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-rw-r--r--indra/llmath/llbbox.cpp10
-rw-r--r--indra/llmath/llbbox.h10
-rw-r--r--indra/llmath/llcoordframe.h2
-rw-r--r--indra/llmath/llinterp.h53
-rw-r--r--indra/llmath/llmath.h62
-rw-r--r--indra/llmath/llmatrix4a.h28
-rw-r--r--indra/llmath/lloctree.h12
-rw-r--r--indra/llmath/llquaternion.cpp14
-rw-r--r--indra/llmath/llquaternion.h14
-rw-r--r--indra/llmath/llrect.h10
-rw-r--r--indra/llmath/llsimdtypes.h4
-rw-r--r--indra/llmath/llsphere.cpp19
-rw-r--r--indra/llmath/llsphere.h8
-rw-r--r--indra/llmath/lltreenode.h5
-rw-r--r--indra/llmath/llvector4a.h45
-rw-r--r--indra/llmath/llvector4logical.h2
-rw-r--r--indra/llmath/llvolume.cpp608
-rw-r--r--indra/llmath/llvolume.h343
-rw-r--r--indra/llmath/llvolumemgr.cpp14
-rw-r--r--indra/llmath/llvolumemgr.h4
-rw-r--r--indra/llmath/llvolumeoctree.cpp13
-rw-r--r--indra/llmath/llvolumeoctree.h8
-rw-r--r--indra/llmath/m3math.cpp8
-rw-r--r--indra/llmath/m4math.cpp8
-rw-r--r--indra/llmath/raytrace.cpp187
-rw-r--r--indra/llmath/raytrace.h63
-rw-r--r--indra/llmath/tests/llbbox_test.cpp20
-rw-r--r--indra/llmath/tests/llrect_test.cpp28
-rw-r--r--indra/llmath/tests/mathmisc_test.cpp2
-rw-r--r--indra/llmath/tests/v2math_test.cpp14
-rw-r--r--indra/llmath/tests/v3color_test.cpp2
-rw-r--r--indra/llmath/tests/v3dmath_test.cpp20
-rw-r--r--indra/llmath/tests/v3math_test.cpp24
-rw-r--r--indra/llmath/tests/v4color_test.cpp60
-rw-r--r--indra/llmath/tests/v4coloru_test.cpp74
-rw-r--r--indra/llmath/tests/v4math_test.cpp8
-rw-r--r--indra/llmath/tests/xform_test.cpp6
-rw-r--r--indra/llmath/v2math.cpp16
-rw-r--r--indra/llmath/v2math.h16
-rw-r--r--indra/llmath/v3color.cpp2
-rw-r--r--indra/llmath/v3color.h18
-rw-r--r--indra/llmath/v3dmath.cpp40
-rw-r--r--indra/llmath/v3dmath.h27
-rw-r--r--indra/llmath/v3math.cpp66
-rw-r--r--indra/llmath/v3math.h36
-rw-r--r--indra/llmath/v4color.cpp132
-rw-r--r--indra/llmath/v4color.h280
-rw-r--r--indra/llmath/v4coloru.cpp30
-rw-r--r--indra/llmath/v4coloru.h221
-rw-r--r--indra/llmath/v4math.cpp42
-rw-r--r--indra/llmath/v4math.h16
-rw-r--r--indra/llmath/xform.cpp6
-rw-r--r--indra/llmath/xform.h40
53 files changed, 1402 insertions, 1398 deletions
diff --git a/indra/llmath/llbbox.cpp b/indra/llmath/llbbox.cpp
index c4dffc8cf8..fa1253e421 100644
--- a/indra/llmath/llbbox.cpp
+++ b/indra/llmath/llbbox.cpp
@@ -38,7 +38,7 @@ void LLBBox::addPointLocal(const LLVector3& p)
{
mMinLocal = p;
mMaxLocal = p;
- mEmpty = FALSE;
+ mEmpty = false;
}
else
{
@@ -140,7 +140,7 @@ LLVector3 LLBBox::agentToLocalBasis(const LLVector3& v) const
return v * m;
}
-BOOL LLBBox::containsPointLocal(const LLVector3& p) const
+bool LLBBox::containsPointLocal(const LLVector3& p) const
{
if ( (p.mV[VX] < mMinLocal.mV[VX])
||(p.mV[VX] > mMaxLocal.mV[VX])
@@ -149,12 +149,12 @@ BOOL LLBBox::containsPointLocal(const LLVector3& p) const
||(p.mV[VZ] < mMinLocal.mV[VZ])
||(p.mV[VZ] > mMaxLocal.mV[VZ]))
{
- return FALSE;
+ return false;
}
- return TRUE;
+ return true;
}
-BOOL LLBBox::containsPointAgent(const LLVector3& p) const
+bool LLBBox::containsPointAgent(const LLVector3& p) const
{
LLVector3 point_local = agentToLocal(p);
return containsPointLocal(point_local);
diff --git a/indra/llmath/llbbox.h b/indra/llmath/llbbox.h
index aac8628762..5617eaebde 100644
--- a/indra/llmath/llbbox.h
+++ b/indra/llmath/llbbox.h
@@ -37,13 +37,13 @@
class LLBBox
{
public:
- LLBBox() {mEmpty = TRUE;}
+ LLBBox() {mEmpty = true;}
LLBBox( const LLVector3& pos_agent,
const LLQuaternion& rot,
const LLVector3& min_local,
const LLVector3& max_local )
:
- mMinLocal( min_local ), mMaxLocal( max_local ), mPosAgent(pos_agent), mRotation( rot), mEmpty( TRUE )
+ mMinLocal( min_local ), mMaxLocal( max_local ), mPosAgent(pos_agent), mRotation( rot), mEmpty( true )
{}
// Default copy constructor is OK.
@@ -64,8 +64,8 @@ public:
LLVector3 getExtentLocal() const { return mMaxLocal - mMinLocal; }
- BOOL containsPointLocal(const LLVector3& p) const;
- BOOL containsPointAgent(const LLVector3& p) const;
+ bool containsPointLocal(const LLVector3& p) const;
+ bool containsPointAgent(const LLVector3& p) const;
void addPointAgent(LLVector3 p);
void addBBoxAgent(const LLBBox& b);
@@ -92,7 +92,7 @@ private:
LLVector3 mMaxLocal;
LLVector3 mPosAgent; // Position relative to Agent's Region
LLQuaternion mRotation;
- BOOL mEmpty; // Nothing has been added to this bbox yet
+ bool mEmpty; // Nothing has been added to this bbox yet
};
//LLBBox operator*(const LLBBox &a, const LLMatrix4 &b);
diff --git a/indra/llmath/llcoordframe.h b/indra/llmath/llcoordframe.h
index 802b98425a..aaa701f792 100644
--- a/indra/llmath/llcoordframe.h
+++ b/indra/llmath/llcoordframe.h
@@ -61,7 +61,7 @@ public:
//LLCoordFrame(const F32 *origin, const F32 *rotation); // Assumes "origin" is 1x3 and "rotation" is 1x9 array
//LLCoordFrame(const F32 *origin_and_rotation); // Assumes "origin_and_rotation" is 1x12 array
- BOOL isFinite() { return mOrigin.isFinite() && mXAxis.isFinite() && mYAxis.isFinite() && mZAxis.isFinite(); }
+ bool isFinite() { return mOrigin.isFinite() && mXAxis.isFinite() && mYAxis.isFinite() && mZAxis.isFinite(); }
void reset();
void resetAxes();
diff --git a/indra/llmath/llinterp.h b/indra/llmath/llinterp.h
index 116e949663..f4faa82a82 100644
--- a/indra/llmath/llinterp.h
+++ b/indra/llmath/llinterp.h
@@ -41,7 +41,6 @@ class LLInterpVal
{
public:
virtual ~LLInterpVal() {}
- virtual void interp(LLInterpVal &target, const F32 frac); // Linear interpolation for each type
};
template <typename Type>
@@ -52,7 +51,7 @@ public:
virtual ~LLInterp() {}
virtual void start();
- void update(const F32 time);
+ virtual void update(const F32 time) = 0;
const Type &getCurVal() const;
void setStartVal(const Type &start_val);
@@ -67,15 +66,15 @@ public:
void setEndTime(const F32 time);
F32 getEndTime() const;
- BOOL isActive() const;
- BOOL isDone() const;
+ bool isActive() const;
+ bool isDone() const;
protected:
F32 mStartTime;
F32 mEndTime;
F32 mDuration;
- BOOL mActive;
- BOOL mDone;
+ bool mActive;
+ bool mDone;
Type mStartVal;
Type mEndVal;
@@ -88,8 +87,8 @@ template <typename Type>
class LLInterpLinear : public LLInterp<Type>
{
public:
- /*virtual*/ void start();
- void update(const F32 time);
+ void start() override;
+ void update(const F32 time) override;
F32 getCurFrac() const;
protected:
F32 mCurFrac;
@@ -108,10 +107,10 @@ class LLInterpAttractor : public LLInterp<Type>
{
public:
LLInterpAttractor();
- /*virtual*/ void start();
+ void start() override;
void setStartVel(const Type &vel);
void setForce(const F32 force);
- void update(const F32 time);
+ void update(const F32 time) override;
protected:
F32 mForce;
Type mStartVel;
@@ -123,7 +122,7 @@ class LLInterpFunc : public LLInterp<Type>
{
public:
LLInterpFunc();
- void update(const F32 time);
+ void update(const F32 time) override;
void setFunc(Type (*)(const F32, void *data), void *data);
protected:
@@ -151,8 +150,8 @@ LLInterp<Type>::LLInterp()
mEndTime = 1.f;
mDuration = 1.f;
mCurTime = 0.f;
- mDone = FALSE;
- mActive = FALSE;
+ mDone = false;
+ mActive = false;
}
template <class Type>
@@ -166,8 +165,8 @@ void LLInterp<Type>::start()
{
mCurVal = mStartVal;
mCurTime = mStartTime;
- mDone = FALSE;
- mActive = FALSE;
+ mDone = false;
+ mActive = false;
}
template <class Type>
@@ -225,13 +224,13 @@ F32 LLInterp<Type>::getEndTime() const
template <class Type>
-BOOL LLInterp<Type>::isDone() const
+bool LLInterp<Type>::isDone() const
{
return mDone;
}
template <class Type>
-BOOL LLInterp<Type>::isActive() const
+bool LLInterp<Type>::isActive() const
{
return mActive;
}
@@ -254,7 +253,7 @@ void LLInterpLinear<Type>::update(const F32 time)
F32 dfrac = target_frac - this->mCurFrac;
if (target_frac >= 0.f)
{
- this->mActive = TRUE;
+ this->mActive = true;
}
if (target_frac > 1.f)
@@ -262,7 +261,7 @@ void LLInterpLinear<Type>::update(const F32 time)
this->mCurVal = this->mEndVal;
this->mCurFrac = 1.f;
this->mCurTime = time;
- this->mDone = TRUE;
+ this->mDone = true;
return;
}
@@ -332,7 +331,7 @@ void LLInterpAttractor<Type>::update(const F32 time)
{
if (time > this->mStartTime)
{
- this->mActive = TRUE;
+ this->mActive = true;
}
else
{
@@ -340,7 +339,7 @@ void LLInterpAttractor<Type>::update(const F32 time)
}
if (time > this->mEndTime)
{
- this->mDone = TRUE;
+ this->mDone = true;
return;
}
@@ -362,8 +361,8 @@ void LLInterpAttractor<Type>::update(const F32 time)
template <class Type>
LLInterpFunc<Type>::LLInterpFunc() : LLInterp<Type>()
{
- mFunc = NULL;
- mData = NULL;
+ mFunc = nullptr;
+ mData = nullptr;
}
template <class Type>
@@ -378,7 +377,7 @@ void LLInterpFunc<Type>::update(const F32 time)
{
if (time > this->mStartTime)
{
- this->mActive = TRUE;
+ this->mActive = true;
}
else
{
@@ -386,7 +385,7 @@ void LLInterpFunc<Type>::update(const F32 time)
}
if (time > this->mEndTime)
{
- this->mDone = TRUE;
+ this->mDone = true;
return;
}
@@ -405,7 +404,7 @@ void LLInterpExp<Type>::update(const F32 time)
F32 target_frac = (time - this->mStartTime) / this->mDuration;
if (target_frac >= 0.f)
{
- this->mActive = TRUE;
+ this->mActive = true;
}
if (target_frac > 1.f)
@@ -413,7 +412,7 @@ void LLInterpExp<Type>::update(const F32 time)
this->mCurVal = this->mEndVal;
this->mCurFrac = 1.f;
this->mCurTime = time;
- this->mDone = TRUE;
+ this->mDone = true;
return;
}
diff --git a/indra/llmath/llmath.h b/indra/llmath/llmath.h
index f425b590e4..4e8fc56de0 100644
--- a/indra/llmath/llmath.h
+++ b/indra/llmath/llmath.h
@@ -59,34 +59,34 @@
#define tanf(x) ((F32)tan((F64)(x)))
#endif*/
-const F32 GRAVITY = -9.8f;
+constexpr F32 GRAVITY = -9.8f;
// mathematical constants
-const F32 F_PI = 3.1415926535897932384626433832795f;
-const F32 F_TWO_PI = 6.283185307179586476925286766559f;
-const F32 F_PI_BY_TWO = 1.5707963267948966192313216916398f;
-const F32 F_SQRT_TWO_PI = 2.506628274631000502415765284811f;
-const F32 F_E = 2.71828182845904523536f;
-const F32 F_SQRT2 = 1.4142135623730950488016887242097f;
-const F32 F_SQRT3 = 1.73205080756888288657986402541f;
-const F32 OO_SQRT2 = 0.7071067811865475244008443621049f;
-const F32 OO_SQRT3 = 0.577350269189625764509f;
-const F32 DEG_TO_RAD = 0.017453292519943295769236907684886f;
-const F32 RAD_TO_DEG = 57.295779513082320876798154814105f;
-const F32 F_APPROXIMATELY_ZERO = 0.00001f;
-const F32 F_LN10 = 2.3025850929940456840179914546844f;
-const F32 OO_LN10 = 0.43429448190325182765112891891661;
-const F32 F_LN2 = 0.69314718056f;
-const F32 OO_LN2 = 1.4426950408889634073599246810019f;
-
-const F32 F_ALMOST_ZERO = 0.0001f;
-const F32 F_ALMOST_ONE = 1.0f - F_ALMOST_ZERO;
-
-const F32 GIMBAL_THRESHOLD = 0.000436f; // sets the gimballock threshold 0.025 away from +/-90 degrees
+constexpr F32 F_PI = 3.1415926535897932384626433832795f;
+constexpr F32 F_TWO_PI = 6.283185307179586476925286766559f;
+constexpr F32 F_PI_BY_TWO = 1.5707963267948966192313216916398f;
+constexpr F32 F_SQRT_TWO_PI = 2.506628274631000502415765284811f;
+constexpr F32 F_E = 2.71828182845904523536f;
+constexpr F32 F_SQRT2 = 1.4142135623730950488016887242097f;
+constexpr F32 F_SQRT3 = 1.73205080756888288657986402541f;
+constexpr F32 OO_SQRT2 = 0.7071067811865475244008443621049f;
+constexpr F32 OO_SQRT3 = 0.577350269189625764509f;
+constexpr F32 DEG_TO_RAD = 0.017453292519943295769236907684886f;
+constexpr F32 RAD_TO_DEG = 57.295779513082320876798154814105f;
+constexpr F32 F_APPROXIMATELY_ZERO = 0.00001f;
+constexpr F32 F_LN10 = 2.3025850929940456840179914546844f;
+constexpr F32 OO_LN10 = 0.43429448190325182765112891891661;
+constexpr F32 F_LN2 = 0.69314718056f;
+constexpr F32 OO_LN2 = 1.4426950408889634073599246810019f;
+
+constexpr F32 F_ALMOST_ZERO = 0.0001f;
+constexpr F32 F_ALMOST_ONE = 1.0f - F_ALMOST_ZERO;
+
+constexpr F32 GIMBAL_THRESHOLD = 0.000436f; // sets the gimballock threshold 0.025 away from +/-90 degrees
// formula: GIMBAL_THRESHOLD = sin(DEG_TO_RAD * gimbal_threshold_angle);
// BUG: Eliminate in favor of F_APPROXIMATELY_ZERO above?
