package monkstone.vecmath.vec3; /* * Copyright (c) 2015-17 Martin Prout * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * http://creativecommons.org/licenses/LGPL/2.1/ * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ import org.jruby.Ruby; import org.jruby.RubyArray; import org.jruby.RubyClass; import org.jruby.RubyFixnum; import org.jruby.RubyFloat; import org.jruby.RubyObject; import org.jruby.RubySymbol; import org.jruby.anno.JRubyClass; import org.jruby.anno.JRubyMethod; import org.jruby.runtime.Arity; import org.jruby.runtime.Block; import org.jruby.runtime.ThreadContext; import org.jruby.runtime.builtin.IRubyObject; import monkstone.vecmath.JRender; import monkstone.vecmath.vec2.Vec2; /** * * @author Martin Prout */ @JRubyClass(name = "Vec3D") public final class Vec3 extends RubyObject { private static final long serialVersionUID = 4563517343762009867L; /** * * @param runtime Ruby */ public static void createVec3(final Ruby runtime) { RubyClass vec3Cls = runtime.defineClass("Vec3D", runtime.getObject(), (Ruby runtime1, RubyClass rubyClass) -> new Vec3(runtime1, rubyClass)); vec3Cls.defineAnnotatedMethods(Vec3.class); } static final double EPSILON = 9.999999747378752e-05; // matches processing.org EPSILON double jx = 0; double jy = 0; double jz = 0; /** * * @param context ThreadContext * @param klazz IRubyObject * @param args optional (no args jx = 0, jy = 0, jz = 0) (2 args jz = 0) * @return new Vec3 object (ruby) */ @JRubyMethod(name = "new", meta = true, rest = true) public final static IRubyObject rbNew(ThreadContext context, IRubyObject klazz, IRubyObject[] args) { Vec3 vec = (Vec3) ((RubyClass) klazz).allocate(); vec.init(context, args); return vec; } /** * * @param runtime Ruby * @param klass RubyClass */ public Vec3(Ruby runtime, RubyClass klass) { super(runtime, klass); } void init(ThreadContext context, IRubyObject[] args) { int count = Arity.checkArgumentCount(context.runtime, args, Arity.OPTIONAL.getValue(), 3); if (count >= 2) { jx = (args[0] instanceof RubyFloat) ? ((RubyFloat) args[0]).getValue() : ((RubyFixnum) args[0]).getDoubleValue(); jy = (args[1] instanceof RubyFloat) ? ((RubyFloat) args[1]).getValue() : ((RubyFixnum) args[1]).getDoubleValue(); } if (count == 3) { jz = (args[2] instanceof RubyFloat) ? ((RubyFloat) args[2]).getValue() : ((RubyFixnum) args[2]).getDoubleValue(); } } /** * * @param context ThreadContext * @return x IRubyObject */ @JRubyMethod(name = "x") public IRubyObject getX(ThreadContext context) { return context.runtime.newFloat(jx); } /** * * @param context ThreadContext * @return y IRubyObject */ @JRubyMethod(name = "y") public IRubyObject getY(ThreadContext context) { return context.runtime.newFloat(jy); } /** * * @param context ThreadContext * @return z IRubyObject */ @JRubyMethod(name = "z") public IRubyObject getZ(ThreadContext context) { return context.runtime.newFloat(jz); } /** * * @param context ThreadContext * @param other IRubyObject * @return x IRubyObject */ @JRubyMethod(name = "x=") public IRubyObject setX(ThreadContext context, IRubyObject other) { if (other instanceof RubyFloat) { jx = ((RubyFloat) other).getValue(); } else { jx = ((RubyFixnum) other).getDoubleValue(); } return other; } /** * * @param context ThreadContext * @param other IRubyObject * @return y IRubyObject */ @JRubyMethod(name = "y=") public IRubyObject setY(ThreadContext context, IRubyObject other) { if (other instanceof RubyFloat) { jy = ((RubyFloat) other).getValue(); } else { jy = ((RubyFixnum) other).getDoubleValue(); } return other; } /** * * @param context ThreadContext * @param other IRubyObject * @return z IRubyObject */ @JRubyMethod(name = "z=") public IRubyObject setZ(ThreadContext context, IRubyObject other) { if (other instanceof RubyFloat) { jz = ((RubyFloat) other).getValue(); } else { jz = ((RubyFixnum) other).getDoubleValue(); } return other; } /** * * @param context ThreadContext * @param key as symbol * @return value float */ @JRubyMethod(name = "[]", required = 1) public IRubyObject aref(ThreadContext context, IRubyObject key) { Ruby runtime = context.runtime; if (key instanceof RubySymbol) { if (key == RubySymbol.newSymbol(runtime, "x")) { return runtime.newFloat(jx); } else if (key == RubySymbol.newSymbol(runtime, "y")) { return runtime.newFloat(jy); } else if (key == RubySymbol.newSymbol(runtime, "z")) { return runtime.newFloat(jz); } else { throw runtime.newIndexError("invalid key"); } } else { throw runtime.newIndexError("invalid key"); } } /** * @param context ThreadContext * @param key as symbol * @param value as float * @return value float */ @JRubyMethod(name = "[]=") public IRubyObject aset(ThreadContext context, IRubyObject key, IRubyObject value) { Ruby runtime = context.runtime; if (key instanceof RubySymbol) { if (key == RubySymbol.newSymbol(runtime, "x")) { jx = (value instanceof RubyFloat) ? ((RubyFloat) value).getValue() : ((RubyFixnum) value).getDoubleValue(); } else if (key == RubySymbol.newSymbol(runtime, "y")) { jy = (value instanceof RubyFloat) ? ((RubyFloat) value).getValue() : ((RubyFixnum) value).getDoubleValue(); } else if (key == RubySymbol.newSymbol(runtime, "z")) { jz = (value instanceof RubyFloat) ? ((RubyFloat) value).getValue() : ((RubyFixnum) value).getDoubleValue(); } else { throw runtime.newIndexError("invalid key"); } } else { throw runtime.newIndexError("invalid key"); } return value; } /** * * @param context ThreadContext * @param other IRubyObject * @return distance float */ @JRubyMethod(name = "dist", required = 1) public IRubyObject dist(ThreadContext context, IRubyObject other) { Vec3 b = null; if (other instanceof Vec3) { b = (Vec3) other.toJava(Vec3.class); } else { throw context.runtime.newTypeError("argument should be Vec3D"); } double result = Math.sqrt((jx - b.jx) * (jx - b.jx) + (jy - b.jy) * (jy - b.jy) + (jz - b.jz) * (jz - b.jz)); return context.runtime.newFloat(result); } /** * * @param context ThreadContext * @param other IRubyObject * @return distance squared float */ @JRubyMethod(name = "dist_squared", required = 1) public IRubyObject dist_squared(ThreadContext context, IRubyObject other) { Vec3 b = null; if (other instanceof Vec3) { b = (Vec3) other.toJava(Vec3.class); } else { throw context.runtime.newTypeError("argument should be Vec3D"); } double result = (jx - b.jx) * (jx - b.jx) + (jy - b.jy) * (jy - b.jy) + (jz - b.jz) * (jz - b.jz); return context.runtime.newFloat(result); } /** * * * @param context ThreadContext * @param other IRubyObject * @return cross product IRubyObject */ @JRubyMethod(name = "cross", required = 1) public IRubyObject cross(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; Vec3 vec = null; if (other instanceof Vec3) { vec = (Vec3) other.toJava(Vec3.class); } else { throw runtime.newTypeError("argument should be Vec3D"); } return Vec3.rbNew(context, other.