public void StringInterop()
{
var v = new float3(2f, 7.5f, -8.5f);
var s0 = v.ToString();
var s1 = v.ToString("#");
var v0 = float3.Parse(s0);
var v1 = float3.Parse(s1, "#");
Assert.AreEqual(v, v0);
Assert.AreEqual(v, v1);
var b0 = float3.TryParse(s0, out v0);
var b1 = float3.TryParse(s1, "#", out v1);
Assert.That(b0);
Assert.That(b1);
Assert.AreEqual(v, v0);
Assert.AreEqual(v, v1);
b0 = float3.TryParse(null, out v0);
Assert.False(b0);
b0 = float3.TryParse("", out v0);
Assert.False(b0);
b0 = float3.TryParse(s0 + ", 0", out v0);
Assert.False(b0);
Assert.Throws <NullReferenceException>(() => { float3.Parse(null); });
Assert.Throws <FormatException>(() => { float3.Parse(""); });
Assert.Throws <FormatException>(() => { float3.Parse(s0 + ", 0"); });
var s2 = v.ToString(";", CultureInfo.InvariantCulture);
Assert.That(s2.Length > 0);
var s3 = v.ToString("; ", "G");
var s4 = v.ToString("; ", "G", CultureInfo.InvariantCulture);
var v3 = float3.Parse(s3, "; ", NumberStyles.Number);
var v4 = float3.Parse(s4, "; ", NumberStyles.Number, CultureInfo.InvariantCulture);
Assert.AreEqual(v, v3);
Assert.AreEqual(v, v4);
var b4 = float3.TryParse(s4, "; ", NumberStyles.Number, CultureInfo.InvariantCulture, out v4);
Assert.That(b4);
Assert.AreEqual(v, v4);
}
public void ToString_CultureDE()
{
string s = "(1,5; 1,5; 1,5)";
float3 f = float3.One * 1.5f;
Assert.Equal(s, f.ToString(new CultureInfo("de-DE")));
}
public override string ToString()
{
string a = Origin.ToString();
string b = Direction.ToString();
return("p" + a + " + t * " + b);
}
protected override void OnCommonUpdate()
{
base.OnCommonUpdate();
if (this.LocalUser.UserID == "U-guillefix")
{
UniLog.Log("Update");
if (record_skeleton)
{
foreach (var item in joint_slots)
{
User user = item.Key;
List <Slot> slots = item.Value;
Slot root_slot = slots[0];
float3 root_global_position = root_slot.GlobalPosition;
floatQ root_global_rotation = root_slot.GlobalRotation;
output_file.Write(root_global_position.ToString() + "," + root_global_rotation.ToString());
for (int i = 1; i < slots.Count; i++)
{
Slot slot = slots[i];
float3 global_position = slot.GlobalPosition;
floatQ global_rotation = slot.GlobalRotation;
float3 relative_position = root_slot.GlobalPointToLocal(global_position);
floatQ relative_rotation = root_slot.GlobalRotationToLocal(global_rotation);
output_file.Write("," + relative_position.ToString() + "," + relative_rotation.ToString());
}
output_file.Write("\n");
}
}
}
}
public void ToString_InvariantCulture()
{
string s = "(1.5, 1.5, 1.5)";
float3 f = float3.One * 1.5f;
Assert.Equal(s, f.ToString(CultureInfo.InvariantCulture));
}
public void Float3_WriteToString(float v0, float v1, float v2)
{
string s = NormalFormat.F(v0, v1, v2);
float3 n = new float3(v0, v1, v2);
string sn = n.ToString();
Assert.That(sn, Is.EqualTo(s));
}
public void ConvertFromFloat3(int i, float f, double d, bool isTrue, string text, double2 d2, double3 d3, double4 d4, double4x4 d4x4, float2 f2, float3 f3, float4 f4, float4x4 f4x4)
{
text = f3.ToString();
ConverterClass source = new ConverterClass();
ConverterClass expected = new ConverterClass();
Node root = new Node(source);
Node node = new Node(expected);
Circuit circuit = new Circuit();
circuit.AddNode(root);
circuit.AddNode(node);
circuit.AddRoot(root);
source.f3 = f3;
root.Attach("f3", node, "i");
root.Attach("f3", node, "f");
root.Attach("f3", node, "d");
root.Attach("f3", node, "isTrue");
root.Attach("f3", node, "text");
root.Attach("f3", node, "d2");
root.Attach("f3", node, "d3");
root.Attach("f3", node, "d4");
root.Attach("f3", node, "d4x4");
root.Attach("f3", node, "f2");