-const F32 FP_MAG_THRESHOLD = 0.0000001f;
+constexpr F32 FP_MAG_THRESHOLD = 0.0000001f;
// TODO: Replace with logic like is_approx_equal
inline bool is_approx_zero( F32 f ) { return (-F_APPROXIMATELY_ZERO < f) && (f < F_APPROXIMATELY_ZERO); }
@@ -123,13 +123,13 @@ inline bool is_zero(F32 x)
inline bool is_approx_equal(F32 x, F32 y)
{
- const S32 COMPARE_MANTISSA_UP_TO_BIT = 0x02;
+ constexpr S32 COMPARE_MANTISSA_UP_TO_BIT = 0x02;
return (std::abs((S32) ((U32&)x - (U32&)y) ) < COMPARE_MANTISSA_UP_TO_BIT);
}
inline bool is_approx_equal(F64 x, F64 y)
{
- const S64 COMPARE_MANTISSA_UP_TO_BIT = 0x02;
+ constexpr S64 COMPARE_MANTISSA_UP_TO_BIT = 0x02;
return (std::abs((S32) ((U64&)x - (U64&)y) ) < COMPARE_MANTISSA_UP_TO_BIT);
}
@@ -272,8 +272,8 @@ inline F64 ll_round( F64 val, F64 nearest )
// peak error = -31.4 dB
// RMS error = -28.1 dB
-const F32 FAST_MAG_ALPHA = 0.960433870103f;
-const F32 FAST_MAG_BETA = 0.397824734759f;
+constexpr F32 FAST_MAG_ALPHA = 0.960433870103f;
+constexpr F32 FAST_MAG_BETA = 0.397824734759f;
// these provide minimum RMS error
//
@@ -281,8 +281,8 @@ const F32 FAST_MAG_BETA = 0.397824734759f;
// peak error = -32.6 dB
// RMS error = -25.7 dB
//
-//const F32 FAST_MAG_ALPHA = 0.948059448969f;
-//const F32 FAST_MAG_BETA = 0.392699081699f;
+//constexpr F32 FAST_MAG_ALPHA = 0.948059448969f;
+//constexpr F32 FAST_MAG_BETA = 0.392699081699f;
inline F32 fastMagnitude(F32 a, F32 b)
{
@@ -299,8 +299,8 @@ inline F32 fastMagnitude(F32 a, F32 b)
//
// Culled from www.stereopsis.com/FPU.html
-const F64 LL_DOUBLE_TO_FIX_MAGIC = 68719476736.0*1.5; //2^36 * 1.5, (52-_shiftamt=36) uses limited precisicion to floor
-const S32 LL_SHIFT_AMOUNT = 16; //16.16 fixed point representation,
+constexpr F64 LL_DOUBLE_TO_FIX_MAGIC = 68719476736.0*1.5; //2^36 * 1.5, (52-_shiftamt=36) uses limited precisicion to floor
+constexpr S32 LL_SHIFT_AMOUNT = 16; //16.16 fixed point representation,
// Endian dependent code
#ifdef LL_LITTLE_ENDIAN
diff --git a/indra/llmath/llmatrix4a.h b/indra/llmath/llmatrix4a.h
index cf4e522467..3b423f783a 100644
--- a/indra/llmath/llmatrix4a.h
+++ b/indra/llmath/llmatrix4a.h
@@ -46,6 +46,34 @@ public:
loadu(val);
}
+ explicit LLMatrix4a(const F32* val)
+ {
+ loadu(val);
+ }
+
+ static const LLMatrix4a& identity()
+ {
+ static const F32 v[] =
+ { 1.f, 0.f, 0.f, 0.f,
+ 0.f, 1.f, 0.f, 0.f,
+ 0.f, 0.f, 1.f, 0.f,
+ 0.f, 0.f, 0.f, 1.f
+ };
+ static LLMatrix4a identity_mat(v);
+
+ return identity_mat;
+ }
+
+ bool operator==(const LLMatrix4a& rhs) const
+ {
+ return mMatrix[0] == rhs.mMatrix[0] && mMatrix[1] == rhs.mMatrix[1] && mMatrix[2] == rhs.mMatrix[2] && mMatrix[3] == rhs.mMatrix[3];
+ }
+
+ bool operator!=(const LLMatrix4a& rhs) const
+ {
+ return !(*this == rhs);
+ }
+
inline F32* getF32ptr()
{
return (F32*) &mMatrix;
diff --git a/indra/llmath/lloctree.h b/indra/llmath/lloctree.h
index 88ba006269..eaa2763d2d 100644
--- a/indra/llmath/lloctree.h
+++ b/indra/llmath/lloctree.h
@@ -453,7 +453,7 @@ public:
S32 i = data->getBinIndex();
- if (i >= 0 && i < getElementCount())
+ if (i >= 0 && i < (S32)getElementCount())
{
if (mData[i] == data)
{ //found it
@@ -548,7 +548,7 @@ public:
}
}
- void addChild(oct_node* child, BOOL silent = FALSE)
+ void addChild(oct_node* child, bool silent = false)
{
#if LL_OCTREE_PARANOIA_CHECK
@@ -591,7 +591,7 @@ public:
}
}
- void removeChild(S32 index, BOOL destroy = FALSE)
+ void removeChild(S32 index, bool destroy = false)
{
for (U32 i = 0; i < this->getListenerCount(); i++)
{
@@ -638,7 +638,7 @@ public:
{
if (getChild(i) == node)
{
- removeChild(i, TRUE);
+ removeChild(i, true);
return;
}
}
@@ -707,7 +707,7 @@ public:
//(don't notify listeners of addition)
for (U32 i = 0; i < child->getChildCount(); i++)
{
- this->addChild(child->getChild(i), TRUE);
+ this->addChild(child->getChild(i), true);
}
//destroy child
@@ -723,7 +723,7 @@ public:
// LLOctreeRoot::insert
bool insert(T* data) override
{
- if (data == NULL)
+ if (data == nullptr)
{
OCT_ERRS << "!!! INVALID ELEMENT ADDED TO OCTREE ROOT !!!" << LL_ENDL;
return false;
diff --git a/indra/llmath/llquaternion.cpp b/indra/llmath/llquaternion.cpp
index ce0a88c26f..aefb82b2f0 100644
--- a/indra/llmath/llquaternion.cpp
+++ b/indra/llmath/llquaternion.cpp
@@ -653,14 +653,14 @@ LLQuaternion slerp( F32 u, const LLQuaternion &a, const LLQuaternion &b )
F32 cos_t = a.mQ[0]*b.mQ[0] + a.mQ[1]*b.mQ[1] + a.mQ[2]*b.mQ[2] + a.mQ[3]*b.mQ[3];
// if b is on opposite hemisphere from a, use -a instead
- int bflip;
+ bool bflip;
if (cos_t < 0.0f)
{
cos_t = -cos_t;
- bflip = TRUE;
+ bflip = true;
}
else
- bflip = FALSE;
+ bflip = false;
// if B is (within precision limits) the same as A,
// just linear interpolate between A and B.
@@ -959,11 +959,11 @@ void LLQuaternion::unpackFromVector3( const LLVector3& vec )
}
}
-BOOL LLQuaternion::parseQuat(const std::string& buf, LLQuaternion* value)
+bool LLQuaternion::parseQuat(const std::string& buf, LLQuaternion* value)
{
if( buf.empty() || value == NULL)
{
- return FALSE;
+ return false;
}
LLQuaternion quat;
@@ -971,10 +971,10 @@ BOOL LLQuaternion::parseQuat(const std::string& buf, LLQuaternion* value)
if( 4 == count )
{
value->set( quat );
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
diff --git a/indra/llmath/llquaternion.h b/indra/llmath/llquaternion.h
index fbe4da97f7..2caa993007 100644
--- a/indra/llmath/llquaternion.h
+++ b/indra/llmath/llquaternion.h
@@ -69,9 +69,9 @@ public:
LLSD getValue() const;
void setValue(const LLSD& sd);
- BOOL isIdentity() const;
- BOOL isNotIdentity() const;
- BOOL isFinite() const; // checks to see if all values of LLQuaternion are finite
+ bool isIdentity() const;
+ bool isNotIdentity() const;
+ bool isFinite() const; // checks to see if all values of LLQuaternion are finite
void quantize16(F32 lower, F32 upper); // changes the vector to reflect quatization
void quantize8(F32 lower, F32 upper); // changes the vector to reflect quatization
void loadIdentity(); // Loads the quaternion that represents the identity rotation
@@ -167,7 +167,7 @@ public:
friend const char *OrderToString( const Order order );
friend Order StringToOrder( const char *str );
- static BOOL parseQuat(const std::string& buf, LLQuaternion* value);
+ static bool parseQuat(const std::string& buf, LLQuaternion* value);
// For debugging, only
//static U32 mMultCount;
@@ -192,12 +192,12 @@ inline void LLQuaternion::setValue(const LLSD& sd)
}
// checker
-inline BOOL LLQuaternion::isFinite() const
+inline bool LLQuaternion::isFinite() const
{
return (llfinite(mQ[VX]) && llfinite(mQ[VY]) && llfinite(mQ[VZ]) && llfinite(mQ[VS]));
}
-inline BOOL LLQuaternion::isIdentity() const
+inline bool LLQuaternion::isIdentity() const
{
return
( mQ[VX] == 0.f ) &&
@@ -206,7 +206,7 @@ inline BOOL LLQuaternion::isIdentity() const
( mQ[VS] == 1.f );
}
-inline BOOL LLQuaternion::isNotIdentity() const
+inline bool LLQuaternion::isNotIdentity() const
{
return
( mQ[VX] != 0.f ) ||
diff --git a/indra/llmath/llrect.h b/indra/llmath/llrect.h
index 6c872611ba..317578da06 100644
--- a/indra/llmath/llrect.h
+++ b/indra/llmath/llrect.h
@@ -83,14 +83,14 @@ public:
}
// Note: follows GL_QUAD conventions: the top and right edges are not considered part of the rect
- BOOL pointInRect(const Type x, const Type y) const
+ bool pointInRect(const Type x, const Type y) const
{
return mLeft <= x && x < mRight &&
mBottom <= y && y < mTop;
}
//// Note: follows GL_QUAD conventions: the top and right edges are not considered part of the rect
- BOOL localPointInRect(const Type x, const Type y) const
+ bool localPointInRect(const Type x, const Type y) const
{
return 0 <= x && x < getWidth() &&
0 <= y && y < getHeight();
@@ -137,8 +137,8 @@ public:
}
// Note: Does NOT follow GL_QUAD conventions: the top and right edges ARE considered part of the rect
- // returns TRUE if any part of rect is is inside this LLRect
- BOOL overlaps(const LLRectBase& rect) const
+ // returns true if any part of rect is is inside this LLRect
+ bool overlaps(const LLRectBase& rect) const
{
return !(mLeft > rect.mRight
|| mRight < rect.mLeft
@@ -146,7 +146,7 @@ public:
|| mTop < rect.mBottom);
}
- BOOL contains(const LLRectBase& rect) const
+ bool contains(const LLRectBase& rect) const
{
return mLeft <= rect.mLeft
&& mRight >= rect.mRight
diff --git a/indra/llmath/llsimdtypes.h b/indra/llmath/llsimdtypes.h
index 9db152adf8..11462170fb 100644
--- a/indra/llmath/llsimdtypes.h
+++ b/indra/llmath/llsimdtypes.h
@@ -60,7 +60,7 @@ public:
inline operator bool() const { return static_cast<const bool&>(m_bool); }
private:
- int m_bool;
+ int m_bool{ 0 };
};
#if LL_WINDOWS
@@ -118,7 +118,7 @@ public:
}
private:
- LLQuad mQ;
+ LLQuad mQ{};
};
#endif //LL_SIMD_TYPES_H
diff --git a/indra/llmath/llsphere.cpp b/indra/llmath/llsphere.cpp
index 75f9ef1772..5f48764455 100644
--- a/indra/llmath/llsphere.cpp
+++ b/indra/llmath/llsphere.cpp
@@ -69,18 +69,18 @@ F32 LLSphere::getRadius() const
return mRadius;
}
-// returns 'TRUE' if this sphere completely contains other_sphere
-BOOL LLSphere::contains(const LLSphere& other_sphere) const
+// returns 'true' if this sphere completely contains other_sphere
+bool LLSphere::contains(const LLSphere& other_sphere) const
{
F32 separation = (mCenter - other_sphere.mCenter).length();
- return (mRadius >= separation + other_sphere.mRadius) ? TRUE : FALSE;
+ return mRadius >= separation + other_sphere.mRadius;
}
-// returns 'TRUE' if this sphere completely contains other_sphere
-BOOL LLSphere::overlaps(const LLSphere& other_sphere) const
+// returns 'true' if this sphere completely contains other_sphere
+bool LLSphere::overlaps(const LLSphere& other_sphere) const
{
F32 separation = (mCenter - other_sphere.mCenter).length();
- return (separation <= mRadius + other_sphere.mRadius) ? TRUE : FALSE;
+ return mRadius >= separation - other_sphere.mRadius;
}
// returns overlap
@@ -93,9 +93,8 @@ F32 LLSphere::getOverlap(const LLSphere& other_sphere) const
bool LLSphere::operator==(const LLSphere& rhs) const
{
- // TODO? -- use approximate equality for centers?
