Unity 机器学习代理工具包 (ML-Agents) 是一个开源项目,它使游戏和模拟能够作为训练智能代理的环境。
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299 行
12 KiB

using System;
using System.Collections.Generic;
using NUnit.Framework;
using UnityEngine;
namespace MLAgents.Tests
{
public class RayPerceptionSensorTests
{
[Test]
public void TestGetRayAngles()
{
var angles = RayPerceptionSensorComponentBase.GetRayAngles(3, 90f);
var expectedAngles = new[] { 90f, 60f, 120f, 30f, 150f, 0f, 180f };
Assert.AreEqual(expectedAngles.Length, angles.Length);
for (var i = 0; i < angles.Length; i++)
{
Assert.AreEqual(expectedAngles[i], angles[i], .01);
}
}
}
public class RayPerception3DTests
{
// Use built-in tags
const string k_CubeTag = "Player";
const string k_SphereTag = "Respawn";
void SetupScene()
{
/* Creates game objects in the world for testing.
* C is a cube
* S are spheres
* @ is the agent (at the origin)
* Each space or line is 5 world units, +x is right, +z is up
*
* C
* S S
* @
*
* S
*/
var cube = GameObject.CreatePrimitive(PrimitiveType.Cube);
cube.transform.position = new Vector3(0, 0, 10);
cube.tag = k_CubeTag;
var sphere1 = GameObject.CreatePrimitive(PrimitiveType.Sphere);
sphere1.transform.position = new Vector3(-5, 0, 5);
sphere1.tag = k_SphereTag;
var sphere2 = GameObject.CreatePrimitive(PrimitiveType.Sphere);
sphere2.transform.position = new Vector3(5, 0, 5);
// No tag for sphere2
var sphere3 = GameObject.CreatePrimitive(PrimitiveType.Sphere);
sphere3.transform.position = new Vector3(0, 0, -10);
sphere3.tag = k_SphereTag;
Physics.SyncTransforms();
}
[Test]
public void TestRaycasts()
{
SetupScene();
var obj = new GameObject("agent");
var perception = obj.AddComponent<RayPerceptionSensorComponent3D>();
perception.raysPerDirection = 1;
perception.maxRayDegrees = 45;
perception.rayLength = 20;
perception.detectableTags = new List<string>();
perception.detectableTags.Add(k_CubeTag);
perception.detectableTags.Add(k_SphereTag);
var radii = new[] { 0f, .5f };
foreach (var castRadius in radii)
{
perception.sphereCastRadius = castRadius;
var sensor = perception.CreateSensor();
var expectedObs = (2 * perception.raysPerDirection + 1) * (perception.detectableTags.Count + 2);
Assert.AreEqual(sensor.GetObservationShape()[0], expectedObs);
var outputBuffer = new float[expectedObs];
WriteAdapter writer = new WriteAdapter();
writer.SetTarget(outputBuffer, sensor.GetObservationShape(), 0);
var numWritten = sensor.Write(writer);
Assert.AreEqual(numWritten, expectedObs);
// Expected hits:
// ray 0 should hit the cube at roughly halfway
// ray 1 should hit a sphere but no tag
// ray 2 should hit a sphere with the k_SphereTag tag
// The hit fraction should be the same for rays 1 and
//
Assert.AreEqual(1.0f, outputBuffer[0]); // hit cube
Assert.AreEqual(0.0f, outputBuffer[1]); // missed sphere
Assert.AreEqual(0.0f, outputBuffer[2]); // missed unknown tag
// Hit is at z=9.0 in world space, ray length is 20
Assert.That(
outputBuffer[3], Is.EqualTo((9.5f - castRadius) / perception.rayLength).Within(.0005f)
);
// Spheres are at 5,0,5 and 5,0,-5, so 5*sqrt(2) units from origin
// Minus 1.0 for the sphere radius to get the length of the hit.
var expectedHitLengthWorldSpace = 5.0f * Mathf.Sqrt(2.0f) - 0.5f - castRadius;
Assert.AreEqual(0.0f, outputBuffer[4]); // missed cube
Assert.AreEqual(0.0f, outputBuffer[5]); // missed sphere
Assert.AreEqual(0.0f, outputBuffer[6]); // hit unknown tag -> all 0
Assert.That(
outputBuffer[7], Is.EqualTo(expectedHitLengthWorldSpace / perception.rayLength).Within(.0005f)
);
Assert.AreEqual(0.0f, outputBuffer[8]); // missed cube
Assert.AreEqual(1.0f, outputBuffer[9]); // hit sphere
Assert.AreEqual(0.0f, outputBuffer[10]); // missed unknown tag
Assert.That(
outputBuffer[11], Is.EqualTo(expectedHitLengthWorldSpace / perception.rayLength).Within(.0005f)
);
}
}
[Test]
public void TestRaycastMiss()
{
var obj = new GameObject("agent");
var perception = obj.AddComponent<RayPerceptionSensorComponent3D>();
perception.raysPerDirection = 0;
perception.maxRayDegrees = 45;
perception.rayLength = 20;
perception.detectableTags = new List<string>();
perception.detectableTags.Add(k_CubeTag);
perception.detectableTags.Add(k_SphereTag);
var sensor = perception.CreateSensor();
var expectedObs = (2 * perception.raysPerDirection + 1) * (perception.detectableTags.Count + 2);
Assert.AreEqual(sensor.GetObservationShape()[0], expectedObs);
var outputBuffer = new float[expectedObs];
WriteAdapter writer = new WriteAdapter();
writer.SetTarget(outputBuffer, sensor.GetObservationShape(), 0);
var numWritten = sensor.Write(writer);
