/*
* Copyright (c) 2017 Samsung Electronics Co., Ltd.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*/
using System;
namespace Tizen.NUI
{
///
/// RelativeVector2 is a two-dimensional vector.
/// Both values (x and y) should be between [0, 1].
///
public class RelativeVector2 : global::System.IDisposable
{
private global::System.Runtime.InteropServices.HandleRef swigCPtr;
///
/// swigCMemOwn
///
/// 3
protected bool swigCMemOwn;
internal RelativeVector2(global::System.IntPtr cPtr, bool cMemoryOwn)
{
swigCMemOwn = cMemoryOwn;
swigCPtr = new global::System.Runtime.InteropServices.HandleRef(this, cPtr);
}
internal static global::System.Runtime.InteropServices.HandleRef getCPtr(RelativeVector2 obj)
{
return (obj == null) ? new global::System.Runtime.InteropServices.HandleRef(null, global::System.IntPtr.Zero) : obj.swigCPtr;
}
//A Flag to check who called Dispose(). (By User or DisposeQueue)
private bool isDisposeQueued = false;
///
/// A Flat to check if it is already disposed.
///
/// 3
protected bool disposed = false;
///
/// Dispose.
///
/// 3
~RelativeVector2()
{
if(!isDisposeQueued)
{
isDisposeQueued = true;
DisposeQueue.Instance.Add(this);
}
}
///
/// Dispose.
///
/// 3
public void Dispose()
{
//Throw excpetion if Dispose() is called in separate thread.
if (!Window.IsInstalled())
{
throw new System.InvalidOperationException("This API called from separate thread. This API must be called from MainThread.");
}
if (isDisposeQueued)
{
Dispose(DisposeTypes.Implicit);
}
else
{
Dispose(DisposeTypes.Explicit);
System.GC.SuppressFinalize(this);
}
}
///
/// Dispose.
///
/// 3
protected virtual void Dispose(DisposeTypes type)
{
if (disposed)
{
return;
}
if(type == DisposeTypes.Explicit)
{
//Called by User
//Release your own managed resources here.
//You should release all of your own disposable objects here.
}
//Release your own unmanaged resources here.
//You should not access any managed member here except static instance.
//because the execution order of Finalizes is non-deterministic.
if (swigCPtr.Handle != global::System.IntPtr.Zero)
{
if (swigCMemOwn)
{
swigCMemOwn = false;
NDalicPINVOKE.delete_Vector2(swigCPtr);
}
swigCPtr = new global::System.Runtime.InteropServices.HandleRef(null, global::System.IntPtr.Zero);
}
disposed = true;
}
///
/// The addition operator.
///
/// The vector to add.
/// The vector to add.
/// The vector containing the result of the addition.
/// 3
public static RelativeVector2 operator +(RelativeVector2 arg1, RelativeVector2 arg2)
{
RelativeVector2 result = arg1.Add(arg2);
ValueCheck(result);
return result;
}
///
/// The subtraction operator.
///
/// The vector to subtract.
/// The vector to subtract.
/// The vector containing the result of the subtraction.
/// 3
public static RelativeVector2 operator -(RelativeVector2 arg1, RelativeVector2 arg2)
{
RelativeVector2 result = arg1.Subtract(arg2);
ValueCheck(result);
return result;
}
///
/// The multiplication operator.
///
/// The vector to multiply.
/// The vector to multiply.
/// The vector containing the result of the multiplication.
/// 3
public static RelativeVector2 operator *(RelativeVector2 arg1, RelativeVector2 arg2)
{
RelativeVector2 result = arg1.Multiply(arg2);
ValueCheck(result);
return result;
}
///
/// The multiplication operator.
///
/// The vector to multiply.
/// The float value to scale the vector.
/// The vector containing the result of the scaling.
/// 3
public static RelativeVector2 operator *(RelativeVector2 arg1, float arg2)
{
RelativeVector2 result = arg1.Multiply(arg2);
ValueCheck(result);
return result;
}
///
/// The division operator.
///
/// The vector to divide.
/// The vector to divide.
/// The vector containing the result of the division.
/// 3
public static RelativeVector2 operator /(RelativeVector2 arg1, RelativeVector2 arg2)
{
RelativeVector2 result = arg1.Divide(arg2);
ValueCheck(result);
return result;
}
///
/// The division operator.
///
/// The vector to divide.
/// The float value to scale the vector by.
/// The vector containing the result of the scaling.
/// 3
public static RelativeVector2 operator /(RelativeVector2 arg1, float arg2)
{
RelativeVector2 result = arg1.Divide(arg2);
ValueCheck(result);
return result;
}
///
/// The const array subscript operator overload. Should be 0, 1.
///
/// The subscript index.
/// The float at the given index.
/// 3
public float this[uint index]
{
get
{
return ValueOfIndex(index);
}
}
///
///
internal static RelativeVector2 GetRelativeVector2FromPtr(global::System.IntPtr cPtr)
{
RelativeVector2 ret = new RelativeVector2(cPtr, false);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
///
/// The constructor.
///
/// 3
public RelativeVector2() : this(NDalicPINVOKE.new_Vector2__SWIG_0(), true)
{
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
}
///
/// The constructor.
///
/// The x component.
/// The y component.
/// 3
public RelativeVector2(float x, float y) : this(NDalicPINVOKE.new_Vector2__SWIG_1(x, y), true)
{
ValueCheck(x);
ValueCheck(y);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
}
///
/// The constructor.