- return (mRadius == rhs.mRadius
- && mCenter == rhs.mCenter);
+ return fabs(mRadius - rhs.mRadius) <= FLT_EPSILON &&
+ (mCenter - rhs.mCenter).length() <= FLT_EPSILON;
}
std::ostream& operator<<( std::ostream& output_stream, const LLSphere& sphere)
@@ -186,7 +185,7 @@ LLSphere LLSphere::getBoundingSphere(const std::vector<LLSphere>& sphere_list)
// TODO -- improve the accuracy for small collections of spheres
LLSphere bounding_sphere( LLVector3(0.f, 0.f, 0.f), 0.f );
- S32 sphere_count = sphere_list.size();
+ auto sphere_count = sphere_list.size();
if (1 == sphere_count)
{
// trivial case -- single sphere
diff --git a/indra/llmath/llsphere.h b/indra/llmath/llsphere.h
index 62bcadf16d..cb923dcd3c 100644
--- a/indra/llmath/llsphere.h
+++ b/indra/llmath/llsphere.h
@@ -47,11 +47,11 @@ public:
const LLVector3& getCenter() const;
F32 getRadius() const;
- // returns TRUE if this sphere completely contains other_sphere
- BOOL contains(const LLSphere& other_sphere) const;
+ // returns true if this sphere completely contains other_sphere
+ bool contains(const LLSphere& other_sphere) const;
- // returns TRUE if this sphere overlaps other_sphere
- BOOL overlaps(const LLSphere& other_sphere) const;
+ // returns true if this sphere overlaps other_sphere
+ bool overlaps(const LLSphere& other_sphere) const;
// returns overlap distance
// negative overlap is closest approach
diff --git a/indra/llmath/lltreenode.h b/indra/llmath/lltreenode.h
index a0b90e3511..e3d30206b7 100644
--- a/indra/llmath/lltreenode.h
+++ b/indra/llmath/lltreenode.h
@@ -56,10 +56,11 @@ public:
virtual bool insert(T* data);
virtual bool remove(T* data);
virtual void notifyRemoval(T* data);
- virtual U32 getListenerCount() { return mListeners.size(); }
+ virtual U32 hasListeners() const { return !mListeners.empty(); }
+ virtual U32 getListenerCount() const { return static_cast<U32>(mListeners.size()); }
virtual LLTreeListener<T>* getListener(U32 index) const
{
- if(index < mListeners.size())
+ if (index < mListeners.size())
{
return mListeners[index];
}
diff --git a/indra/llmath/llvector4a.h b/indra/llmath/llvector4a.h
index 8f0ee4b739..8ef560dadf 100644
--- a/indra/llmath/llvector4a.h
+++ b/indra/llmath/llvector4a.h
@@ -117,6 +117,49 @@ public:
mQ = q;
}
+ bool operator==(const LLVector4a& rhs) const
+ {
+ return equals4(rhs);
+ }
+
+ bool operator!=(const LLVector4a& rhs) const
+ {
+ return !(*this == rhs);
+ }
+
+ const LLVector4a& operator+=(const LLVector4a& rhs)
+ {
+ add(rhs);
+ return *this;
+ }
+
+ const LLVector4a& operator-=(const LLVector4a& rhs)
+ {
+ sub(rhs);
+ return *this;
+ }
+
+ LLVector4a operator+(const LLVector4a& rhs) const
+ {
+ LLVector4a result = *this;
+ result.add(rhs);
+ return result;
+ }
+
+ LLVector4a operator-(const LLVector4a& rhs) const
+ {
+ LLVector4a result = *this;
+ result.sub(rhs);
+ return result;
+ }
+
+ LLVector4a cross3(const LLVector4a& b) const
+ {
+ LLVector4a result;
+ result.setCross3(*this, b);
+ return result;
+ }
+
////////////////////////////////////
// LOAD/STORE
////////////////////////////////////
@@ -322,7 +365,7 @@ public:
inline operator LLQuad() const;
private:
- LLQuad mQ;
+ LLQuad mQ{};
};
inline void update_min_max(LLVector4a& min, LLVector4a& max, const LLVector4a& p)
diff --git a/indra/llmath/llvector4logical.h b/indra/llmath/llvector4logical.h
index d08b5513d9..70759eef5c 100644
--- a/indra/llmath/llvector4logical.h
+++ b/indra/llmath/llvector4logical.h
@@ -120,7 +120,7 @@ public:
private:
- LLQuad mQ;
+ LLQuad mQ{};
};
#endif //LL_VECTOR4ALOGICAL_H
diff --git a/indra/llmath/llvolume.cpp b/indra/llmath/llvolume.cpp
index 41e614524e..f3db9424d9 100644
--- a/indra/llmath/llvolume.cpp
+++ b/indra/llmath/llvolume.cpp
@@ -61,66 +61,66 @@
#define DEBUG_SILHOUETTE_NORMALS 0 // TomY: Use this to display normals using the silhouette
#define DEBUG_SILHOUETTE_EDGE_MAP 0 // DaveP: Use this to display edge map using the silhouette
-const F32 MIN_CUT_DELTA = 0.02f;
+constexpr F32 MIN_CUT_DELTA = 0.02f;
-const F32 HOLLOW_MIN = 0.f;
-const F32 HOLLOW_MAX = 0.95f;
-const F32 HOLLOW_MAX_SQUARE = 0.7f;
+constexpr F32 HOLLOW_MIN = 0.f;
+constexpr F32 HOLLOW_MAX = 0.95f;
+constexpr F32 HOLLOW_MAX_SQUARE = 0.7f;
-const F32 TWIST_MIN = -1.f;
-const F32 TWIST_MAX = 1.f;
+constexpr F32 TWIST_MIN = -1.f;
+constexpr F32 TWIST_MAX = 1.f;
-const F32 RATIO_MIN = 0.f;
-const F32 RATIO_MAX = 2.f; // Tom Y: Inverted sense here: 0 = top taper, 2 = bottom taper
+constexpr F32 RATIO_MIN = 0.f;
+constexpr F32 RATIO_MAX = 2.f; // Tom Y: Inverted sense here: 0 = top taper, 2 = bottom taper
-const F32 HOLE_X_MIN= 0.05f;
-const F32 HOLE_X_MAX= 1.0f;
+constexpr F32 HOLE_X_MIN= 0.05f;
+constexpr F32 HOLE_X_MAX= 1.0f;
-const F32 HOLE_Y_MIN= 0.05f;
-const F32 HOLE_Y_MAX= 0.5f;
+constexpr F32 HOLE_Y_MIN= 0.05f;
+constexpr F32 HOLE_Y_MAX= 0.5f;
-const F32 SHEAR_MIN = -0.5f;
-const F32 SHEAR_MAX = 0.5f;
+constexpr F32 SHEAR_MIN = -0.5f;
+constexpr F32 SHEAR_MAX = 0.5f;
-const F32 REV_MIN = 1.f;
-const F32 REV_MAX = 4.f;
+constexpr F32 REV_MIN = 1.f;
+constexpr F32 REV_MAX = 4.f;
-const F32 TAPER_MIN = -1.f;
-const F32 TAPER_MAX = 1.f;
+constexpr F32 TAPER_MIN = -1.f;
+constexpr F32 TAPER_MAX = 1.f;
-const F32 SKEW_MIN = -0.95f;
-const F32 SKEW_MAX = 0.95f;
+constexpr F32 SKEW_MIN = -0.95f;
+constexpr F32 SKEW_MAX = 0.95f;
-const F32 SCULPT_MIN_AREA = 0.002f;
-const S32 SCULPT_MIN_AREA_DETAIL = 1;
+constexpr F32 SCULPT_MIN_AREA = 0.002f;
+constexpr S32 SCULPT_MIN_AREA_DETAIL = 1;
-BOOL gDebugGL = FALSE; // See settings.xml "RenderDebugGL"
+bool gDebugGL = false; // See settings.xml "RenderDebugGL"
-BOOL check_same_clock_dir( const LLVector3& pt1, const LLVector3& pt2, const LLVector3& pt3, const LLVector3& norm)
+bool check_same_clock_dir( const LLVector3& pt1, const LLVector3& pt2, const LLVector3& pt3, const LLVector3& norm)
{
LLVector3 test = (pt2-pt1)%(pt3-pt2);
//answer
if(test * norm < 0)
{
- return FALSE;
+ return false;
}
else
{
- return TRUE;
+ return true;
}
}
-BOOL LLLineSegmentBoxIntersect(const LLVector3& start, const LLVector3& end, const LLVector3& center, const LLVector3& size)
+bool LLLineSegmentBoxIntersect(const LLVector3& start, const LLVector3& end, const LLVector3& center, const LLVector3& size)
{
return LLLineSegmentBoxIntersect(start.mV, end.mV, center.mV, size.mV);
}
-BOOL LLLineSegmentBoxIntersect(const F32* start, const F32* end, const F32* center, const F32* size)
+bool LLLineSegmentBoxIntersect(const F32* start, const F32* end, const F32* center, const F32* size)
{
- F32 fAWdU[3];
- F32 dir[3];
- F32 diff[3];
+ F32 fAWdU[3]{};
+ F32 dir[3]{};
+ F32 diff[3]{};
for (U32 i = 0; i < 3; i++)
{
@@ -218,11 +218,11 @@ void calc_tangent_from_triangle(
// intersect test between triangle vert0, vert1, vert2 and a ray from orig in direction dir.
-// returns TRUE if intersecting and returns barycentric coordinates in intersection_a, intersection_b,
+// returns true if intersecting and returns barycentric coordinates in intersection_a, intersection_b,
// and returns the intersection point along dir in intersection_t.
