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2 Commits

Author SHA1 Message Date
ae12084dee Fix angle problems in Root importer 2023-09-30 12:51:11 +03:00
92bfb173d8 minor fix to Root rotations 2023-09-16 12:27:09 +03:00
8 changed files with 99 additions and 60 deletions

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@ -42,7 +42,7 @@ public open class DObject(public val meta: Meta, public val refCache: DObjectCac
}
internal fun <T : DObject> tObjectArray(
builder: (Meta, DObjectCache) -> T
builder: (Meta, DObjectCache) -> T,
): ReadOnlyProperty<Any?, List<T>> = ReadOnlyProperty { _, property ->
meta.getIndexed(Name.of(property.name, "arr")).values.mapNotNull {
resolve(builder, it)
@ -51,9 +51,9 @@ public open class DObject(public val meta: Meta, public val refCache: DObjectCac
internal fun <T : DObject> dObject(
builder: (Meta, DObjectCache) -> T,
key: Name? = null
key: Name? = null,
): ReadOnlyProperty<Any?, T?> = ReadOnlyProperty { _, property ->
meta[key ?: property.name.asName()]?.let { resolve(builder, it) }
meta[key ?: property.name.asName()]?.takeIf { it.value != Null }?.let { resolve(builder, it) }
}
}
@ -62,8 +62,7 @@ public open class DNamed(meta: Meta, refCache: DObjectCache) : DObject(meta, ref
public val fTitle: String by meta.string("")
}
public class DGeoMaterial(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCache) {
}
public class DGeoMaterial(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCache)
public class DGeoMedium(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCache) {
public val fMaterial: DGeoMaterial? by dObject(::DGeoMaterial)
@ -90,27 +89,69 @@ public class DGeoNode(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCach
public val fVolume: DGeoVolume? by dObject(::DGeoVolume)
}
public open class DGeoMatrix(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCache)
public sealed class DGeoMatrix(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCache)
public open class DGeoScale(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache) {
public class DGeoIdentity(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache)
public class DGeoScale(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache) {
public val fScale: DoubleArray by meta.doubleArray(1.0, 1.0, 1.0)
public val x: Double get() = fScale[0]
public val y: Double get() = fScale[1]
public val z: Double get() = fScale[2]
}
public class DGeoRotation(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache) {
public val fRotationMatrix: DoubleArray by meta.doubleArray()
}
public class DGeoTranslation(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache) {
public val fTranslation: DoubleArray by meta.doubleArray()
}
public open class DGeoCombiTrans(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache) {
public val fRotation: DGeoRotation? by dObject(::DGeoRotation)
public val fTranslation: DoubleArray by meta.doubleArray()
}
public class DGeoGenTrans(meta: Meta, refCache: DObjectCache) : DGeoCombiTrans(meta, refCache) {
public val fScale: DoubleArray by meta.doubleArray()
}
public class DGeoHMatrix(meta: Meta, refCache: DObjectCache) : DGeoMatrix(meta, refCache) {
public val fRotation: DGeoRotation? by dObject(::DGeoRotation)
public val fTranslation: DoubleArray by meta.doubleArray()
public val fScale: DoubleArray by meta.doubleArray()
}
/**
* Create a specialized version of [DGeoMatrix]
*/
internal fun dGeoMatrix(
meta: Meta,
refCache: DObjectCache,
): DGeoMatrix = when (val typename = meta["_typename"].string) {
null -> error("Type name is undefined")
"TGeoIdentity" -> DGeoIdentity(meta, refCache)
"TGeoScale" -> DGeoScale(meta, refCache)
"TGeoRotation" -> DGeoRotation(meta, refCache)
"TGeoTranslation" -> DGeoTranslation(meta, refCache)
"TGeoCombiTrans" -> DGeoCombiTrans(meta, refCache)
"TGeoGenTrans" -> DGeoGenTrans(meta, refCache)
"TGeoHMatrix" -> DGeoHMatrix(meta, refCache)
else -> error("$typename is not a member of TGeoMatrix")
}
public class DGeoBoolNode(meta: Meta, refCache: DObjectCache) : DObject(meta, refCache) {
public val fLeft: DGeoShape? by dObject(::DGeoShape)
public val fLeftMat: DGeoMatrix? by dObject(::DGeoMatrix)
public val fLeftMat: DGeoMatrix? by dObject(::dGeoMatrix)
public val fRight: DGeoShape? by dObject(::DGeoShape)
public val fRightMat: DGeoMatrix? by dObject(::DGeoMatrix)
public val fRightMat: DGeoMatrix? by dObject(::dGeoMatrix)
}
public class DGeoManager(meta: Meta, refCache: DObjectCache) : DNamed(meta, refCache) {
public val fMatrices: List<DGeoMatrix> by tObjectArray(::DGeoMatrix)
public val fMatrices: List<DGeoMatrix> by tObjectArray(::dGeoMatrix)
public val fShapes: List<DGeoShape> by tObjectArray(::DGeoShape)