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jy * vec.jz - jz * vec.jy), runtime.newFloat(jz * vec.jx - jx * vec.jz), runtime.newFloat(jx * vec.jy - jy * vec.jx) } ); } /** * * @param context ThreadContext * @param other IRubyObject * @return dot product IRubyObject */ @JRubyMethod(name = "dot", required = 1) public IRubyObject dot(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; Vec3 b = null; if (other instanceof Vec3) { b = (Vec3) other.toJava(Vec3.class); } else { throw runtime.newTypeError("argument should be Vec3D"); } return runtime.newFloat(jx * b.jx + jy * b.jy + jz * b.jz); } /** * * @param context ThreadContext * @param other IRubyObject * @return new Vec3 object (ruby) */ @JRubyMethod(name = "+", required = 1) public IRubyObject op_add(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; Vec3 b = (Vec3) other.toJava(Vec3.class); return Vec3.rbNew(context, other.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx + b.jx), runtime.newFloat(jy + b.jy), runtime.newFloat(jz + b.jz)}); } /** * * @param context ThreadContext * @param other IRubyObject * @return new Vec3 object (ruby) */ @JRubyMethod(name = "-") public IRubyObject op_sub(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; Vec3 b = null; if (other instanceof Vec3) { b = (Vec3) other.toJava(Vec3.class); } else { throw runtime.newTypeError("argument should be Vec3D"); } return Vec3.rbNew(context, other.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx - b.jx), runtime.newFloat(jy - b.jy), runtime.newFloat(jz - b.jz)}); } /** * * @param context ThreadContext * @param scalar IRubyObject * @return new Vec3 object (ruby) */ @JRubyMethod(name = "*", required = 1) public IRubyObject op_mul(ThreadContext context, IRubyObject scalar) { Ruby runtime = context.runtime; double multi = (scalar instanceof RubyFloat) ? ((RubyFloat) scalar).getValue() : ((RubyFixnum) scalar).getDoubleValue(); return Vec3.rbNew(context, this.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx * multi), runtime.newFloat(jy * multi), runtime.newFloat(jz * multi)}); } /** * * @param context ThreadContext * @param scalar IRubyObject * @return new Vec3 object (ruby) */ @JRubyMethod(name = "/", required = 1) public IRubyObject op_div(ThreadContext context, IRubyObject scalar) { Ruby runtime = context.runtime; double divisor = (scalar instanceof RubyFloat) ? ((RubyFloat) scalar).getValue() : ((RubyFixnum) scalar).getDoubleValue(); if (Math.abs(divisor) < Vec3.EPSILON) { return this; } return Vec3.rbNew(context, this.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx / divisor), runtime.newFloat(jy / divisor), runtime.newFloat(jz / divisor)}); } /** * * @param context ThreadContext * @return magnitude squared IRubyObject */ @JRubyMethod(name = "mag_squared") public IRubyObject mag_squared(ThreadContext context) { return context.runtime.newFloat(jx * jx + jy * jy + jz * jz); } /** * * @param context ThreadContext * @return magnitude IRubyObject */ @JRubyMethod(name = "mag") public IRubyObject mag(ThreadContext context) { return context.runtime.newFloat(Math.sqrt(jx * jx + jy * jy + jz * jz)); } /** * Call yield if block given, do nothing if yield == false else set_mag to * given scalar * * @param context ThreadContext * @param scalar double value to set * @param block should return a boolean (optional) * @return magnitude IRubyObject */ @JRubyMethod(name = "set_mag") public IRubyObject set_mag(ThreadContext context, IRubyObject scalar, Block block) { if (block.isGiven()) { if (!