// Moller-Trumbore algorithm
-BOOL LLTriangleRayIntersect(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
+bool LLTriangleRayIntersect(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
F32& intersection_a, F32& intersection_b, F32& intersection_t)
{
@@ -284,15 +284,15 @@ BOOL LLTriangleRayIntersect(const LLVector4a& vert0, const LLVector4a& vert1, co
intersection_a = u[0];
intersection_b = v[0];
intersection_t = t[0];
- return TRUE;
+ return true;
}
}
}
- return FALSE;
+ return false;
}
-BOOL LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
+bool LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
F32& intersection_a, F32& intersection_b, F32& intersection_t)
{
F32 u, v, t;
@@ -315,7 +315,7 @@ BOOL LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& v
if (det > -F_APPROXIMATELY_ZERO && det < F_APPROXIMATELY_ZERO)
{
- return FALSE;
+ return false;
}
F32 inv_det = 1.f / det;
@@ -328,7 +328,7 @@ BOOL LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& v
u = (tvec.dot3(pvec).getF32()) * inv_det;
if (u < 0.f || u > 1.f)
{
- return FALSE;
+ return false;
}
/* prepare to test V parameter */
@@ -339,7 +339,7 @@ BOOL LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& v
if (v < 0.f || u + v > 1.f)
{
- return FALSE;
+ return false;
}
/* calculate t, ray intersects triangle */
@@ -350,30 +350,7 @@ BOOL LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& v
intersection_t = t;
- return TRUE;
-}
-
-//helper for non-aligned vectors
-BOOL LLTriangleRayIntersect(const LLVector3& vert0, const LLVector3& vert1, const LLVector3& vert2, const LLVector3& orig, const LLVector3& dir,
- F32& intersection_a, F32& intersection_b, F32& intersection_t, BOOL two_sided)
-{
- LLVector4a vert0a, vert1a, vert2a, origa, dira;
- vert0a.load3(vert0.mV);
- vert1a.load3(vert1.mV);
- vert2a.load3(vert2.mV);
- origa.load3(orig.mV);
- dira.load3(dir.mV);
-
- if (two_sided)
- {
- return LLTriangleRayIntersectTwoSided(vert0a, vert1a, vert2a, origa, dira,
- intersection_a, intersection_b, intersection_t);
- }
- else
- {
- return LLTriangleRayIntersect(vert0a, vert1a, vert2a, origa, dira,
- intersection_a, intersection_b, intersection_t);
- }
+ return true;
}
//-------------------------------------------------------------------
@@ -390,12 +367,12 @@ LLProfile::Face* LLProfile::addCap(S16 faceID)
face->mIndex = 0;
face->mCount = mTotal;
face->mScaleU= 1.0f;
- face->mCap = TRUE;
+ face->mCap = true;
face->mFaceID = faceID;
return face;
}
-LLProfile::Face* LLProfile::addFace(S32 i, S32 count, F32 scaleU, S16 faceID, BOOL flat)
+LLProfile::Face* LLProfile::addFace(S32 i, S32 count, F32 scaleU, S16 faceID, bool flat)
{
Face *face = vector_append(mFaces, 1);
@@ -404,7 +381,7 @@ LLProfile::Face* LLProfile::addFace(S32 i, S32 count, F32 scaleU, S16 faceID, BO
face->mScaleU= scaleU;
face->mFlat = flat;
- face->mCap = FALSE;
+ face->mCap = false;
face->mFaceID = faceID;
return face;
}
@@ -479,7 +456,7 @@ void LLProfile::genNGon(const LLProfileParams& params, S32 sides, F32 offset, F3
{
// Generate an n-sided "circular" path.
// 0 is (1,0), and we go counter-clockwise along a circular path from there.
- static const F32 tableScale[] = { 1, 1, 1, 0.5f, 0.707107f, 0.53f, 0.525f, 0.5f };
+ constexpr F32 tableScale[] = { 1, 1, 1, 0.5f, 0.707107f, 0.53f, 0.525f, 0.5f };
F32 scale = 0.5f;
F32 t, t_step, t_first, t_fraction, ang, ang_step;
LLVector4a pt1,pt2;
@@ -579,13 +556,13 @@ void LLProfile::genNGon(const LLProfileParams& params, S32 sides, F32 offset, F3
{
if ((end - begin)*ang_scale > 0.5f)
{
- mConcave = TRUE;
+ mConcave = true;
}
else
{
- mConcave = FALSE;
+ mConcave = false;
}
- mOpen = TRUE;
+ mOpen = true;
if (params.getHollow() <= 0)
{
// put center point if not hollow.
@@ -595,8 +572,8 @@ void LLProfile::genNGon(const LLProfileParams& params, S32 sides, F32 offset, F3
else
{
// The profile isn't open.
- mOpen = FALSE;
- mConcave = FALSE;
+ mOpen = false;
+ mConcave = false;
}
mTotal = mProfile.size();
@@ -605,7 +582,7 @@ void LLProfile::genNGon(const LLProfileParams& params, S32 sides, F32 offset, F3
// Hollow is percent of the original bounding box, not of this particular
// profile's geometry. Thus, a swept triangle needs lower hollow values than
// a swept square.
-LLProfile::Face* LLProfile::addHole(const LLProfileParams& params, BOOL flat, F32 sides, F32 offset, F32 box_hollow, F32 ang_scale, S32 split)
+LLProfile::Face* LLProfile::addHole(const LLProfileParams& params, bool flat, F32 sides, F32 offset, F32 box_hollow, F32 ang_scale, S32 split)
{
// Note that addHole will NOT work for non-"circular" profiles, if we ever decide to use them.
@@ -644,8 +621,8 @@ LLProfile::Face* LLProfile::addHole(const LLProfileParams& params, BOOL flat, F3
}
//static
-S32 LLProfile::getNumPoints(const LLProfileParams& params, BOOL path_open,F32 detail, S32 split,
- BOOL is_sculpted, S32 sculpt_size)
+S32 LLProfile::getNumPoints(const LLProfileParams& params, bool path_open,F32 detail, S32 split,
+ bool is_sculpted, S32 sculpt_size)
{ // this is basically LLProfile::generate stripped down to only operations that influence the number of points
if (detail < MIN_LOD)
{
@@ -754,16 +731,16 @@ S32 LLProfile::getNumPoints(const LLProfileParams& params, BOOL path_open,F32 de
}
-BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detail, S32 split,
- BOOL is_sculpted, S32 sculpt_size)
+bool LLProfile::generate(const LLProfileParams& params, bool path_open,F32 detail, S32 split,
+ bool is_sculpted, S32 sculpt_size)
{
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME
if ((!mDirty) && (!is_sculpted))
{
- return FALSE;
+ return false;
}
- mDirty = FALSE;
+ mDirty = false;
if (detail < MIN_LOD)
{
@@ -784,7 +761,7 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
if (begin > end - 0.01f)
{
LL_WARNS() << "LLProfile::generate() assertion failed (begin >= end)" << LL_ENDL;
- return FALSE;
+ return false;
}
S32 face_num = 0;
@@ -801,7 +778,7 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
for (i = llfloor(begin * 4.f); i < llfloor(end * 4.f + .999f); i++)
{
- addFace((face_num++) * (split +1), split+2, 1, LL_FACE_OUTER_SIDE_0 << i, TRUE);
+ addFace((face_num++) * (split +1), split+2, 1, LL_FACE_OUTER_SIDE_0 << i, true);
}
LLVector4a scale(1,1,4,1);
@@ -819,16 +796,16 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
{
case LL_PCODE_HOLE_TRIANGLE:
// This offset is not correct, but we can't change it now... DK 11/17/04
- addHole(params, TRUE, 3, -0.375f, hollow, 1.f, split);
+ addHole(params, true, 3, -0.375f, hollow, 1.f, split);
break;
case LL_PCODE_HOLE_CIRCLE:
// TODO: Compute actual detail levels for cubes
- addHole(params, FALSE, MIN_DETAIL_FACES * detail, -0.375f, hollow, 1.f);
+ addHole(params, false, MIN_DETAIL_FACES * detail, -0.375f, hollow, 1.f);
break;
case LL_PCODE_HOLE_SAME:
case LL_PCODE_HOLE_SQUARE:
default:
- addHole(params, TRUE, 4, -0.375f, hollow, 1.f, split);
+ addHole(params, true, 4, -0.375f, hollow, 1.f, split);
break;
}
}
@@ -858,7 +835,7 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
for (i = llfloor(begin * 3.f); i < llfloor(end * 3.f + .999f); i++)
{
- addFace((face_num++) * (split +1), split+2, 1, LL_FACE_OUTER_SIDE_0 << i, TRUE);
+ addFace((face_num++) * (split +1), split+2, 1, LL_FACE_OUTER_SIDE_0 << i, true);
}
if (hollow)
{
@@ -870,15 +847,15 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
{
case LL_PCODE_HOLE_CIRCLE:
// TODO: Actually generate level of detail for triangles
- addHole(params, FALSE, MIN_DETAIL_FACES * detail, 0, triangle_hollow, 1.f);
+ addHole(params, false, MIN_DETAIL_FACES * detail, 0, triangle_hollow, 1.f);
break;
case LL_PCODE_HOLE_SQUARE:
- addHole(params, TRUE, 4, 0, triangle_hollow, 1.f, split);
+ addHole(params, true, 4, 0, triangle_hollow, 1.f, split);
break;
case LL_PCODE_HOLE_SAME:
case LL_PCODE_HOLE_TRIANGLE:
default:
- addHole(params, TRUE, 3, 0, triangle_hollow, 1.f, split);
+ addHole(params, true, 3, 0, triangle_hollow, 1.f, split);
break;
}
}
@@ -915,11 +892,11 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
if (mOpen && !hollow)
{
- addFace(0,mTotal-1,0,LL_FACE_OUTER_SIDE_0, FALSE);
+ addFace(0,mTotal-1,0,LL_FACE_OUTER_SIDE_0, false);
}
else
{
- addFace(0,mTotal,0,LL_FACE_OUTER_SIDE_0, FALSE);
+ addFace(0,mTotal,0,LL_FACE_OUTER_SIDE_0, false);
}
if (hollow)
@@ -927,15 +904,15 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
switch (hole_type)
{
case LL_PCODE_HOLE_SQUARE:
- addHole(params, TRUE, 4, 0, hollow, 1.f, split);
+ addHole(params, true, 4, 0, hollow, 1.f, split);
break;
case LL_PCODE_HOLE_TRIANGLE:
- addHole(params, TRUE, 3, 0, hollow, 1.f, split);
+ addHole(params, true, 3, 0, hollow, 1.f, split);
break;
case LL_PCODE_HOLE_CIRCLE:
case LL_PCODE_HOLE_SAME:
default:
- addHole(params, FALSE, circle_detail, 0, hollow, 1.f);
+ addHole(params, true, circle_detail, 0, hollow, 1.f);
break;
}
}
@@ -965,11 +942,11 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
}
if (mOpen && !params.getHollow())
{
- addFace(0,mTotal-1,0,LL_FACE_OUTER_SIDE_0, FALSE);
+ addFace(0,mTotal-1,0,LL_FACE_OUTER_SIDE_0, false);
}
else
{
- addFace(0,mTotal,0,LL_FACE_OUTER_SIDE_0, FALSE);
+ addFace(0,mTotal,0,LL_FACE_OUTER_SIDE_0, false);
}
if (hollow)
@@ -977,15 +954,15 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
switch (hole_type)
{
case LL_PCODE_HOLE_SQUARE:
- addHole(params, TRUE, 2, 0.5f, hollow, 0.5f, split);
+ addHole(params, true, 2, 0.5f, hollow, 0.5f, split);
break;
case LL_PCODE_HOLE_TRIANGLE:
- addHole(params, TRUE, 3, 0.5f, hollow, 0.5f, split);
+ addHole(params, true, 3, 0.5f, hollow, 0.5f, split);
break;
case LL_PCODE_HOLE_CIRCLE:
case LL_PCODE_HOLE_SAME:
default:
- addHole(params, FALSE, circle_detail, 0.5f, hollow, 0.5f);
+ addHole(params, false, circle_detail, 0.5f, hollow, 0.5f);
break;
}
}
@@ -993,11 +970,11 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
// Special case for openness of sphere
if ((params.getEnd() - params.getBegin()) < 1.f)
{
- mOpen = TRUE;
+ mOpen = true;
}
else if (!hollow)
{
- mOpen = FALSE;
+ mOpen = false;
mProfile.push_back(mProfile[0]);
mTotal++;
}
@@ -1015,24 +992,24 @@ BOOL LLProfile::generate(const LLProfileParams& params, BOOL path_open,F32 detai
if ( mOpen) // interior edge caps
{
- addFace(mTotal-1, 2,0.5,LL_FACE_PROFILE_BEGIN, TRUE);
+ addFace(mTotal-1, 2,0.5,LL_FACE_PROFILE_BEGIN, true);
if (hollow)
{
- addFace(mTotalOut-1, 2,0.5,LL_FACE_PROFILE_END, TRUE);
+ addFace(mTotalOut-1, 2,0.5,LL_FACE_PROFILE_END, true);
}
else
{
- addFace(mTotal-2, 2,0.5,LL_FACE_PROFILE_END, TRUE);
+ addFace(mTotal-2, 2,0.5,LL_FACE_PROFILE_END, true);
}
}
- return TRUE;
+ return true;
}
-BOOL LLProfileParams::importFile(LLFILE *fp)
+bool LLProfileParams::importFile(LLFILE *fp)
{
const S32 BUFSIZE = 16384;
char buffer[BUFSIZE]; /* Flawfinder: ignore */
@@ -1090,11 +1067,11 @@ BOOL LLProfileParams::importFile(LLFILE *fp)
}
}
- return TRUE;
+ return true;
}
-BOOL LLProfileParams::exportFile(LLFILE *fp) const
+bool LLProfileParams::exportFile(LLFILE *fp) const
{
fprintf(fp,"\t\tprofile 0\n");
fprintf(fp,"\t\t{\n");
@@ -1103,11 +1080,11 @@ BOOL LLProfileParams::exportFile(LLFILE *fp) const
fprintf(fp,"\t\t\tend\t%g\n", getEnd());
fprintf(fp,"\t\t\thollow\t%g\n", getHollow());
fprintf(fp, "\t\t}\n");
- return TRUE;
+ return true;
}
-BOOL LLProfileParams::importLegacyStream(std::istream& input_stream)
+bool LLProfileParams::importLegacyStream(std::istream& input_stream)
{
const S32 BUFSIZE = 16384;
char buffer[BUFSIZE]; /* Flawfinder: ignore */
@@ -1162,11 +1139,11 @@ BOOL LLProfileParams::importLegacyStream(std::istream& input_stream)
}
}
- return TRUE;
+ return true;
}
-BOOL LLProfileParams::exportLegacyStream(std::ostream& output_stream) const
+bool LLProfileParams::exportLegacyStream(std::ostream& output_stream) const
{
output_stream <<"\t\tprofile 0\n";
output_stream <<"\t\t{\n";
@@ -1175,7 +1152,7 @@ BOOL LLProfileParams::exportLegacyStream(std::ostream& output_stream) const
output_stream <<"\t\t\tend\t" << getEnd() << "\n";
output_stream <<"\t\t\thollow\t" << getHollow() << "\n";
output_stream << "\t\t}\n";
- return TRUE;
+ return true;
}
LLSD LLProfileParams::asLLSD() const
@@ -1242,7 +1219,7 @@ void LLPath::genNGon(const LLPathParams& params, S32 sides, F32 startOff, F32 en
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME
// Generates a circular path, starting at (1, 0, 0), counterclockwise along the xz plane.