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@ -1,16 +1,23 @@
package ru.mipt.npm.root
import space.kscience.dataforge.meta.*
import space.kscience.dataforge.meta.Meta
import space.kscience.dataforge.meta.double
import space.kscience.dataforge.meta.int
import space.kscience.dataforge.names.Name
import space.kscience.dataforge.names.parseAsName
import space.kscience.dataforge.names.plus
import space.kscience.dataforge.names.withIndex
import space.kscience.kmath.complex.Quaternion
import space.kscience.kmath.geometry.fromRotationMatrix
import space.kscience.kmath.linear.VirtualMatrix
import space.kscience.visionforge.MutableVisionContainer
import space.kscience.visionforge.isEmpty
import space.kscience.visionforge.set
import space.kscience.visionforge.solid.*
import space.kscience.visionforge.solid.SolidMaterial.Companion.MATERIAL_COLOR_KEY
import kotlin.math.*
import kotlin.math.PI
import kotlin.math.cos
import kotlin.math.sin
private val volumesName = Name.EMPTY //"volumes".asName()
@ -28,12 +35,10 @@ private data class RootToSolidContext(
val colorCache: MutableMap<Meta, String> = mutableMapOf(),
)
// converting to XYZ to TaitBryan angles according to https://en.wikipedia.org/wiki/Euler_angles#Rotation_matrix
// apply rotation from a matrix
private fun Solid.rotate(rot: DoubleArray) {
val xAngle = atan2(-rot[5], rot[8])
val yAngle = atan2(rot[2], sqrt(1.0 - rot[2].pow(2)))
val zAngle = atan2(-rot[1], rot[0])
rotation = Float32Vector3D(xAngle, yAngle, zAngle)
val matrix = VirtualMatrix(3, 3) { i, j -> rot[i * 3 + j] }
quaternion = Quaternion.fromRotationMatrix(matrix)
}
private fun Solid.translate(trans: DoubleArray) {
@ -41,39 +46,32 @@ private fun Solid.translate(trans: DoubleArray) {
position = Float32Vector3D(x, y, z)
}
private fun Solid.useMatrix(matrix: DGeoMatrix?) {
if (matrix == null) return
when (matrix.typename) {
"TGeoIdentity" -> {
//do nothing
private fun Solid.scale(s: DoubleArray) {
scale = Float32Vector3D(s[0], s[1], s[2])
}
"TGeoTranslation" -> {
val fTranslation by matrix.meta.doubleArray()
translate(fTranslation)
private fun Solid.useMatrix(matrix: DGeoMatrix?): Unit {
when (matrix) {
null -> {}
is DGeoIdentity -> {}
is DGeoTranslation -> translate(matrix.fTranslation)
is DGeoRotation -> rotate(matrix.fRotationMatrix)
is DGeoScale -> scale(matrix.fScale)
is DGeoGenTrans -> {
translate(matrix.fTranslation)
matrix.fRotation?.fRotationMatrix?.let { rotate(it) }
scale(matrix.fScale)
}
"TGeoRotation" -> {
val fRotationMatrix by matrix.meta.doubleArray()
rotate(fRotationMatrix)
is DGeoCombiTrans -> {
translate(matrix.fTranslation)
matrix.fRotation?.fRotationMatrix?.let { rotate(it) }
}
"TGeoCombiTrans" -> {
val fTranslation by matrix.meta.doubleArray()
translate(fTranslation)
matrix.meta["fRotation.fRotationMatrix"]?.value?.let {
rotate(it.doubleArray)
}
}
"TGeoHMatrix" -> {
val fTranslation by matrix.meta.doubleArray()
val fRotationMatrix by matrix.meta.doubleArray()
val fScale by matrix.meta.doubleArray()
translate(fTranslation)
rotate(fRotationMatrix)
scale = Float32Vector3D(fScale[0], fScale[1], fScale[2])
is DGeoHMatrix -> {
translate(matrix.fTranslation)
matrix.fRotation?.fRotationMatrix?.let { rotate(it) }
scale(matrix.fScale)
}
}
}
@ -96,10 +94,10 @@ private fun SolidGroup.addShape(
}
smartComposite(compositeType, name = name) {
addShape(node.fLeft!!, context, null) {
this.useMatrix(node.fLeftMat)
useMatrix(node.fLeftMat)
}
addShape(node.fRight!!, context, null) {
this.useMatrix(node.fRightMat)
useMatrix(node.fRightMat)
}
}.apply(block)
}
@ -283,7 +281,7 @@ private fun SolidGroup.addRootNode(obj: DGeoNode, context: RootToSolidContext) {
addRootVolume(volume, context, obj.fName) {
when (obj.typename) {
"TGeoNodeMatrix" -> {
val fMatrix by obj.dObject(::DGeoMatrix)
val fMatrix by obj.dObject(::dGeoMatrix)
this.useMatrix(fMatrix)
}