root.Attach("f3", node, "f3");
root.Attach("f3", node, "f4");
root.Attach("f3", node, "f4x4");
circuit.Execute();
Assert.True(expected.i == i, "Error when parsing to int: Should be " + i + " but is " + expected.i + ".");
Assert.True(expected.f == f, "Error when parsing to float: Should be " + f + " but is " + expected.f + ".");
Assert.True(expected.d == d, "Error when parsing to double: Should be " + d + " but is " + expected.d + ".");
Assert.True(expected.isTrue == isTrue, "Error when parsing to bool: Should be " + isTrue + " but is " + expected.isTrue + ".");
Assert.True(expected.text == text, "Error when parsing to string: Should be " + text + " but is " + expected.text + ".");
Assert.True(expected.d2 == d2, "Error when parsing to double2: Should be " + d2 + " but is " + expected.d2 + ".");
Assert.True(expected.d3 == d3, "Error when parsing to double3: Should be " + d3 + " but is " + expected.d3 + ".");
Assert.True(expected.d4 == d4, "Error when parsing to double4: Should be " + d4 + " but is " + expected.d4 + ".");
Assert.True(expected.d4x4 == d4x4, "Error when parsing to double4x4: Should be " + d4x4 + " but is " + expected.d4x4 + ".");
Assert.True(expected.f2 == f2, "Error when parsing to float2: Should be " + f2 + " but is " + expected.f2 + ".");
Assert.True(expected.f3 == f3, "Error when parsing to float3: Should be " + f3 + " but is " + expected.f3 + ".");
Assert.True(expected.f4 == f4, "Error when parsing to float4: Should be " + f4 + " but is " + expected.f4 + ".");
Assert.True(expected.f4x4 == f4x4, "Error when parsing to float4x4: Should be " + f4x4 + " but is " + expected.f4x4 + ".");
}
private void SpawnWorld(int id, float3 spawnPosition, MapDatam map, Entity gameEntity)
{
if (map != null)
{
Entity world = World.EntityManager.CreateEntity(worldArchtype);
worlds.Add(id, world);
worldLookups.Add(id, new WorldChunkMap {
chunks = new Dictionary <int3, Entity>()
});
World.EntityManager.SetComponentData(world, new Translation {
Value = spawnPosition
});
UpdateMap(world, map, id);
Game game = World.EntityManager.GetComponentData <Game>(gameEntity);
game.map = world;
World.EntityManager.SetComponentData(gameEntity, game);
}
else
{
Debug.LogError("Cannot spawn world at: " + spawnPosition.ToString() + " as map is null.");
}
}
/// <summary> /// Returns a string representation of this vector using a provided seperator. /// </summary> public static string ToString(float3 v, string sep) => v.ToString(sep);
/// <summary> /// Returns a string representation of this vector using ', ' as a seperator. /// </summary> public static string ToString(float3 v) => v.ToString();
public static void SetEnviromentEntityData(EntityManager entityManager, GameObject go, NativeArray <Entity> entities,
NativeArray <Bounds> entitiesToAviod, bool disposeOnCompletion, string region, string name, float3 entitySize, float3 center, float3 bounds)
{
Unity.Mathematics.Random rand = new Unity.Mathematics.Random(0x6E624EB7u);
float3 newPosition;
Debug.Log("entitySize = " + entitySize);
for (int i = 0; i < entities.Length; i++)
{
switch (name)
{
case "Tree":
center.y = 0; // bounds -= entitySize;
bool overlap = false;
float3 scale = go.GetComponent <Transform>().localScale;
Bounds _bounds = go.GetComponent <MeshFilter>().sharedMesh.bounds;
Debug.Log("Tree stuff = " + scale.ToString() + "," + _bounds.ToString() + "," + (_bounds.size * scale));
int attempt = 0;
while (true)
{
newPosition = center + rand.NextFloat3(-bounds / 2, bounds / 2);
newPosition.y = -0.1f; //spawning on flat land for now
for (int j = 0; j < i; j++)
{