- static const F32 tableScale[] = { 1, 1, 1, 0.5f, 0.707107f, 0.53f, 0.525f, 0.5f };
+ constexpr F32 tableScale[] = { 1, 1, 1, 0.5f, 0.707107f, 0.53f, 0.525f, 0.5f };
F32 revolutions = params.getRevolutions();
F32 skew = params.getSkew();
@@ -1472,14 +1449,14 @@ S32 LLPath::getNumPoints(const LLPathParams& params, F32 detail)
return np;
}
-BOOL LLPath::generate(const LLPathParams& params, F32 detail, S32 split,
- BOOL is_sculpted, S32 sculpt_size)
+bool LLPath::generate(const LLPathParams& params, F32 detail, S32 split,
+ bool is_sculpted, S32 sculpt_size)
{
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME
if ((!mDirty) && (!is_sculpted))
{
- return FALSE;
+ return false;
}
if (detail < MIN_LOD)
@@ -1488,11 +1465,11 @@ BOOL LLPath::generate(const LLPathParams& params, F32 detail, S32 split,
detail = MIN_LOD;
}
- mDirty = FALSE;
+ mDirty = false;
S32 np = 2; // hardcode for line
mPath.resize(0);
- mOpen = TRUE;
+ mOpen = true;
// Is this 0xf0 mask really necessary? DK 03/02/05
switch (params.getCurveType() & 0xf0)
@@ -1552,7 +1529,7 @@ BOOL LLPath::generate(const LLPathParams& params, F32 detail, S32 split,
if (params.getEnd() - params.getBegin() >= 0.99f &&
params.getScaleX() >= .99f)
{
- mOpen = FALSE;
+ mOpen = false;
}
//genNGon(params, llfloor(MIN_DETAIL_FACES * detail), 4.f, 0.f);
@@ -1596,19 +1573,19 @@ BOOL LLPath::generate(const LLPathParams& params, F32 detail, S32 split,
break;
};
- if (params.getTwist() != params.getTwistBegin()) mOpen = TRUE;
+ if (params.getTwist() != params.getTwistBegin()) mOpen = true;
//if ((int(fabsf(params.getTwist() - params.getTwistBegin())*100))%100 != 0) {
- // mOpen = TRUE;
+ // mOpen = true;
//}
- return TRUE;
+ return true;
}
-BOOL LLDynamicPath::generate(const LLPathParams& params, F32 detail, S32 split,
- BOOL is_sculpted, S32 sculpt_size)
+bool LLDynamicPath::generate(const LLPathParams& params, F32 detail, S32 split,
+ bool is_sculpted, S32 sculpt_size)
{
- mOpen = TRUE; // Draw end caps
+ mOpen = true; // Draw end caps
if (getPathLength() == 0)
{
// Path hasn't been generated yet.
@@ -1627,11 +1604,11 @@ BOOL LLDynamicPath::generate(const LLPathParams& params, F32 detail, S32 split,
}
}
- return TRUE;
+ return true;
}
-BOOL LLPathParams::importFile(LLFILE *fp)
+bool LLPathParams::importFile(LLFILE *fp)
{
const S32 BUFSIZE = 16384;
char buffer[BUFSIZE]; /* Flawfinder: ignore */
@@ -1746,11 +1723,11 @@ BOOL LLPathParams::importFile(LLFILE *fp)
LL_WARNS() << "unknown keyword " << " in path import" << LL_ENDL;
}
}
- return TRUE;
+ return true;
}
-BOOL LLPathParams::exportFile(LLFILE *fp) const
+bool LLPathParams::exportFile(LLFILE *fp) const
{
fprintf(fp, "\t\tpath 0\n");
fprintf(fp, "\t\t{\n");
@@ -1771,11 +1748,11 @@ BOOL LLPathParams::exportFile(LLFILE *fp) const
fprintf(fp,"\t\t\tskew\t%g\n", getSkew());
fprintf(fp, "\t\t}\n");
- return TRUE;
+ return true;
}
-BOOL LLPathParams::importLegacyStream(std::istream& input_stream)
+bool LLPathParams::importLegacyStream(std::istream& input_stream)
{
const S32 BUFSIZE = 16384;
char buffer[BUFSIZE]; /* Flawfinder: ignore */
@@ -1886,11 +1863,11 @@ BOOL LLPathParams::importLegacyStream(std::istream& input_stream)
LL_WARNS() << "unknown keyword " << " in path import" << LL_ENDL;
}
}
- return TRUE;
+ return true;
}
-BOOL LLPathParams::exportLegacyStream(std::ostream& output_stream) const
+bool LLPathParams::exportLegacyStream(std::ostream& output_stream) const
{
output_stream << "\t\tpath 0\n";
output_stream << "\t\t{\n";
@@ -1911,7 +1888,7 @@ BOOL LLPathParams::exportLegacyStream(std::ostream& output_stream) const
output_stream <<"\t\t\tskew\t" << getSkew() << "\n";
output_stream << "\t\t}\n";
- return TRUE;
+ return true;
}
LLSD LLPathParams::asLLSD() const
@@ -1976,7 +1953,7 @@ LLProfile::~LLProfile()
S32 LLVolume::sNumMeshPoints = 0;
-LLVolume::LLVolume(const LLVolumeParams &params, const F32 detail, const BOOL generate_single_face, const BOOL is_unique)
+LLVolume::LLVolume(const LLVolumeParams &params, const F32 detail, const bool generate_single_face, const bool is_unique)
: mParams(params)
{
mUnique = is_unique;
@@ -1987,8 +1964,8 @@ LLVolume::LLVolume(const LLVolumeParams &params, const F32 detail, const BOOL ge
mIsMeshAssetLoaded = false;
mIsMeshAssetUnavaliable = false;
mLODScaleBias.setVec(1,1,1);
- mHullPoints = NULL;
- mHullIndices = NULL;
+ mHullPoints = nullptr;
+ mHullIndices = nullptr;
mNumHullPoints = 0;
mNumHullIndices = 0;
@@ -2050,7 +2027,7 @@ LLVolume::~LLVolume()
mHullIndices = NULL;
}
-BOOL LLVolume::generate()
+bool LLVolume::generate()
{
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME
@@ -2094,8 +2071,8 @@ BOOL LLVolume::generate()
}
}
- BOOL regenPath = mPathp->generate(mParams.getPathParams(), path_detail, split);
- BOOL regenProf = mProfilep->generate(mParams.getProfileParams(), mPathp->isOpen(),profile_detail, split);
+ bool regenPath = mPathp->generate(mParams.getPathParams(), path_detail, split);
+ bool regenProf = mProfilep->generate(mParams.getProfileParams(), mPathp->isOpen(),profile_detail, split);
if (regenPath || regenProf )
{
@@ -2158,11 +2135,11 @@ BOOL LLVolume::generate()
mFaceMask |= id;
}
LL_CHECK_MEMORY
- return TRUE;
+ return true;
}
LL_CHECK_MEMORY
- return FALSE;
+ return false;
}
void LLVolumeFace::VertexData::init()
@@ -2343,7 +2320,7 @@ bool LLVolume::unpackVolumeFaces(U8* in_data, S32 size)
bool LLVolume::unpackVolumeFacesInternal(const LLSD& mdl)
{
{
- U32 face_count = mdl.size();
+ auto face_count = mdl.size();
if (face_count == 0)
{ //no faces unpacked, treat as failed decode
@@ -2375,7 +2352,7 @@ bool LLVolume::unpackVolumeFacesInternal(const LLSD& mdl)
LLSD::Binary idx = mdl[i]["TriangleList"];
//copy out indices
- S32 num_indices = idx.size() / 2;
+ auto num_indices = idx.size() / 2;
const S32 indices_to_discard = num_indices % 3;
if (indices_to_discard > 0)
{
@@ -2383,7 +2360,7 @@ bool LLVolume::unpackVolumeFacesInternal(const LLSD& mdl)
LL_WARNS() << "Incomplete triangle discarded from face! Indices count " << num_indices << " was not divisible by 3. face index: " << i << " Total: " << face_count << LL_ENDL;
num_indices -= indices_to_discard;
}
- face.resizeIndices(num_indices);
+ face.resizeIndices(static_cast<S32>(num_indices));
if (num_indices > 2 && !face.mIndices)
{
@@ -2404,7 +2381,7 @@ bool LLVolume::unpackVolumeFacesInternal(const LLSD& mdl)
}
//copy out vertices
- U32 num_verts = pos.size()/(3*2);
+ U32 num_verts = static_cast<U32>(pos.size())/(3*2);
face.resizeVertices(num_verts);
if (num_verts > 0 && !face.mPositions)
@@ -2668,7 +2645,7 @@ bool LLVolume::unpackVolumeFacesInternal(const LLSD& mdl)
if (do_reverse_triangles)
{
- for (U32 j = 0; j < face.mNumIndices; j += 3)
+ for (S32 j = 0; j < face.mNumIndices; j += 3)
{
// swap the 2nd and 3rd index
S32 swap = face.mIndices[j+1];
@@ -2705,7 +2682,7 @@ bool LLVolume::unpackVolumeFacesInternal(const LLSD& mdl)
min_tc = face.mTexCoords[0];
max_tc = face.mTexCoords[0];
- for (U32 j = 1; j < face.mNumVertices; ++j)
+ for (S32 j = 1; j < face.mNumVertices; ++j)
{
update_min_max(min_tc, max_tc, face.mTexCoords[j]);
}
@@ -2808,10 +2785,10 @@ void LLVolume::createVolumeFaces()
else
{
S32 num_faces = getNumFaces();
- BOOL partial_build = TRUE;
+ bool partial_build = true;
if (num_faces != mVolumeFaces.size())
{
- partial_build = FALSE;
+ partial_build = false;
mVolumeFaces.resize(num_faces);
}
// Initialize volume faces with parameter data
@@ -3046,9 +3023,9 @@ void LLVolume::sculptGenerateSpherePlaceholder()
void LLVolume::sculptGenerateMapVertices(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components, const U8* sculpt_data, U8 sculpt_type)
{
U8 sculpt_stitching = sculpt_type & LL_SCULPT_TYPE_MASK;
- BOOL sculpt_invert = sculpt_type & LL_SCULPT_FLAG_INVERT;
- BOOL sculpt_mirror = sculpt_type & LL_SCULPT_FLAG_MIRROR;
- BOOL reverse_horizontal = (sculpt_invert ? !sculpt_mirror : sculpt_mirror); // XOR
+ bool sculpt_invert = sculpt_type & LL_SCULPT_FLAG_INVERT;
+ bool sculpt_mirror = sculpt_type & LL_SCULPT_FLAG_MIRROR;
+ bool reverse_horizontal = (sculpt_invert ? !sculpt_mirror : sculpt_mirror); // XOR
S32 sizeS = mPathp->mPath.size();
S32 sizeT = mProfilep->mProfile.size();
@@ -3133,14 +3110,13 @@ void LLVolume::sculptGenerateMapVertices(U16 sculpt_width, U16 sculpt_height, S8
}
-const S32 SCULPT_REZ_1 = 6; // changed from 4 to 6 - 6 looks round whereas 4 looks square
-const S32 SCULPT_REZ_2 = 8;
-const S32 SCULPT_REZ_3 = 16;
-const S32 SCULPT_REZ_4 = 32;
+constexpr S32 SCULPT_REZ_1 = 6; // changed from 4 to 6 - 6 looks round whereas 4 looks square
+constexpr S32 SCULPT_REZ_2 = 8;
+constexpr S32 SCULPT_REZ_3 = 16;
+constexpr S32 SCULPT_REZ_4 = 32;
S32 sculpt_sides(F32 detail)
{
-
// detail is usually one of: 1, 1.5, 2.5, 4.0.