Assert.AreEqual(numWritten, expectedObs);
// Everything missed
Assert.AreEqual(new float[] { 0, 0, 1, 1 }, outputBuffer);
}
[Test]
public void TestRayFilter()
{
var cube = GameObject.CreatePrimitive(PrimitiveType.Cube);
cube.transform.position = new Vector3(0, 0, 10);
cube.tag = k_CubeTag;
cube.name = "cubeFar";
var cubeFiltered = GameObject.CreatePrimitive(PrimitiveType.Cube);
cubeFiltered.transform.position = new Vector3(0, 0, 5);
cubeFiltered.tag = k_CubeTag;
cubeFiltered.name = "cubeNear";
cubeFiltered.layer = 7;
Physics.SyncTransforms();
var obj = new GameObject("agent");
var perception = obj.AddComponent<RayPerceptionSensorComponent3D>();
perception.raysPerDirection = 0;
perception.rayLength = 20;
perception.detectableTags = new List<string>();
var filterCubeLayers = new[] { false, true };
foreach (var filterCubeLayer in filterCubeLayers)
{
// Set the layer mask to either the default, or one that ignores the close cube's layer
var layerMask = Physics.DefaultRaycastLayers;
if (filterCubeLayer)
{
layerMask &= ~(1 << cubeFiltered.layer);
}
perception.rayLayerMask = layerMask;
var sensor = perception.CreateSensor();
var expectedObs = (2 * perception.raysPerDirection + 1) * (perception.detectableTags.Count + 2);
Assert.AreEqual(sensor.GetObservationShape()[0], expectedObs);
var outputBuffer = new float[expectedObs];
WriteAdapter writer = new WriteAdapter();
writer.SetTarget(outputBuffer, sensor.GetObservationShape(), 0);
var numWritten = sensor.Write(writer);
Assert.AreEqual(numWritten, expectedObs);
if (filterCubeLayer)
{
// Hit the far cube because close was filtered.
Assert.That(outputBuffer[outputBuffer.Length - 1],
Is.EqualTo((9.5f - perception.sphereCastRadius) / perception.rayLength).Within(.0005f)
);
}
else
{
// Hit the close cube because not filtered.
Assert.That(outputBuffer[outputBuffer.Length - 1],
Is.EqualTo((4.5f - perception.sphereCastRadius) / perception.rayLength).Within(.0005f)
);
}
}
}
[Test]
public void TestRaycastsScaled()
{
SetupScene();
var obj = new GameObject("agent");
var perception = obj.AddComponent<RayPerceptionSensorComponent3D>();
obj.transform.localScale = new Vector3(2, 2,2 );
perception.raysPerDirection = 0;
perception.maxRayDegrees = 45;
perception.rayLength = 20;
perception.detectableTags = new List<string>();
perception.detectableTags.Add(k_CubeTag);
var radii = new[] { 0f, .5f };
foreach (var castRadius in radii)
{
perception.sphereCastRadius = castRadius;
var sensor = perception.CreateSensor();
var expectedObs = (2 * perception.raysPerDirection + 1) * (perception.detectableTags.Count + 2);
Assert.AreEqual(sensor.GetObservationShape()[0], expectedObs);
var outputBuffer = new float[expectedObs];
WriteAdapter writer = new WriteAdapter();
writer.SetTarget(outputBuffer, sensor.GetObservationShape(), 0);
var numWritten = sensor.Write(writer);
Assert.AreEqual(numWritten, expectedObs);
// Expected hits:
// ray 0 should hit the cube at roughly 1/4 way
//
Assert.AreEqual(1.0f, outputBuffer[0]); // hit cube
Assert.AreEqual(0.0f, outputBuffer[1]); // missed unknown tag
// Hit is at z=9.0 in world space, ray length was 20
// But scale increases the cast size and the ray length
var scaledRayLength = 2 * perception.rayLength;
var scaledCastRadius = 2 * castRadius;
Assert.That(
outputBuffer[2], Is.EqualTo((9.5f - scaledCastRadius) / scaledRayLength).Within(.0005f)
);
}
}
[Test]
public void TestRayZeroLength()
{
// Place the cube touching the origin
var cube = GameObject.CreatePrimitive(PrimitiveType.Cube);
cube.transform.position = new Vector3(0, 0, .5f);
cube.tag = k_CubeTag;
Physics.SyncTransforms();
var obj = new GameObject("agent");
var perception = obj.AddComponent<RayPerceptionSensorComponent3D>();
perception.raysPerDirection = 0;
perception.rayLength = 0.0f;
perception.sphereCastRadius = .5f;
perception.detectableTags = new List<string>();
perception.detectableTags.Add(k_CubeTag);
{
// Set the layer mask to either the default, or one that ignores the close cube's layer
var sensor = perception.CreateSensor();
var expectedObs = (2 * perception.raysPerDirection + 1) * (perception.detectableTags.Count + 2);
Assert.AreEqual(sensor.GetObservationShape()[0], expectedObs);
var outputBuffer = new float[expectedObs];
WriteAdapter writer = new WriteAdapter();
writer.SetTarget(outputBuffer, sensor.GetObservationShape(), 0);
var numWritten = sensor.Write(writer);
Assert.AreEqual(numWritten, expectedObs);
// hit fraction is arbitrary but should be finite in [0,1]
Assert.GreaterOrEqual(outputBuffer[2], 0.0f);
Assert.LessOrEqual(outputBuffer[2], 1.0f);
}
}
}
}