float3 entityPosition = entityManager.GetComponentData <Translation>(entities[j]).Value;
//Note that this treats the coreData position and size as cube which may not be tree for all entities (we just want the AABBs)
Bounds a = new Bounds(newPosition, _bounds.size * scale);
if (!a.Intersects(new Bounds(entityPosition, _bounds.size * scale)))
{
if (entitiesToAviod.Length > 0 && !entitiesToAviod[0].size.Equals(new float3(-1f, -1f, -1f)))
{
for (int k = 0; k < entitiesToAviod.Length; k++)
{
if (a.Intersects(entitiesToAviod[k]))
{
Debug.LogWarning("AAA");
overlap = true;
break;
}
}
}
else
{
Debug.LogWarning("No entities to compare");
}
}
else
{
Debug.LogWarning("B");
overlap = true;
break;
}
}
if (!overlap)
{
break;
}
else
{
attempt++;
}
if (attempt == 50)
{
Debug.LogWarning("Failed to create entity " + i + " for Tree");
break;
}
else
{
overlap = false;
}
}
if (!overlap)
{
entityManager.SetComponentData(entities[i], new Translation {
Value = newPosition
});
entityManager.SetComponentData(entities[i], new Scale {
Value = scale.x
});
entityManager.SetSharedComponentData(entities[i], new RenderMesh
{
mesh = go.GetComponent <MeshFilter>().sharedMesh,
castShadows = UnityEngine.Rendering.ShadowCastingMode.On,
material = go.GetComponent <MeshRenderer>().sharedMaterial,
receiveShadows = true
});
entityManager.SetComponentData(entities[i], GetEnviromentPhysicsCollider(region + "|" + name, scale.x));
entityManager.SetName(entities[i], region + "|" + name + i);
entityManager.SetComponentData(entities[i], new CoreData(new ByteString30(name), new ByteString30(region), bounds, scale));
}
break;
default:
Debug.LogWarning("Failed to set data for entity with name \"" + region + "|" + name + "\"");
break;
}
}
if (disposeOnCompletion)
{
entitiesToAviod.Dispose();
}
}
public override string ToString()
{
return(Values.ToString());
}
public void Parse_ToString_CultureDE()
{
float3 f = float3.One * 1.5f;
Assert.Equal(f, float3.Parse(f.ToString(new CultureInfo("de-DE")), new CultureInfo("de-DE")));
}
public override string ToString()
{
return(string30.ToString() + " | " + _float3.ToString());
}
/// <summary> /// Returns a string representation of this vector using a provided seperator and a format for each component. /// </summary> public static string ToString(float3 v, string sep, string format) => v.ToString(sep, format);
public override string ToString()
{
return(_value.ToString());
}
public override string ToString()
{
return(string.Format(CultureInfo.CurrentCulture, "Minimum:{0} Maximum:{1}", min.ToString(), max.ToString()));
}
/// <summary> /// Returns a string representation of this vector using a provided seperator and a format and format provider for each component. /// </summary> public static string ToString(float3 v, string sep, string format, IFormatProvider provider) => v.ToString(sep, format, provider);
public void Parse_ToString_NoCulture()
{
float3 f = float3.One * 1.5f;
Assert.Equal(f, float3.Parse(f.ToString()));
}
public void Parse_ToString_InvariantCulture()
{
float3 f = float3.One * 1.5f;
Assert.Equal(f, float3.Parse(f.ToString(CultureInfo.InvariantCulture), CultureInfo.InvariantCulture));
}
private void CutBeam(int beamIndex, float3 cutOffPosition)
{
bool exceptionChecker = true;
for (int i = 0; i < _discreteBeams[beamIndex].movementCoordinates.Count; i++)
{
if (ChechTwofloat3sEqual(cutOffPosition, _discreteBeams[beamIndex].movementCoordinates[i]))
{
;
_discreteBeams[beamIndex] = _discreteBeams[beamIndex].CutBeam(i);
exceptionChecker = false;
break;
}
}
if (exceptionChecker)
{
throw new Exception("The point for cutoff was not found. The position is : " + cutOffPosition.ToString());
}
}