if (detail <= 1.0)
@@ -3203,12 +3179,12 @@ void LLVolume::sculpt(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components,
{
U8 sculpt_type = mParams.getSculptType();
- BOOL data_is_empty = FALSE;
+ bool data_is_empty = false;
if (sculpt_width == 0 || sculpt_height == 0 || sculpt_components < 3 || sculpt_data == NULL)
{
sculpt_level = -1;
- data_is_empty = TRUE;
+ data_is_empty = true;
}
S32 requested_sizeS = 0;
@@ -3216,8 +3192,8 @@ void LLVolume::sculpt(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components,
sculpt_calc_mesh_resolution(sculpt_width, sculpt_height, sculpt_type, mDetail, requested_sizeS, requested_sizeT);
- mPathp->generate(mParams.getPathParams(), mDetail, 0, TRUE, requested_sizeS);
- mProfilep->generate(mParams.getProfileParams(), mPathp->isOpen(), mDetail, 0, TRUE, requested_sizeT);
+ mPathp->generate(mParams.getPathParams(), mDetail, 0, true, requested_sizeS);
+ mProfilep->generate(mParams.getProfileParams(), mPathp->isOpen(), mDetail, 0, true, requested_sizeT);
S32 sizeS = mPathp->mPath.size(); // we requested a specific size, now see what we really got
S32 sizeT = mProfilep->mProfile.size(); // we requested a specific size, now see what we really got
@@ -3248,7 +3224,7 @@ void LLVolume::sculpt(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components,
if (area < SCULPT_MIN_AREA || area > SCULPT_MAX_AREA)
{
- data_is_empty = TRUE;
+ data_is_empty = true;
visible_placeholder = true;
}
}
@@ -3267,8 +3243,6 @@ void LLVolume::sculpt(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components,
}
}
-
-
for (S32 i = 0; i < (S32)mProfilep->mFaces.size(); i++)
{
mFaceMask |= mProfilep->mFaces[i].mFaceID;
@@ -3285,12 +3259,12 @@ void LLVolume::sculpt(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components,
-BOOL LLVolume::isCap(S32 face)
+bool LLVolume::isCap(S32 face)
{
return mProfilep->mFaces[face].mCap;
}
-BOOL LLVolume::isFlat(S32 face)
+bool LLVolume::isFlat(S32 face)
{
return mProfilep->mFaces[face].mFlat;
}
@@ -3353,7 +3327,7 @@ void LLVolumeParams::copyParams(const LLVolumeParams &params)
}
// Less restricitve approx 0 for volumes
-const F32 APPROXIMATELY_ZERO = 0.001f;
+constexpr F32 APPROXIMATELY_ZERO = 0.001f;
bool approx_zero( F32 f, F32 tolerance = APPROXIMATELY_ZERO)
{
return (f >= -tolerance) && (f <= tolerance);
@@ -3609,7 +3583,7 @@ bool LLVolumeParams::setSkew(const F32 skew_value)
return valid;
}
-bool LLVolumeParams::setSculptID(const LLUUID sculpt_id, U8 sculpt_type)
+bool LLVolumeParams::setSculptID(const LLUUID& sculpt_id, U8 sculpt_type)
{
mSculptID = sculpt_id;
mSculptType = sculpt_type;
@@ -3804,7 +3778,7 @@ void LLVolume::generateSilhouetteVertices(std::vector<LLVector3> &vertices,
LLVector4a* v = (LLVector4a*)face.mPositions;
LLVector4a* n = (LLVector4a*)face.mNormals;
- for (U32 j = 0; j < face.mNumIndices / 3; j++)
+ for (S32 j = 0; j < face.mNumIndices / 3; j++)
{
for (S32 k = 0; k < 3; k++)
{
@@ -3839,7 +3813,6 @@ void LLVolume::generateSilhouetteVertices(std::vector<LLVector3> &vertices,
}
else
{
-
//==============================================
//DEBUG draw edge map instead of silhouette edge
//==============================================
@@ -3921,8 +3894,8 @@ void LLVolume::generateSilhouetteVertices(std::vector<LLVector3> &vertices,
//DEBUG
//==============================================
- static const U8 AWAY = 0x01,
- TOWARDS = 0x02;
+ constexpr U8 AWAY = 0x01,
+ TOWARDS = 0x02;
//for each triangle
std::vector<U8> fFacing;
@@ -3931,7 +3904,7 @@ void LLVolume::generateSilhouetteVertices(std::vector<LLVector3> &vertices,
LLVector4a* v = (LLVector4a*) face.mPositions;
LLVector4a* n = (LLVector4a*) face.mNormals;
- for (U32 j = 0; j < face.mNumIndices/3; j++)
+ for (S32 j = 0; j < face.mNumIndices/3; j++)
{
//approximate normal
S32 v1 = face.mIndices[j*3+0];
@@ -3968,7 +3941,7 @@ void LLVolume::generateSilhouetteVertices(std::vector<LLVector3> &vertices,
}
//for each triangle
- for (U32 j = 0; j < face.mNumIndices/3; j++)
+ for (S32 j = 0; j < face.mNumIndices/3; j++)
{
if (fFacing[j] == (AWAY | TOWARDS))
{ //this is a degenerate triangle
@@ -4192,7 +4165,7 @@ LLVertexIndexPair::LLVertexIndexPair(const LLVector3 &vertex, const S32 index)
mIndex = index;
}
-const F32 VERTEX_SLOP = 0.00001f;
+constexpr F32 VERTEX_SLOP = 0.00001f;
struct lessVertex
{
@@ -4202,32 +4175,32 @@ struct lessVertex
if (a->mVertex.mV[0] + slop < b->mVertex.mV[0])
{
- return TRUE;
+ return true;
}
else if (a->mVertex.mV[0] - slop > b->mVertex.mV[0])
{
- return FALSE;
+ return false;
}
if (a->mVertex.mV[1] + slop < b->mVertex.mV[1])
{
- return TRUE;
+ return true;
}
else if (a->mVertex.mV[1] - slop > b->mVertex.mV[1])
{
- return FALSE;
+ return false;
}
if (a->mVertex.mV[2] + slop < b->mVertex.mV[2])
{
- return TRUE;
+ return true;
}
else if (a->mVertex.mV[2] - slop > b->mVertex.mV[2])
{
- return FALSE;
+ return false;
}
- return FALSE;
+ return false;
}
};
@@ -4237,45 +4210,45 @@ struct lessTriangle
{
if (*a < *b)
{
- return TRUE;
+ return true;
}
else if (*a > *b)
{
- return FALSE;
+ return false;
}
if (*(a+1) < *(b+1))
{
- return TRUE;
+ return true;
}
else if (*(a+1) > *(b+1))
{
- return FALSE;
+ return false;
}
if (*(a+2) < *(b+2))
{
- return TRUE;
+ return true;
}
else if (*(a+2) > *(b+2))
{
- return FALSE;
+ return false;
}
- return FALSE;
+ return false;
}
};
-BOOL equalTriangle(const S32 *a, const S32 *b)
+bool equalTriangle(const S32 *a, const S32 *b)
{
if ((*a == *b) && (*(a+1) == *(b+1)) && (*(a+2) == *(b+2)))
{
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
-BOOL LLVolumeParams::importFile(LLFILE *fp)
+bool LLVolumeParams::importFile(LLFILE *fp)
{
//LL_INFOS() << "importing volume" << LL_ENDL;
const S32 BUFSIZE = 16384;
@@ -4315,21 +4288,21 @@ BOOL LLVolumeParams::importFile(LLFILE *fp)
}
}
- return TRUE;
+ return true;
}
-BOOL LLVolumeParams::exportFile(LLFILE *fp) const
+bool LLVolumeParams::exportFile(LLFILE *fp) const
{
fprintf(fp,"\tshape 0\n");
fprintf(fp,"\t{\n");
mPathParams.exportFile(fp);
mProfileParams.exportFile(fp);
fprintf(fp, "\t}\n");
- return TRUE;
+ return true;
}
-BOOL LLVolumeParams::importLegacyStream(std::istream& input_stream)
+bool LLVolumeParams::importLegacyStream(std::istream& input_stream)
{
//LL_INFOS() << "importing volume" << LL_ENDL;
const S32 BUFSIZE = 16384;
@@ -4365,17 +4338,17 @@ BOOL LLVolumeParams::importLegacyStream(std::istream& input_stream)
}
}
- return TRUE;
+ return true;
}
-BOOL LLVolumeParams::exportLegacyStream(std::ostream& output_stream) const
+bool LLVolumeParams::exportLegacyStream(std::ostream& output_stream) const
{
output_stream <<"\tshape 0\n";
output_stream <<"\t{\n";
mPathParams.exportLegacyStream(output_stream);
mProfileParams.exportLegacyStream(output_stream);
output_stream << "\t}\n";
- return TRUE;
+ return true;
}
LLSD LLVolumeParams::sculptAsLLSD() const
@@ -4447,14 +4420,14 @@ void LLVolumeParams::reduceT(F32 begin, F32 end)
const F32 MIN_CONCAVE_PROFILE_WEDGE = 0.125f; // 1/8 unity
const F32 MIN_CONCAVE_PATH_WEDGE = 0.111111f; // 1/9 unity
-// returns TRUE if the shape can be approximated with a convex shape
+// returns true if the shape can be approximated with a convex shape
// for collison purposes
-BOOL LLVolumeParams::isConvex() const
+bool LLVolumeParams::isConvex() const
{
if (!getSculptID().isNull())
{
// can't determine, be safe and say no:
- return FALSE;
+ return false;
}
F32 path_length = mPathParams.getEnd() - mPathParams.getBegin();
@@ -4467,11 +4440,11 @@ BOOL LLVolumeParams::isConvex() const
&& LL_PCODE_PATH_LINE != path_type) ) )
{
// twist along a "not too short" path is concave
- return FALSE;
+ return false;
}
F32 profile_length = mProfileParams.getEnd() - mProfileParams.getBegin();
- BOOL same_hole = hollow == 0.f
+ bool same_hole = hollow == 0.f
|| (mProfileParams.getCurveType() & LL_PCODE_HOLE_MASK) == LL_PCODE_HOLE_SAME;
F32 min_profile_wedge = MIN_CONCAVE_PROFILE_WEDGE;
@@ -4482,7 +4455,7 @@ BOOL LLVolumeParams::isConvex() const
min_profile_wedge = 2.f * MIN_CONCAVE_PROFILE_WEDGE;
}
- BOOL convex_profile = ( ( profile_length == 1.f
+ bool convex_profile = ( ( profile_length == 1.f
|| profile_length <= 0.5f )
&& hollow == 0.f ) // trivially convex
|| ( profile_length <= min_profile_wedge
@@ -4491,36 +4464,36 @@ BOOL LLVolumeParams::isConvex() const
if (!convex_profile)
{
// profile is concave
- return FALSE;
+ return false;
}
if ( LL_PCODE_PATH_LINE == path_type )
{
// straight paths with convex profile
- return TRUE;
+ return true;
}
- BOOL concave_path = (path_length < 1.0f) && (path_length > 0.5f);
+ bool concave_path = (path_length < 1.0f) && (path_length > 0.5f);
if (concave_path)
{
- return FALSE;
+ return false;
}
// we're left with spheres, toroids and tubes
if ( LL_PCODE_PROFILE_CIRCLE_HALF == profile_type )
{
// at this stage all spheres must be convex
- return TRUE;
+ return true;
}
// it's a toroid or tube
if ( path_length <= MIN_CONCAVE_PATH_WEDGE )
{
// effectively convex
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
// debug
@@ -4598,7 +4571,7 @@ LLFaceID LLVolume::generateFaceMask()
return new_mask;
}
-BOOL LLVolume::isFaceMaskValid(LLFaceID face_mask)
+bool LLVolume::isFaceMaskValid(LLFaceID face_mask)
{
LLFaceID test_mask = 0;
for(S32 i = 0; i < getNumFaces(); i++)
@@ -4609,9 +4582,9 @@ BOOL LLVolume::isFaceMaskValid(LLFaceID face_mask)
return test_mask == face_mask;
}
-BOOL LLVolume::isConvex() const
+bool LLVolume::isConvex() const
{
- // mParams.isConvex() may return FALSE even though the final
+ // mParams.isConvex() may return false even though the final
// geometry is actually convex due to LOD approximations.