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@ -15,13 +15,13 @@ import kotlin.math.sin
fun main() = serve {
val azimuth = 60.degrees
val inclination = 15.degrees
// val azimuth = 60.degrees
// val inclination = 15.degrees
val direction = with(QuaternionField) {
Quaternion.fromRotation(-azimuth, Euclidean3DSpace.zAxis) *
Quaternion.fromRotation(Angle.piDiv2 - inclination, Euclidean3DSpace.yAxis)
}
// val direction = with(QuaternionField) {
// Quaternion.fromRotation(-azimuth, Euclidean3DSpace.zAxis) *
// Quaternion.fromRotation(Angle.piDiv2 - inclination, Euclidean3DSpace.yAxis)
// }
//val direction2 = Quaternion.fromEuler(Angle.zero, Angle.piDiv2 - inclination, -azimuth, RotationOrder.ZYX)
@ -43,7 +43,7 @@ fun main() = serve {
solidGroup("frame") {
z = 60
val antenna = solidGroup("antenna") {
solidGroup("antenna") {
axes(200)
tube(40, 10, 30)
sphereLayer(100, 95, theta = PI / 6) {

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@ -206,7 +206,7 @@ public var Solid.rotationZ: Number by float(Z_ROTATION_KEY, 0f)
/**
* Raw quaternion value defined in properties
*/
public var Solid.quaternionValue: Quaternion?
public var Solid.quaternionOrNull: Quaternion?
get() = properties.getValue(ROTATION_KEY)?.list?.let {
require(it.size == 4) { "Quaternion must be a number array of 4 elements" }
Quaternion(it[0].float, it[1].float, it[2].float, it[3].float)
@ -229,14 +229,14 @@ public var Solid.quaternionValue: Quaternion?
* Quaternion value including information from euler angles
*/
public var Solid.quaternion: Quaternion
get() = quaternionValue ?: Quaternion.fromEuler(
get() = quaternionOrNull ?: Quaternion.fromEuler(
rotationX.radians,
rotationY.radians,
rotationZ.radians,
rotationOrder
)
set(value) {
quaternionValue = value
quaternionOrNull = value
}
public var Solid.scaleX: Number by float(X_SCALE_KEY, 1f)

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@ -41,7 +41,7 @@ public fun Object3D.updatePosition(vision: Vision) {
if (vision is Solid) {
position.set(vision.x, vision.y, vision.z)
val quaternion = vision.quaternionValue
val quaternion = vision.quaternionOrNull
if (quaternion != null) {
setRotationFromQuaternion(