(boolean) block.yield(context, scalar).toJava(Boolean.class)) { return this; } } double new_mag = (scalar instanceof RubyFloat) ? ((RubyFloat) scalar).getValue() : ((RubyFixnum) scalar).getDoubleValue(); double current = Math.sqrt(jx * jx + jy * jy + jz * jz); if (current > EPSILON) { jx *= new_mag / current; jy *= new_mag / current; jz *= new_mag / current; } return this; } /** * * @param context ThreadContext * @return this as a ruby object */ @JRubyMethod(name = "normalize!") public IRubyObject normalize_bang(ThreadContext context) { if (Math.abs(jx) < EPSILON && Math.abs(jy) < EPSILON && Math.abs(jz) < EPSILON) { return this; } double mag = Math.sqrt(jx * jx + jy * jy + jz * jz); jx /= mag; jy /= mag; jz /= mag; return this; } /** * * @param context ThreadContext * @return new normalized Vec3D object (ruby) */ @JRubyMethod(name = "normalize") public IRubyObject normalize(ThreadContext context) { Ruby runtime = context.runtime; double mag = Math.sqrt(jx * jx + jy * jy + jz * jz); if (mag < EPSILON) { return Vec3.rbNew(context, this.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx), runtime.newFloat(jy), runtime.newFloat(jz)}); } return Vec3.rbNew(context, this.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx / mag), runtime.newFloat(jy / mag), runtime.newFloat(jz / mag)}); } /** * Example of a regular ruby class method * * @param context ThreadContext * @param klazz IRubyObject * @return new random Vec3D object (ruby) */ @JRubyMethod(name = "random", meta = true) public static IRubyObject random_direction(ThreadContext context, IRubyObject klazz) { Ruby runtime = context.runtime; double angle = Math.random() * Math.PI * 2; double vz = Math.random() * 2 - 1; double vx = Math.sqrt(1 - vz * vz) * Math.cos(angle); double vy = Math.sqrt(1 - vz * vz) * Math.sin(angle); return Vec3.rbNew(context, klazz, new IRubyObject[]{ runtime.newFloat(vx), runtime.newFloat(vy), runtime.newFloat(vz)}); } /** * * @param context ThreadContext * @param other IRubyObject another Vec3D * @return angle IRubyObject in radians */ @JRubyMethod(name = "angle_between") public IRubyObject angleBetween(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; Vec3 vec = (Vec3) other.toJava(Vec3.class); // We get NaN if we pass in a zero vector which can cause problems // Zero seems like a reasonable angle between a (0,0,0) vector and something else if (jx == 0 && jy == 0 && jz == 0) { return runtime.newFloat(0.0); } if (vec.jx == 0 && vec.jy == 0 && vec.jz == 0) { return runtime.newFloat(0.0); } double dot = jx * vec.jx + jy * vec.jy + jz * vec.jz; double v1mag = Math.sqrt(jx * jx + jy * jy + jz * jz); double v2mag = Math.sqrt(vec.jx * vec.jx + vec.jy * vec.jy + vec.jz * vec.jz); // This should be a number between -1 and 1, since it's "normalized" double amt = dot / (v1mag * v2mag); if (amt <= -1) { return runtime.newFloat(Math.PI); } else if (amt >= 1) { return runtime.newFloat(0.0); } return runtime.newFloat(Math.acos(amt)); } /** * * @param context ThreadContext * @return IRubyObject copy */ @JRubyMethod(name = {"copy", "dup"}) public IRubyObject copy(ThreadContext context) { Ruby runtime = context.runtime; return Vec3.rbNew(context, this.getMetaClass(), new IRubyObject[]{ runtime.newFloat(jx), runtime.newFloat(jy), runtime.newFloat(jz)}); } /** * * @param context ThreadContext * @return IRubyObject array of float */ @JRubyMethod(name = "to_a") public IRubyObject toArray(ThreadContext context) { Ruby runtime = context.runtime; return RubyArray.newArray(context.runtime, new IRubyObject[]{ runtime.newFloat(jx), runtime.newFloat(jy), runtime.newFloat(jz)}); } /** * To vertex * * @param context ThreadContext * @param object IRubyObject vertex renderer */ @JRubyMethod(name = "to_vertex") public void toVertex(ThreadContext context, IRubyObject object) { JRender renderer = (JRender) object.toJava(JRender.class); renderer.vertex(jx, jy, jz); } /** * To curve vertex * * @param context ThreadContext * @param object IRubyObject vertex renderer */ @JRubyMethod(name = "to_curve_vertex") public void toCurveVertex(ThreadContext context, IRubyObject object) { JRender