// TODO -- provide LLPath and LLProfile with isConvex() methods
// that correctly determine convexity. -- Leviathan
@@ -4717,10 +4690,10 @@ LLVolumeFace::LLVolumeFace() :
mJustWeights(NULL),
mJointIndices(NULL),
#endif
- mWeightsScrubbed(FALSE),
+ mWeightsScrubbed(false),
mOctree(NULL),
mOctreeTriangles(NULL),
- mOptimized(FALSE)
+ mOptimized(false)
{
mExtents = (LLVector4a*) ll_aligned_malloc_16(sizeof(LLVector4a)*3);
mExtents[0].splat(-0.5f);
@@ -4748,7 +4721,7 @@ LLVolumeFace::LLVolumeFace(const LLVolumeFace& src)
mJustWeights(NULL),
mJointIndices(NULL),
#endif
- mWeightsScrubbed(FALSE),
+ mWeightsScrubbed(false),
mOctree(NULL),
mOctreeTriangles(NULL)
{
@@ -4822,7 +4795,7 @@ LLVolumeFace& LLVolumeFace::operator=(const LLVolumeFace& src)
{
ll_aligned_free_16(mWeights);
mWeights = NULL;
- mWeightsScrubbed = FALSE;
+ mWeightsScrubbed = false;
}
#if USE_SEPARATE_JOINT_INDICES_AND_WEIGHTS
@@ -4895,7 +4868,7 @@ void LLVolumeFace::freeData()
destroyOctree();
}
-BOOL LLVolumeFace::create(LLVolume* volume, BOOL partial_build)
+bool LLVolumeFace::create(LLVolume* volume, bool partial_build)
{
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME
@@ -4903,7 +4876,7 @@ BOOL LLVolumeFace::create(LLVolume* volume, BOOL partial_build)
destroyOctree();
LL_CHECK_MEMORY
- BOOL ret = FALSE ;
+ bool ret = false ;
if (mTypeMask & CAP_MASK)
{
ret = createCap(volume, partial_build);
@@ -4970,13 +4943,13 @@ void LLVolumeFace::remap()
{
// Generate a remap buffer
std::vector<unsigned int> remap(mNumVertices);
- S32 remap_vertices_count = LLMeshOptimizer::generateRemapMultiU16(&remap[0],
+ S32 remap_vertices_count = static_cast<S32>(LLMeshOptimizer::generateRemapMultiU16(&remap[0],
mIndices,
mNumIndices,
mPositions,
mNormals,
mTexCoords,
- mNumVertices);
+ mNumVertices));
// Allocate new buffers
S32 size = ((mNumIndices * sizeof(U16)) + 0xF) & ~0xF;
@@ -5021,7 +4994,7 @@ void LLVolumeFace::optimize(F32 angle_cutoff)
range.setSub(mExtents[1],mExtents[0]);
//remove redundant vertices
- for (U32 i = 0; i < mNumIndices; ++i)
+ for (S32 i = 0; i < mNumIndices; ++i)
{
U16 index = mIndices[i];
@@ -5039,7 +5012,7 @@ void LLVolumeFace::optimize(F32 angle_cutoff)
LLVolumeFace::VertexData cv;
getVertexData(index, cv);
- BOOL found = FALSE;
+ bool found = false;
LLVector4a pos;
pos.setSub(mPositions[index], mExtents[0]);
@@ -5060,7 +5033,7 @@ void LLVolumeFace::optimize(F32 angle_cutoff)
LLVolumeFace::VertexData& tv = (point_iter->second)[j];
if (tv.compareNormal(cv, angle_cutoff))
{
- found = TRUE;
+ found = true;
new_face.pushIndex((point_iter->second)[j].mIndex);
break;
}
@@ -5167,12 +5140,12 @@ public:
}
};
-const F64 FindVertexScore_CacheDecayPower = 1.5;
-const F64 FindVertexScore_LastTriScore = 0.75;
-const F64 FindVertexScore_ValenceBoostScale = 2.0;
-const F64 FindVertexScore_ValenceBoostPower = 0.5;
-const U32 MaxSizeVertexCache = 32;
-const F64 FindVertexScore_Scaler = 1.0/(MaxSizeVertexCache-3);
+constexpr F64 FindVertexScore_CacheDecayPower = 1.5;
+constexpr F64 FindVertexScore_LastTriScore = 0.75;
+constexpr F64 FindVertexScore_ValenceBoostScale = 2.0;
+constexpr F64 FindVertexScore_ValenceBoostPower = 0.5;
+constexpr U32 MaxSizeVertexCache = 32;
+constexpr F64 FindVertexScore_Scaler = 1.0/(MaxSizeVertexCache-3);
F64 find_vertex_score(LLVCacheVertexData& data)
{
@@ -5407,7 +5380,7 @@ struct MikktData
LLVector3 inv_scale(1.f / face->mNormalizedScale.mV[0], 1.f / face->mNormalizedScale.mV[1], 1.f / face->mNormalizedScale.mV[2]);
- for (int i = 0; i < face->mNumIndices; ++i)
+ for (S32 i = 0; i < face->mNumIndices; ++i)
{
U32 idx = face->mIndices[i];
@@ -5418,17 +5391,6 @@ struct MikktData
n[i].normalize();
tc[i].set(face->mTexCoords[idx]);
- if (idx >= face->mNumVertices)
- {
- // invalid index
- // replace with a valid index to avoid crashes
- idx = face->mNumVertices - 1;
- face->mIndices[i] = idx;
-
- // Needs better logging
- LL_DEBUGS_ONCE("LLVOLUME") << "Invalid index, substituting" << LL_ENDL;
- }
-
if (face->mWeights)
{
w[i].set(face->mWeights[idx].getF32ptr());
@@ -5475,7 +5437,7 @@ bool LLVolumeFace::cacheOptimize(bool gen_tangents)
{ //optimize for vertex cache according to Forsyth method:
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME;
llassert(!mOptimized);
- mOptimized = TRUE;
+ mOptimized = true;
if (gen_tangents && mNormals && mTexCoords)
{ // generate mikkt space tangents before cache optimizing since the index buffer may change
@@ -5500,7 +5462,7 @@ bool LLVolumeFace::cacheOptimize(bool gen_tangents)
U32 stream_count = data.w.empty() ? 4 : 5;
- size_t vert_count = meshopt_generateVertexRemapMulti(&remap[0], nullptr, data.p.size(), data.p.size(), mos, stream_count);
+ S32 vert_count = static_cast<S32>(meshopt_generateVertexRemapMulti(&remap[0], nullptr, data.p.size(), data.p.size(), mos, stream_count));
if (vert_count < 65535 && vert_count != 0)
{
@@ -5514,11 +5476,11 @@ bool LLVolumeFace::cacheOptimize(bool gen_tangents)
allocateTangents(mNumVertices);
- for (int i = 0; i < mNumIndices; ++i)
+ for (S32 i = 0; i < mNumIndices; ++i)
{
U32 src_idx = i;
U32 dst_idx = remap[i];
- if (dst_idx >= mNumVertices)
+ if (dst_idx >= (U32)mNumVertices)
{
dst_idx = mNumVertices - 1;
// Shouldn't happen, figure out what gets returned in remap and why.
@@ -5545,7 +5507,7 @@ bool LLVolumeFace::cacheOptimize(bool gen_tangents)
scale.load3(mNormalizedScale.mV);
scale.getF32ptr()[3] = 1.f;
- for (int i = 0; i < mNumVertices; ++i)
+ for (S32 i = 0; i < mNumVertices; ++i)
{
mPositions[i].mul(inv_scale);
mNormals[i].mul(scale);
@@ -5706,7 +5668,7 @@ void LerpPlanarVertex(LLVolumeFace::VertexData& v0,
vout.setNormal(v0.getNormal());
}
-BOOL LLVolumeFace::createUnCutCubeCap(LLVolume* volume, BOOL partial_build)
+bool LLVolumeFace::createUnCutCubeCap(LLVolume* volume, bool partial_build)
{
LL_CHECK_MEMORY
@@ -5938,11 +5900,11 @@ BOOL LLVolumeFace::createUnCutCubeCap(LLVolume* volume, BOOL partial_build)
}
LL_CHECK_MEMORY
- return TRUE;
+ return true;
}
-BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
+bool LLVolumeFace::createCap(LLVolume* volume, bool partial_build)
{
if (!(mTypeMask & HOLLOW_MASK) &&
!(mTypeMask & OPEN_MASK) &&
@@ -6099,7 +6061,7 @@ BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
//if (partial_build)
//{
- // return TRUE;
+ // return true;
//}
if (mTypeMask & HOLLOW_MASK)
@@ -6148,36 +6110,36 @@ BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
(paV[0]*pbV[1] - pbV[0]*paV[1]) +
(pbV[0]*p2V[1] - p2V[0]*pbV[1]);
- BOOL use_tri1a2 = TRUE;
- BOOL tri_1a2 = TRUE;
- BOOL tri_21b = TRUE;
+ bool use_tri1a2 = true;
+ bool tri_1a2 = true;
+ bool tri_21b = true;
if (area_1a2 < 0)
{
- tri_1a2 = FALSE;
+ tri_1a2 = false;
}
if (area_2ab < 0)
{
// Can't use, because it contains point b
- tri_1a2 = FALSE;
+ tri_1a2 = false;
}
if (area_21b < 0)
{
- tri_21b = FALSE;
+ tri_21b = false;
}
if (area_1ba < 0)
{
// Can't use, because it contains point b
- tri_21b = FALSE;
+ tri_21b = false;
}
if (!tri_1a2)
{
- use_tri1a2 = FALSE;
+ use_tri1a2 = false;
}
else if (!tri_21b)
{
- use_tri1a2 = TRUE;
+ use_tri1a2 = true;
}
else
{
@@ -6189,11 +6151,11 @@ BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
if (d1.dot3(d1) < d2.dot3(d2))
{
- use_tri1a2 = TRUE;
+ use_tri1a2 = true;
}
else
{
- use_tri1a2 = FALSE;
+ use_tri1a2 = false;
}
}
@@ -6254,36 +6216,36 @@ BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
(paV[0]*pbV[1] - pbV[0]*paV[1]) +
(pbV[0]*p2V[1] - p2V[0]*pbV[1]);
- BOOL use_tri1a2 = TRUE;
- BOOL tri_1a2 = TRUE;
- BOOL tri_21b = TRUE;
+ bool use_tri1a2 = true;
+ bool tri_1a2 = true;
+ bool tri_21b = true;
if (area_1a2 < 0)
{
- tri_1a2 = FALSE;
+ tri_1a2 = false;
}
if (area_2ab < 0)
{
// Can't use, because it contains point b
- tri_1a2 = FALSE;
+ tri_1a2 = false;
}
if (area_21b < 0)
{
- tri_21b = FALSE;
+ tri_21b = false;
}
if (area_1ba < 0)
{
// Can't use, because it contains point b
- tri_21b = FALSE;
+ tri_21b = false;
}
if (!tri_1a2)
{
- use_tri1a2 = FALSE;
+ use_tri1a2 = false;
}
else if (!tri_21b)
{
- use_tri1a2 = TRUE;
+ use_tri1a2 = true;
}
else
{
@@ -6294,11 +6256,11 @@ BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
if (d1.dot3(d1) < d2.dot3(d2))
{
- use_tri1a2 = TRUE;
+ use_tri1a2 = true;
}
else
{
- use_tri1a2 = FALSE;
+ use_tri1a2 = false;
}
}
@@ -6377,7 +6339,7 @@ BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build)
norm[i].load4a(normal.getF32ptr());
}
- return TRUE;
+ return true;
}
void LLVolumeFace::createTangents()
@@ -6400,7 +6362,7 @@ void LLVolumeFace::createTangents()
LLCalculateTangentArray(mNumVertices, mPositions, mNormals, mTexCoords, mNumIndices / 3, mIndices, mTangents);
//normalize normals
- for (U32 i = 0; i < mNumVertices; i++)
+ for (S32 i = 0; i < mNumVertices; i++)
{
//bump map/planar projection code requires normals to be normalized
mNormals[i].normalize3fast();
@@ -6576,8 +6538,8 @@ void LLVolumeFace::pushIndex(const U16& idx)
void LLVolumeFace::fillFromLegacyData(std::vector<LLVolumeFace::VertexData>& v, std::vector<U16>& idx)
{
- resizeVertices(v.size());
- resizeIndices(idx.size());
+ resizeVertices(static_cast<S32>(v.size()));
+ resizeIndices(static_cast<S32>(idx.size()));
for (U32 i = 0; i < v.size(); ++i)
{
@@ -6592,18 +6554,18 @@ void LLVolumeFace::fillFromLegacyData(std::vector<LLVolumeFace::VertexData>& v,
}
}
-BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
+bool LLVolumeFace::createSide(LLVolume* volume, bool partial_build)
{
LL_PROFILE_ZONE_SCOPED_CATEGORY_VOLUME
LL_CHECK_MEMORY
- BOOL flat = mTypeMask & FLAT_MASK;
+ bool flat = mTypeMask & FLAT_MASK;
U8 sculpt_type = volume->getParams().getSculptType();
U8 sculpt_stitching = sculpt_type & LL_SCULPT_TYPE_MASK;
- BOOL sculpt_invert = sculpt_type & LL_SCULPT_FLAG_INVERT;
- BOOL sculpt_mirror = sculpt_type & LL_SCULPT_FLAG_MIRROR;
- BOOL sculpt_reverse_horizontal = (sculpt_invert ? !sculpt_mirror : sculpt_mirror); // XOR
+ bool sculpt_invert = sculpt_type & LL_SCULPT_FLAG_INVERT;
+ bool sculpt_mirror = sculpt_type & LL_SCULPT_FLAG_MIRROR;
+ bool sculpt_reverse_horizontal = (sculpt_invert ? !sculpt_mirror : sculpt_mirror); // XOR
S32 num_vertices, num_indices;
@@ -6619,7 +6581,7 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
num_vertices = mNumS*mNumT;
num_indices = (mNumS-1)*(mNumT-1)*6;
- partial_build = (num_vertices > mNumVertices || num_indices > mNumIndices) ? FALSE : partial_build;
+ partial_build = (num_vertices > mNumVertices || num_indices > mNumIndices) ? false : partial_build;
if (!partial_build)
{
@@ -6672,7 +6634,7 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
{
// Get s value for tex-coord.