///
/// The RelativeVector3 to create this vector from.
/// 3
public RelativeVector2(RelativeVector3 relativeVector3) : this(NDalicPINVOKE.new_Vector2__SWIG_3(RelativeVector3.getCPtr(relativeVector3)), true)
{
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
}
///
/// The constructor.
///
/// The RelativeVector4 to create this vector from.
/// 3
public RelativeVector2(RelativeVector4 relativeVector4) : this(NDalicPINVOKE.new_Vector2__SWIG_4(RelativeVector4.getCPtr(relativeVector4)), true)
{
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
}
private RelativeVector2 Add(RelativeVector2 rhs)
{
RelativeVector2 ret = new RelativeVector2(NDalicPINVOKE.Vector2_Add(swigCPtr, RelativeVector2.getCPtr(rhs)), true);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
private RelativeVector2 Subtract(RelativeVector2 rhs)
{
RelativeVector2 ret = new RelativeVector2(NDalicPINVOKE.Vector2_Subtract__SWIG_0(swigCPtr, RelativeVector2.getCPtr(rhs)), true);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
private RelativeVector2 Multiply(RelativeVector2 rhs)
{
RelativeVector2 ret = new RelativeVector2(NDalicPINVOKE.Vector2_Multiply__SWIG_0(swigCPtr, RelativeVector2.getCPtr(rhs)), true);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
private RelativeVector2 Multiply(float rhs)
{
RelativeVector2 ret = new RelativeVector2(NDalicPINVOKE.Vector2_Multiply__SWIG_1(swigCPtr, rhs), true);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
private RelativeVector2 Divide(RelativeVector2 rhs)
{
RelativeVector2 ret = new RelativeVector2(NDalicPINVOKE.Vector2_Divide__SWIG_0(swigCPtr, RelativeVector2.getCPtr(rhs)), true);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
private RelativeVector2 Divide(float rhs)
{
RelativeVector2 ret = new RelativeVector2(NDalicPINVOKE.Vector2_Divide__SWIG_1(swigCPtr, rhs), true);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
private float ValueOfIndex(uint index)
{
float ret = NDalicPINVOKE.Vector2_ValueOfIndex__SWIG_0(swigCPtr, index);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
///
/// Compares if the rhs is equal to.
///
/// The vector to compare.
/// Returns true if the two vectors are equal, otherwise false.
/// 3
public bool EqualTo(RelativeVector2 rhs)
{
bool ret = NDalicPINVOKE.Vector2_EqualTo(swigCPtr, RelativeVector2.getCPtr(rhs));
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
///
/// Compares if the rhs is not equal to.
///
/// The vector to compare.
/// Returns true if the two vectors are not equal, otherwise false.
/// 3
public bool NotEqualTo(RelativeVector2 rhs)
{
bool ret = NDalicPINVOKE.Vector2_NotEqualTo(swigCPtr, RelativeVector2.getCPtr(rhs));
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
///
/// The x component.
///
/// 3
public float X
{
set
{
ValueCheck(value);
NDalicPINVOKE.Vector2_X_set(swigCPtr, value);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
}
get
{
float ret = NDalicPINVOKE.Vector2_X_get(swigCPtr);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
}
///
/// The y component.
///
/// 3
public float Y
{
set
{
ValueCheck(value);
NDalicPINVOKE.Vector2_Y_set(swigCPtr, value);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
}
get
{
float ret = NDalicPINVOKE.Vector2_Y_get(swigCPtr);
if (NDalicPINVOKE.SWIGPendingException.Pending) throw NDalicPINVOKE.SWIGPendingException.Retrieve();
return ret;
}
}
///
///
/// 3
public static implicit operator Vector2(RelativeVector2 relativeVector2)
{
return new Vector2(relativeVector2.X, relativeVector2.Y);
}
///
///
/// 3
public static implicit operator RelativeVector2(Vector2 vec)
{
ValueCheck(vec.X);
ValueCheck(vec.Y);
return new RelativeVector2(vec.X, vec.Y);
}
internal static void ValueCheck(RelativeVector2 relativeVector2)
{
if(relativeVector2.X < 0.0f)
{
relativeVector2.X = 0.0f;
Tizen.Log.Fatal("NUI", "The value of Result is invalid! Should be between [0, 1].");
}
else if(relativeVector2.X > 1.0f)
{
relativeVector2.X = 1.0f;
Tizen.Log.Fatal("NUI", "The value of Result is invalid! Should be between [0, 1].");
}
if(relativeVector2.Y < 0.0f)
{
relativeVector2.Y = 0.0f;
Tizen.Log.Fatal("NUI", "The value of Result is invalid! Should be between [0, 1].");
}
else if(relativeVector2.Y > 1.0f)
{
relativeVector2.Y = 1.0f;
Tizen.Log.Fatal("NUI", "The value of Result is invalid! Should be between [0, 1].");
}
}
internal static void ValueCheck(float value)
{
if(value < 0.0f)
{
value = 0.0f;
Tizen.Log.Fatal("NUI", "The value of Parameters is invalid! Should be between [0, 1].");
}
else if(value > 1.0f)
{
value = 1.0f;
Tizen.Log.Fatal("NUI", "The value of Parameters is invalid! Should be between [0, 1].");
}
}
}
}