renderer = (JRender) object.toJava(JRender.class); renderer.curveVertex(jx, jy, jz); } /** * Sends this Vec3D as a processing vertex uv * * @param context ThreadContext * @param args IRubyObject[] */ @JRubyMethod(name = "to_vertex_uv", rest = true) public void toVertexUV(ThreadContext context, IRubyObject[] args) { int count = Arity.checkArgumentCount(context.runtime, args, Arity.OPTIONAL.getValue(), 3); double u = 0; double v = 0; if (count == 3) { u = (args[1] instanceof RubyFloat) ? ((RubyFloat) args[1]).getValue() : ((RubyFixnum) args[1]).getDoubleValue(); v = (args[2] instanceof RubyFloat) ? ((RubyFloat) args[2]).getValue() : ((RubyFixnum) args[2]).getDoubleValue(); } if (count == 2) { Vec2 texture = (Vec2) args[1].toJava(Vec2.class); u = texture.javax(); v = texture.javay(); } JRender renderer = (JRender) args[0].toJava(JRender.class); renderer.vertex(jx, jy, jz, u, v); } /** * Sends this Vec3D as a processing normal * * @param context ThreadContext * @param object IRubyObject vertex renderer */ @JRubyMethod(name = "to_normal") public void toNormal(ThreadContext context, IRubyObject object) { JRender renderer = (JRender) object.toJava(JRender.class); renderer.normal(jx, jy, jz); } /** * For jruby-9000 we alias to inspect * * @param context ThreadContext * @return IRubyObject to_s */ @JRubyMethod(name = {"to_s", "inspect"}) public IRubyObject to_s(ThreadContext context) { return context.runtime.newString(String.format("Vec3D(x = %4.4f, y = %4.4f, z = %4.4f)", jx, jy, jz)); } /** * Java hash * * @return hash int */ @Override public int hashCode() { int hash = 7; hash = 97 * hash + (int) (Double.doubleToLongBits(this.jx) ^ (Double.doubleToLongBits(this.jx) >>> 32)); hash = 97 * hash + (int) (Double.doubleToLongBits(this.jy) ^ (Double.doubleToLongBits(this.jy) >>> 32)); hash = 97 * hash + (int) (Double.doubleToLongBits(this.jz) ^ (Double.doubleToLongBits(this.jz) >>> 32)); return hash; } /** * Java Equals * * @param obj Object * @return result boolean */ @Override public boolean equals(Object obj) { if (obj == this) { return true; } if (obj instanceof Vec3) { final Vec3 other = (Vec3) obj; if ((Double.compare(jx, (Double) other.jx) == 0) && (Double.compare(jy, (Double) other.jy) == 0) && (Double.compare(jz, (Double) other.jz) == 0)) { return true; } } return false; } /** * * @param context ThreadContext * @param other IRubyObject * @return result IRubyObject as boolean */ @JRubyMethod(name = "eql?", required = 1) public IRubyObject eql_p(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; if (other == this) { return runtime.newBoolean(true); } if (other instanceof Vec3) { Vec3 v = (Vec3) other.toJava(Vec3.class); if ((Double.compare(jx, (Double) v.jx) == 0) && (Double.compare(jy, (Double) v.jy) == 0) && (Double.compare(jz, (Double) v.jz) == 0)) { return runtime.newBoolean(true); } } return runtime.newBoolean(false); } /** * * @param context ThreadContext * @param other IRubyObject * @return result IRubyObject as boolean */ @JRubyMethod(name = "==", required = 1) @Override public IRubyObject op_equal(ThreadContext context, IRubyObject other) { Ruby runtime = context.runtime; if (other == this) { return runtime.newBoolean(true); } if (other instanceof Vec3) { Vec3 v = (Vec3) other.toJava(Vec3.class); double diff = jx - v.jx; if ((diff < 0 ? -diff : diff) > Vec3.EPSILON) { return runtime.newBoolean(false); } diff = jy - v.jy; if ((diff < 0 ? -diff : diff) > Vec3.EPSILON) { return runtime.newBoolean(false); } diff = jz - v.jz; return runtime.newBoolean((diff < 0 ? -diff : diff) < Vec3.EPSILON); } return runtime.newBoolean(false); } }