struct {
parent *Doodle
Open bool
Prompt string
callback func(string) // for prompt answers only
Text string
History []string
Output []string
Flashes []Flash
// Blinky cursor variables.
cursor byte // cursor symbol
cursorFlip uint64 // ticks until cursor flip
cursorRate uint64
// Paging through history variables.
historyPaging bool
historyIndex int
// JavaScript shell interpreter.
js *otto.Otto
}
// Flash holds a message to flash on screen.
type Flash struct {
Text string
Expires uint64 // tick that it expires
}
// NewShell initializes the shell helper (the "Shellper").
func NewShell(d *Doodle) Shell {
s := Shell{
parent: d,
History: []string{},
Output: []string{},
Flashes: []Flash{},
Prompt: ">",
cursor: '_',
cursorRate: balance.ShellCursorBlinkRate,
js: otto.New(),
}
// Make the Doodle instance available to the shell.
bindings := map[string]interface{}{
"d": d,
"log": log,
"RGBA": render.RGBA,
"Point": render.NewPoint,
"Rect": render.NewRect,
}
for name, v := range bindings {
err := s.js.Set(name, v)
if err != nil {
log.Error("Failed to make `%s` available to JS shell: %s", name, err)
}
}
return s
}
// Close the shell, resetting its internal state.
func (s *Shell) Close() {
log.Debug("Shell: closing shell")
s.Open = false
s.Prompt = ">"
s.callback = nil
s.Text = ""
s.historyPaging = false
s.historyIndex = 0
}
// Execute a command in the shell.
func (s *Shell) Execute(input string) {
command := s.Parse(input)
if command.Raw != "" {
s.Output = append(s.Output, s.Prompt+command.Raw)
s.History = append(s.History, command.Raw)
}
// Are we answering a Prompt?
if s.callback != nil {
log.Info("Invoking prompt callback:")
s.callback(command.Raw)
s.Close()
return
}
if command.Command == "clear" {
s.Output = []string{}
} else {
err := command.Run(s.parent)
if err != nil {
s.Write(err.Error())
}
}
// Reset the text buffer in the shell.
s.Text = ""
}
// Write a line of output text to the console.
func (s *Shell) Write(line string) {
s.Output = append(s.Output, line)
s.Flashes = append(s.Flashes, Flash{
Text: line,
Expires: s.parent.ticks + balance.FlashTTL,
})
}
// Parse the command line.
func (s *Shell) Parse(input string) Command {
input = strings.TrimSpace(input)
if len(input) == 0 {
return Command{}
}
var (
inQuote bool
buffer = bytes.NewBuffer([]byte{})
words = []string{}
)
for i := 0; i < len(input); i++ {
char := input[i]
switch char {
case ' ':
if inQuote {
buffer.WriteByte(char)
continue
}
if word := buffer.String(); word != "" {
words = append(words, word)
buffer.Reset()
}
case '"':
if !inQuote {
// An opening quote character.
inQuote = true
} else {
// The closing quote.
inQuote = false
if word := buffer.String(); word != "" {
words = append(words, word)
buffer.Reset()
}
}
default:
buffer.WriteByte(char)
}
}
if remainder := buffer.String(); remainder != "" {
words = append(words, remainder)
}
return Command{
Raw: input,
Command: words[0],
Args: words[1:],
ArgsLiteral: strings.TrimSpace(input[len(words[0]):]),
}
}
// Draw the shell.
func (s *Shell) Draw(d *Doodle, ev *events.State) error {
if ev.EscapeKey.Read() {
s.Close()
return nil
} else if ev.EnterKey.Read() || ev.EscapeKey.Read() {
s.Execute(s.Text)
s.Close()
return nil
} else if (ev.Up.Now || ev.Down.Now) && len(s.History) > 0 {
// Paging through history.
if !s.historyPaging {
s.historyPaging = true
s.historyIndex = len(s.History)
}
// Consume the inputs and make convenient variables.
ev.Down.Read()
isUp := ev.Up.Read()
// Scroll through the input history.
if isUp {
s.historyIndex--
if s.historyIndex < 0 {
s.historyIndex = 0
}
} else {
s.historyIndex++
if s.historyIndex >= len(s.History) {
s.historyIndex = len(s.History) - 1
}
}
s.Text = s.History[s.historyIndex]
}
// Compute the line height we can draw.
lineHeight := balance.ShellFontSize + int(balance.ShellPadding)
// If the console is open, draw the console.
if s.Open {
// Cursor flip?
if d.ticks > s.cursorFlip {
s.cursorFlip = d.ticks + s.cursorRate
if s.cursor == ' ' {
s.cursor = '_'
} else {
s.cursor = ' '
}
}
// Read a character from the keyboard.
if key := ev.ReadKey(); key != "" {
// Backspace?
if key == `\b` {
if len(s.Text) > 0 {
s.Text = s.Text[:len(s.Text)-1]
}
} else {
s.Text += key
}
}
// How tall is the box?
boxHeight := int32(lineHeight*(balance.ShellHistoryLineCount+1)) + balance.ShellPadding
// Draw the background color.
d.Engine.DrawBox(
balance.ShellBackgroundColor,
render.Rect{
X: 0,
Y: d.height - boxHeight,
W: d.width,
H: boxHeight,
},
)
// Draw the recent commands.
outputY := d.height - int32(lineHeight*2)
for i := 0; i < balance.ShellHistoryLineCount; i++ {
if len(s.Output) > i {
line := s.Output[len(s.Output)-1-i]
d.Engine.DrawText(
render.Text{
FontFilename: balance.ShellFontFilename,
Text: line,
Size: balance.ShellFontSize,
Color: balance.ShellForegroundColor,
},
render.Point{
X: balance.ShellPadding,
Y: outputY,
},
)
}
outputY -= int32(lineHeight)
}
// Draw the command prompt.
d.Engine.DrawText(
render.Text{
FontFilename: balance.ShellFontFilename,
Text: s.Prompt + s.Text + string(s.cursor),
Size: balance.ShellFontSize,
Color: balance.ShellPromptColor,
},
render.Point{
X: balance.ShellPadding,
Y: d.height - int32(balance.ShellFontSize) - balance.ShellPadding,
},
)
} else if len(s.Flashes) > 0 {
// Otherwise, just draw flashed messages.
valid := false // Did we actually draw any?
outputY := d.height - int32(lineHeight*2)
for i := len(s.Flashes); i > 0; i-- {
flash := s.Flashes[i-1]
if d.ticks >= flash.Expires {
continue
}
d.Engine.DrawText(
render.Text{
Text: flash.Text,
Size: balance.ShellFontSize,
Color: render.SkyBlue,
Stroke: render.Grey,
Shadow: render.Black,
},
render.Point{
X: balance.ShellPadding,
Y: outputY,
},
)
outputY -= int32(lineHeight)
valid = true
}
// If we've exhausted all flashes, free up the memory.
if !valid {
s.Flashes = []Flash{}
}
}
return nil
}