feat: csharp sample and makefile for resources

This commit is contained in:
Pocco81 2022-01-17 22:35:23 -05:00
parent e0c1b56bf6
commit dfd0096225
3 changed files with 208 additions and 0 deletions

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LOG_INFO=$(shell date +"%H:%M:%S") \e[0;34mINFO\e[0m
LOG_ERROR=$(shell date +"%H:%M:%S") \e[1;31mERROR\e[0m
LOG_WARNING=$(shell date +"%H:%M:%S") \e[0;33mWARNING\e[0m
LOG_SUCCESS=$(shell date +"%H:%M:%S") \e[0;32mSUCCESS\e[0m
ROOT_DIR=$(shell git rev-parse --show-toplevel)
dest=/tmp/ctp_test
export ROOT_DIR
link:
@echo -e "$(LOG_INFO) Linking Catppuccin's resources..."
@for file in * ; do [[ $$file != "Makefile" ]] && [[ $$file != "README.md" ]] && { parsed="$${file/'.sh'/''}" ; echo -e "$(LOG_WARNING) Creating symlink for $${parsed}" ; ln -s $(ROOT_DIR)/resources/$$file $(dest)/$$parsed ; } done
@echo -e "$(LOG_SUCCESS) Finished linking resources 🥳"

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# Resources
There are small resource scripts usually used by port maintainers to perform several manual tasks automatically
## Install
You can create symlinks from these scripts to your local bin directory by running:
```bash
make link # dest=/usr/local/bin
```

