Эта страница переведена с помощью Cloud Translation API.

Государственная консервация и постоянное хранение

Сохранение состояния и постоянное хранение данных — нетривиальные аспекты приложений для рисования от руки, особенно в Compose. Основные объекты данных, такие как свойства кисти и точки, формирующие обводку, сложны и не сохраняются автоматически. Это требует продуманной стратегии сохранения состояния в таких сценариях, как изменение конфигурации и постоянное сохранение рисунков пользователя в базе данных.

State preservation

In Jetpack Compose, UI state is typically managed using remember and rememberSaveable. While rememberSaveable offers automatic state preservation across configuration changes, its built-in capabilities are limited to primitive data types and objects that implement Parcelable or Serializable.

For custom objects that contain complex properties, such as Brush, you must define explicit serialization and deserialization mechanisms using a custom state saver. By defining a custom Saver for the Brush object, you can preserve the brush's essential attributes when configuration changes occur, as shown in the following brushStateSaver example.

fun brushStateSaver(converters: Converters): Saver<MutableState<Brush>, SerializedBrush> = Saver(
    save = { converters.serializeBrush(it.value) },
    restore = { mutableStateOf(converters.deserializeBrush(it)) },
)

You can then use the custom Saver to preserve the selected brush state:

val currentBrush = rememberSaveable(saver = brushStateSaver(Converters())) { mutableStateOf(defaultBrush) }

Постоянное хранение

To enable features such as document saving, loading, and potential real-time collaboration, store strokes and associated data in a serialized format. For the Ink API, manual serialization and deserialization are necessary.

To accurately restore a stroke, save its Brush and StrokeInputBatch.

Brush: Includes numeric fields (size, epsilon), color, and BrushFamily.
StrokeInputBatch: A list of input points with numeric fields.

The Storage module simplifies compactly serializing the most complex part: the StrokeInputBatch.

To save a stroke:

Serialize the StrokeInputBatch using the storage module's encode function. Store the resulting binary data.
Separately save the essential properties of the stroke's Brush:
- The enum that represents the brush family &mdash Although the instance can be serialized, this is not efficient for apps that use a limited selection of brush families
- colorLong
- size
- epsilon

fun serializeStroke(stroke: Stroke): SerializedStroke {
  val serializedBrush = serializeBrush(stroke.brush)
  val encodedSerializedInputs = ByteArrayOutputStream().use
    {
      stroke.inputs.encode(it)
      it.toByteArray()
    }

  return SerializedStroke(
    inputs = encodedSerializedInputs,
    brush = serializedBrush
  )
}

To load a stroke object:

Retrieve the saved binary data for the StrokeInputBatch and deserialize it using the storage module's decode() function.
Retrieve the saved Brush properties and create the brush.

Create the final stroke using the recreated brush and the deserialized StrokeInputBatch.

fun deserializeStroke(serializedStroke: SerializedStroke): Stroke {
  val inputs = ByteArrayInputStream(serializedStroke.inputs).use {
    StrokeInputBatch.decode(it)
  }
  val brush = deserializeBrush(serializedStroke.brush)
  return Stroke(brush = brush, inputs = inputs)
}

Handle zoom, pan, and rotation

If your app supports zooming, panning, or rotation, you must provide the current transformation to InProgressStrokes. This helps newly drawn strokes match the position and scale of your existing strokes.

You do this by passing a Matrix to the pointerEventToWorldTransform parameter. The matrix should represent the inverse of the transformation you apply to your finished strokes canvas.

@Composable
fun ZoomableDrawingScreen(...) {
    // 1. Manage your zoom/pan state (e.g., using detectTransformGestures).
    var zoom by remember { mutableStateOf(1f) }
    var pan by remember { mutableStateOf(Offset.Zero) }

    // 2. Create the Matrix.
    val pointerEventToWorldTransform = remember(zoom, pan) {
        android.graphics.Matrix().apply {
            // Apply the inverse of your rendering transforms
            postTranslate(-pan.x, -pan.y)
            postScale(1 / zoom, 1 / zoom)
        }
    }

    Box(modifier = Modifier.fillMaxSize()) {
        // ...Your finished strokes Canvas, with regular transform applied

        // 3. Pass the matrix to InProgressStrokes.
        InProgressStrokes(
            modifier = Modifier.fillMaxSize(),
            pointerEventToWorldTransform = pointerEventToWorldTransform,
            defaultBrush = currentBrush,
            nextBrush = onGetNextBrush,
            onStrokesFinished = onStrokesFinished
        )
    }
}

Export strokes

Возможно, вам потребуется экспортировать сцену с контурами в виде статического графического файла. Это полезно для обмена рисунком с другими приложениями, создания эскизов или сохранения окончательной, не подлежащей редактированию версии содержимого.

Для экспорта сцены вы можете отрисовывать свои линии на внеэкранном растровом изображении вместо того, чтобы выводить их непосредственно на экран. Используйте Android's Picture API , который позволяет записывать рисунки на холсте без необходимости использования видимого компонента пользовательского интерфейса.

Процесс включает в себя создание экземпляра Picture , вызов beginRecording() для получения Canvas , а затем использование существующего CanvasStrokeRenderer для отрисовки каждого штриха на этом Canvas . После записи всех команд рисования вы можете использовать Picture для создания Bitmap , который затем можно сжать и сохранить в файл.

fun exportDocumentAsImage() {
  val picture = Picture()
  val canvas = picture.beginRecording(bitmapWidth, bitmapHeight)

  // The following is similar logic that you'd use in your custom View.onDraw or Compose Canvas.
  for (item in myDocument) {
    when (item) {
      is Stroke -> {
        canvasStrokeRenderer.draw(canvas, stroke, worldToScreenTransform)
      }
      // Draw your other types of items to the canvas.
    }
  }

  // Create a Bitmap from the Picture and write it to a file.
  val bitmap = Bitmap.createBitmap(picture)
  val outstream = FileOutputStream(filename)
  bitmap.compress(Bitmap.CompressFormat.PNG, 100, outstream)
}

Data object and converter helpers

Define a serialization object structure that mirrors needed Ink API objects.

Use the Ink API's storage module to encode and decode StrokeInputBatch.

Data transfer objects

@Parcelize
@Serializable
data class SerializedStroke(
  val inputs: ByteArray,
  val brush: SerializedBrush
) : Parcelable {
  override fun equals(other: Any?): Boolean {
    if (this === other) return true
    if (other !is SerializedStroke) return false
    if (!inputs.contentEquals(other.inputs)) return false
    if (brush != other.brush) return false
    return true
  }

  override fun hashCode(): Int {
    var result = inputs.contentHashCode()
    result = 31 * result + brush.hashCode()
    return result
  }
}

@Parcelize
@Serializable
data class SerializedBrush(
  val size: Float,
  val color: Long,
  val epsilon: Float,
  val stockBrush: SerializedStockBrush,
  val clientBrushFamilyId: String? = null
) : Parcelable

enum class SerializedStockBrush {
  Marker,
  PressurePen,
  Highlighter,
  DashedLine,
}

Converters

object Converters {
  private val stockBrushToEnumValues = mapOf(
    StockBrushes.marker() to SerializedStockBrush.Marker,
    StockBrushes.pressurePen() to SerializedStockBrush.PressurePen,
    StockBrushes.highlighter() to SerializedStockBrush.Highlighter,
    StockBrushes.dashedLine() to SerializedStockBrush.DashedLine,
  )

  private val enumToStockBrush =
    stockBrushToEnumValues.entries.associate { (key, value) -> value to key
  }

  private fun serializeBrush(brush: Brush): SerializedBrush {
    return SerializedBrush(
      size = brush.size,
      color = brush.colorLong,
      epsilon = brush.epsilon,
      stockBrush = stockBrushToEnumValues[brush.family] ?: SerializedStockBrush.Marker,
    )
  }

  fun serializeStroke(stroke: Stroke): SerializedStroke {
    val serializedBrush = serializeBrush(stroke.brush)
    val encodedSerializedInputs = ByteArrayOutputStream().use { outputStream ->
      stroke.inputs.encode(outputStream)
      outputStream.toByteArray()
    }

    return SerializedStroke(
      inputs = encodedSerializedInputs,
      brush = serializedBrush
    )
  }

  private fun deserializeStroke(
    serializedStroke: SerializedStroke,
  ): Stroke? {
    val inputs = ByteArrayInputStream(serializedStroke.inputs).use { inputStream ->
        StrokeInputBatch.decode(inputStream)
    }
    val brush = deserializeBrush(serializedStroke.brush, customBrushes)
    return Stroke(brush = brush, inputs = inputs)
  }

  private fun deserializeBrush(
    serializedBrush: SerializedBrush,
  ): Brush {
    val stockBrushFamily = enumToStockBrush[serializedBrush.stockBrush]
    val brushFamily = customBrush?.brushFamily ?: stockBrushFamily ?: StockBrushes.marker()

    return Brush.createWithColorLong(
      family = brushFamily,
      colorLong = serializedBrush.color,
      size = serializedBrush.size,
      epsilon = serializedBrush.epsilon,
    )
  }
}

Создавайте интерактивные инструменты с помощью API Geometry.

Выберите эпсилон и систему координат.