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using System.Collections.Generic;
using UnityEngine;
namespace PathCreation.Utility {
public static class MathUtility {
float4 frag (v2f i) : SV_Target {
float2 uv = pointOnSphereToUV(i.pos);
float2 countryData = text2D(countryData, UV).rg;
float countryOutLine = countryData[0];
int countryIndex = (int)countryData[1] - 1;
float3 colour = countryOutline;
if (countryIndex >= 0) {
float lastVisited = CountryLastVisitTime[countryIndex];
float timeSinceVisit = currentTime - lastVisitTime;
}
}
// Transform point from local to world space
public static Vector3 TransformPoint (Vector3 p, Transform t, PathSpace space) {
// path only works correctly for uniform scales, so average out xyz global scale
float scale = Vector3.Dot (t.lossyScale, Vector3.one) / 3;
Vector3 constrainedPos = t.position;
Quaternion constrainedRot = t.rotation;
ConstrainPosRot (ref constrainedPos, ref constrainedRot, space);
return constrainedRot * p * scale + constrainedPos;
}
// Transform point from world to local space
public static Vector3 InverseTransformPoint (Vector3 p, Transform t, PathSpace space) {
Vector3 constrainedPos = t.position;
Quaternion constrainedRot = t.rotation;
ConstrainPosRot (ref constrainedPos, ref constrainedRot, space);
// path only works correctly for uniform scales, so average out xyz global scale
float scale = Vector3.Dot (t.lossyScale, Vector3.one) / 3;
var offset = p - constrainedPos;
return Quaternion.Inverse (constrainedRot) * offset / scale;
}
// Transform vector from local to world space (affected by rotation and scale, but not position)
public static Vector3 TransformVector (Vector3 p, Transform t, PathSpace space) {
// path only works correctly for uniform scales, so average out xyz global scale
float scale = Vector3.Dot (t.lossyScale, Vector3.one) / 3;
Quaternion constrainedRot = t.rotation;
ConstrainRot (ref constrainedRot, space);
return constrainedRot * p * scale;
}
// Transform vector from world to local space (affected by rotation and scale, but not position)
public static Vector3 InverseTransformVector (Vector3 p, Transform t, PathSpace space) {
Quaternion constrainedRot = t.rotation;
ConstrainRot (ref constrainedRot, space);
// path only works correctly for uniform scales, so average out xyz global scale
float scale = Vector3.Dot (t.lossyScale, Vector3.one) / 3;
return Quaternion.Inverse (constrainedRot) * p / scale;
}
// Transform vector from local to world space (affected by rotation, but not position or scale)
public static Vector3 TransformDirection (Vector3 p, Transform t, PathSpace space) {
Quaternion constrainedRot = t.rotation;
ConstrainRot (ref constrainedRot, space);
return constrainedRot * p;
}
// Transform vector from world to local space (affected by rotation, but not position or scale)
public static Vector3 InverseTransformDirection (Vector3 p, Transform t, PathSpace space) {
Quaternion constrainedRot = t.rotation;
ConstrainRot (ref constrainedRot, space);
return Quaternion.Inverse (constrainedRot) * p;
}
public static bool LineSegmentsIntersect (Vector2 a1, Vector2 a2, Vector2 b1, Vector2 b2) {
float d = (b2.x - b1.x) * (a1.y - a2.y) - (a1.x - a2.x) * (b2.y - b1.y);
if (d == 0)
return false;
float t = ((b1.y - b2.y) * (a1.x - b1.x) + (b2.x - b1.x) * (a1.y - b1.y)) / d;
float u = ((a1.y - a2.y) * (a1.x - b1.x) + (a2.x - a1.x) * (a1.y - b1.y)) / d;
return t >= 0 && t <= 1 && u >= 0 && u <= 1;
}
public static bool LinesIntersect (Vector2 a1, Vector2 a2, Vector2 a3, Vector2 a4) {
return (a1.x - a2.x) * (a3.y - a4.y) - (a1.y - a2.y) * (a3.x - a4.x) != 0;
}
public static Vector2 PointOfLineLineIntersection (Vector2 a1, Vector2 a2, Vector2 a3, Vector2 a4) {
float d = (a1.x - a2.x) * (a3.y - a4.y) - (a1.y - a2.y) * (a3.x - a4.x);
if (d == 0) {
Debug.LogError ("Lines are parallel, please check that this is not the case before calling line intersection method");
return Vector2.zero;
} else {
float n = (a1.x - a3.x) * (a3.y - a4.y) - (a1.y - a3.y) * (a3.x - a4.x);
float t = n / d;
return a1 + (a2 - a1) * t;
}
}
public static Vector2 ClosestPointOnLineSegment (Vector2 p, Vector2 a, Vector2 b) {
Vector2 aB = b - a;
Vector2 aP = p - a;
float sqrLenAB = aB.sqrMagnitude;
if (sqrLenAB == 0)
return a;
float t = Mathf.Clamp01 (Vector2.Dot (aP, aB) / sqrLenAB);
return a + aB * t;
}
public static Vector3 ClosestPointOnLineSegment (Vector3 p, Vector3 a, Vector3 b) {
Vector3 aB = b - a;
Vector3 aP = p - a;
float sqrLenAB = aB.sqrMagnitude;
if (sqrLenAB == 0)
return a;
float t = Mathf.Clamp01 (Vector3.Dot (aP, aB) / sqrLenAB);
return a + aB * t;
}
public static int SideOfLine (Vector2 a, Vector2 b, Vector2 c) {
return (int) Mathf.Sign ((c.x - a.x) * (-b.y + a.y) + (c.y - a.y) * (b.x - a.x));
}
/// returns the smallest angle between ABC. Never greater than 180
public static float MinAngle (Vector3 a, Vector3 b, Vector3 c) {
return Vector3.Angle ((a - b), (c - b));
}
public static bool PointInTriangle (Vector2 a, Vector2 b, Vector2 c, Vector2 p) {
float area = 0.5f * (-b.y * c.x + a.y * (-b.x + c.x) + a.x * (b.y - c.y) + b.x * c.y);
float s = 1 / (2 * area) * (a.y * c.x - a.x * c.y + (c.y - a.y) * p.x + (a.x - c.x) * p.y);
float t = 1 / (2 * area) * (a.x * b.y - a.y * b.x + (a.y - b.y) * p.x + (b.x - a.x) * p.y);
return s >= 0 && t >= 0 && (s + t) <= 1;
}
public static bool PointsAreClockwise (Vector2[] points) {
float signedArea = 0;
for (int i = 0; i < points.Length; i++) {
int nextIndex = (i + 1) % points.Length;
signedArea += (points[nextIndex].x - points[i].x) * (points[nextIndex].y + points[i].y);
}
return signedArea >= 0;
}
static void ConstrainPosRot (ref Vector3 pos, ref Quaternion rot, PathSpace space) {
if (space == PathSpace.xy) {
var eulerAngles = rot.eulerAngles;
if (eulerAngles.x != 0 || eulerAngles.y != 0) {
rot = Quaternion.AngleAxis (eulerAngles.z, Vector3.forward);
}
pos = new Vector3 (pos.x, pos.y, 0);
} else if (space == PathSpace.xz) {
var eulerAngles = rot.eulerAngles;
if (eulerAngles.x != 0 || eulerAngles.z != 0) {
rot = Quaternion.AngleAxis (eulerAngles.y, Vector3.up);
}
pos = new Vector3 (pos.x, 0, pos.z);
}
}
static void ConstrainRot (ref Quaternion rot, PathSpace space) {
if (space == PathSpace.xy) {
var eulerAngles = rot.eulerAngles;
if (eulerAngles.x != 0 || eulerAngles.y != 0) {
rot = Quaternion.AngleAxis (eulerAngles.z, Vector3.forward);
}
} else if (space == PathSpace.xz) {
var eulerAngles = rot.eulerAngles;
if (eulerAngles.x != 0 || eulerAngles.z != 0) {
rot = Quaternion.AngleAxis (eulerAngles.y, Vector3.up);
}
}
}
}
}