S32 index = mBeginS + s;
- if (index >= profile.size())
+ if (index >= (S32)profile.size())
{
// edge?
ss = flat ? 1.f - begin_stex : 1.f;
@@ -6790,7 +6752,7 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
S32 cur_index = 0;
S32 cur_edge = 0;
- BOOL flat_face = mTypeMask & FLAT_MASK;
+ bool flat_face = mTypeMask & FLAT_MASK;
if (!partial_build)
{
@@ -6806,45 +6768,63 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
mIndices[cur_index++] = s+1 + mNumS*t; //bottom right
mIndices[cur_index++] = s+1 + mNumS*(t+1); //top right
- mEdge[cur_edge++] = (mNumS-1)*2*t+s*2+1; //bottom left/top right neighbor face
- if (t < mNumT-2) { //top right/top left neighbor face
+ // bottom left/top right neighbor face
+ mEdge[cur_edge++] = (mNumS-1)*2*t+s*2+1;
+
+ if (t < mNumT-2)
+ { // top right/top left neighbor face
mEdge[cur_edge++] = (mNumS-1)*2*(t+1)+s*2+1;
}
- else if (mNumT <= 3 || volume->getPath().isOpen() == TRUE) { //no neighbor
+ else if (mNumT <= 3 || volume->getPath().isOpen())
+ { // no neighbor
mEdge[cur_edge++] = -1;
}
- else { //wrap on T
+ else
+ { // wrap on T
mEdge[cur_edge++] = s*2+1;
}
- if (s > 0) { //top left/bottom left neighbor face
+
+ if (s > 0)
+ { // top left/bottom left neighbor face
mEdge[cur_edge++] = (mNumS-1)*2*t+s*2-1;
}
- else if (flat_face || volume->getProfile().isOpen() == TRUE) { //no neighbor
+ else if (flat_face || volume->getProfile().isOpen())
+ { // no neighbor
mEdge[cur_edge++] = -1;
}
- else { //wrap on S
+ else
+ { // wrap on S
mEdge[cur_edge++] = (mNumS-1)*2*t+(mNumS-2)*2+1;
}
- if (t > 0) { //bottom left/bottom right neighbor face
+ if (t > 0)
+ { // bottom left/bottom right neighbor face
mEdge[cur_edge++] = (mNumS-1)*2*(t-1)+s*2;
}
- else if (mNumT <= 3 || volume->getPath().isOpen() == TRUE) { //no neighbor
+ else if (mNumT <= 3 || volume->getPath().isOpen())
+ { // no neighbor
mEdge[cur_edge++] = -1;
}
- else { //wrap on T
+ else
+ { // wrap on T
mEdge[cur_edge++] = (mNumS-1)*2*(mNumT-2)+s*2;
}
- if (s < mNumS-2) { //bottom right/top right neighbor face
+
+ if (s < mNumS-2)
+ { // bottom right/top right neighbor face
mEdge[cur_edge++] = (mNumS-1)*2*t+(s+1)*2;
}
- else if (flat_face || volume->getProfile().isOpen() == TRUE) { //no neighbor
+ else if (flat_face || volume->getProfile().isOpen())
+ { // no neighbor
mEdge[cur_edge++] = -1;
}
- else { //wrap on S
+ else
+ { // wrap on S
mEdge[cur_edge++] = (mNumS-1)*2*t;
}
- mEdge[cur_edge++] = (mNumS-1)*2*t+s*2; //top right/bottom left neighbor face
+
+ // top right/bottom left neighbor face
+ mEdge[cur_edge++] = (mNumS-1)*2*t+s*2;
}
}
}
@@ -6974,14 +6954,14 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
LLVector4a top;
top.setSub(pos[0], pos[mNumS*(mNumT-2)]);
- BOOL s_bottom_converges = (top.dot3(top) < 0.000001f);
+ bool s_bottom_converges = (top.dot3(top) < 0.000001f);
top.setSub(pos[mNumS-1], pos[mNumS*(mNumT-2)+mNumS-1]);
- BOOL s_top_converges = (top.dot3(top) < 0.000001f);
+ bool s_top_converges = (top.dot3(top) < 0.000001f);
if (sculpt_stitching == LL_SCULPT_TYPE_NONE) // logic for non-sculpt volumes
{
- if (volume->getPath().isOpen() == FALSE)
+ if (!volume->getPath().isOpen())
{ //wrap normals on T
for (S32 i = 0; i < mNumS; i++)
{
@@ -6992,7 +6972,7 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
}
}
- if ((volume->getProfile().isOpen() == FALSE) && !(s_bottom_converges))
+ if (!volume->getProfile().isOpen() && !s_bottom_converges)
{ //wrap normals on S
for (S32 i = 0; i < mNumT; i++)
{
@@ -7025,20 +7005,20 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
}
else // logic for sculpt volumes
{
- BOOL average_poles = FALSE;
- BOOL wrap_s = FALSE;
- BOOL wrap_t = FALSE;
+ bool average_poles = false;
+ bool wrap_s = false;
+ bool wrap_t = false;
if (sculpt_stitching == LL_SCULPT_TYPE_SPHERE)
- average_poles = TRUE;
+ average_poles = true;
if ((sculpt_stitching == LL_SCULPT_TYPE_SPHERE) ||
(sculpt_stitching == LL_SCULPT_TYPE_TORUS) ||
(sculpt_stitching == LL_SCULPT_TYPE_CYLINDER))
- wrap_s = TRUE;
+ wrap_s = true;
if (sculpt_stitching == LL_SCULPT_TYPE_TORUS)
- wrap_t = TRUE;
+ wrap_t = true;
if (average_poles)
@@ -7103,7 +7083,7 @@ BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build)
LL_CHECK_MEMORY
- return TRUE;
+ return true;
}
//adapted from Lengyel, Eric. "Computing Tangent Space Basis Vectors for an Arbitrary Mesh". Terathon Software 3D Graphics Library, 2001. http://www.terathon.com/code/tangent.html
diff --git a/indra/llmath/llvolume.h b/indra/llmath/llvolume.h
index d53ca2a4b3..bbb2a16b0b 100644
--- a/indra/llmath/llvolume.h
+++ b/indra/llmath/llvolume.h
@@ -63,146 +63,148 @@ class LLVolumeOctree;
//============================================================================
-const S32 MIN_DETAIL_FACES = 6;
-const S32 MIN_LOD = 0;
-const S32 MAX_LOD = 3;
+constexpr S32 MIN_DETAIL_FACES = 6;
+constexpr S32 MIN_LOD = 0;
+constexpr S32 MAX_LOD = 3;
// These are defined here but are not enforced at this level,
// rather they are here for the convenience of code that uses
// the LLVolume class.
-const F32 MIN_VOLUME_PROFILE_WIDTH = 0.05f;
-const F32 MIN_VOLUME_PATH_WIDTH = 0.05f;
+constexpr F32 MIN_VOLUME_PROFILE_WIDTH = 0.05f;
+constexpr F32 MIN_VOLUME_PATH_WIDTH = 0.05f;
-const F32 CUT_QUANTA = 0.00002f;
-const F32 SCALE_QUANTA = 0.01f;
-const F32 SHEAR_QUANTA = 0.01f;
-const F32 TAPER_QUANTA = 0.01f;
-const F32 REV_QUANTA = 0.015f;
-const F32 HOLLOW_QUANTA = 0.00002f;
+constexpr F32 CUT_QUANTA = 0.00002f;
+constexpr F32 SCALE_QUANTA = 0.01f;
+constexpr F32 SHEAR_QUANTA = 0.01f;
+constexpr F32 TAPER_QUANTA = 0.01f;
+constexpr F32 REV_QUANTA = 0.015f;
+constexpr F32 HOLLOW_QUANTA = 0.00002f;
-const S32 MAX_VOLUME_TRIANGLE_INDICES = 10000;
+constexpr S32 MAX_VOLUME_TRIANGLE_INDICES = 10000;
//============================================================================
// useful masks
-const LLPCode LL_PCODE_HOLLOW_MASK = 0x80; // has a thickness
-const LLPCode LL_PCODE_SEGMENT_MASK = 0x40; // segments (1 angle)
-const LLPCode LL_PCODE_PATCH_MASK = 0x20; // segmented segments (2 angles)
-const LLPCode LL_PCODE_HEMI_MASK = 0x10; // half-primitives get their own type per PR's dictum
-const LLPCode LL_PCODE_BASE_MASK = 0x0F;
+constexpr LLPCode LL_PCODE_HOLLOW_MASK = 0x80; // has a thickness
+constexpr LLPCode LL_PCODE_SEGMENT_MASK = 0x40; // segments (1 angle)
+constexpr LLPCode LL_PCODE_PATCH_MASK = 0x20; // segmented segments (2 angles)
+constexpr LLPCode LL_PCODE_HEMI_MASK = 0x10; // half-primitives get their own type per PR's dictum
+constexpr LLPCode LL_PCODE_BASE_MASK = 0x0F;
// primitive shapes
-const LLPCode LL_PCODE_CUBE = 1;
-const LLPCode LL_PCODE_PRISM = 2;
-const LLPCode LL_PCODE_TETRAHEDRON = 3;
-const LLPCode LL_PCODE_PYRAMID = 4;
-const LLPCode LL_PCODE_CYLINDER = 5;
-const LLPCode LL_PCODE_CONE = 6;
-const LLPCode LL_PCODE_SPHERE = 7;
-const LLPCode LL_PCODE_TORUS = 8;
-const LLPCode LL_PCODE_VOLUME = 9;
+constexpr LLPCode LL_PCODE_CUBE = 1;
+constexpr LLPCode LL_PCODE_PRISM = 2;
+constexpr LLPCode LL_PCODE_TETRAHEDRON = 3;
+constexpr LLPCode LL_PCODE_PYRAMID = 4;
+constexpr LLPCode LL_PCODE_CYLINDER = 5;
+constexpr LLPCode LL_PCODE_CONE = 6;
+constexpr LLPCode LL_PCODE_SPHERE = 7;
+constexpr LLPCode LL_PCODE_TORUS = 8;
+constexpr LLPCode LL_PCODE_VOLUME = 9;
// surfaces
-//const LLPCode LL_PCODE_SURFACE_TRIANGLE = 10;
-//const LLPCode LL_PCODE_SURFACE_SQUARE = 11;
-//const LLPCode LL_PCODE_SURFACE_DISC = 12;
+//constexpr LLPCode LL_PCODE_SURFACE_TRIANGLE = 10;
+//constexpr LLPCode LL_PCODE_SURFACE_SQUARE = 11;
+//constexpr LLPCode LL_PCODE_SURFACE_DISC = 12;
-const LLPCode LL_PCODE_APP = 14; // App specific pcode (for viewer/sim side only objects)
-const LLPCode LL_PCODE_LEGACY = 15;
+constexpr LLPCode LL_PCODE_APP = 14; // App specific pcode (for viewer/sim side only objects)
+constexpr LLPCode LL_PCODE_LEGACY = 15;
// Pcodes for legacy objects
-//const LLPCode LL_PCODE_LEGACY_ATOR = 0x10 | LL_PCODE_LEGACY; // ATOR
-const LLPCode LL_PCODE_LEGACY_AVATAR = 0x20 | LL_PCODE_LEGACY; // PLAYER
-//const LLPCode LL_PCODE_LEGACY_BIRD = 0x30 | LL_PCODE_LEGACY; // BIRD
-//const LLPCode LL_PCODE_LEGACY_DEMON = 0x40 | LL_PCODE_LEGACY; // DEMON
-const LLPCode LL_PCODE_LEGACY_GRASS = 0x50 | LL_PCODE_LEGACY; // GRASS
-const LLPCode LL_PCODE_TREE_NEW = 0x60 | LL_PCODE_LEGACY; // new trees
-//const LLPCode LL_PCODE_LEGACY_ORACLE = 0x70 | LL_PCODE_LEGACY; // ORACLE
-const LLPCode LL_PCODE_LEGACY_PART_SYS = 0x80 | LL_PCODE_LEGACY; // PART_SYS
-const LLPCode LL_PCODE_LEGACY_ROCK = 0x90 | LL_PCODE_LEGACY; // ROCK
-//const LLPCode LL_PCODE_LEGACY_SHOT = 0xA0 | LL_PCODE_LEGACY; // BASIC_SHOT
-//const LLPCode LL_PCODE_LEGACY_SHOT_BIG = 0xB0 | LL_PCODE_LEGACY;
-//const LLPCode LL_PCODE_LEGACY_SMOKE = 0xC0 | LL_PCODE_LEGACY; // SMOKE
-//const LLPCode LL_PCODE_LEGACY_SPARK = 0xD0 | LL_PCODE_LEGACY;// SPARK
-const LLPCode LL_PCODE_LEGACY_TEXT_BUBBLE = 0xE0 | LL_PCODE_LEGACY; // TEXTBUBBLE
-const LLPCode LL_PCODE_LEGACY_TREE = 0xF0 | LL_PCODE_LEGACY; // TREE
+//constexpr LLPCode LL_PCODE_LEGACY_ATOR = 0x10 | LL_PCODE_LEGACY; // ATOR
+constexpr LLPCode LL_PCODE_LEGACY_AVATAR = 0x20 | LL_PCODE_LEGACY; // PLAYER
+//constexpr LLPCode LL_PCODE_LEGACY_BIRD = 0x30 | LL_PCODE_LEGACY; // BIRD
+//constexpr LLPCode LL_PCODE_LEGACY_DEMON = 0x40 | LL_PCODE_LEGACY; // DEMON
+constexpr LLPCode LL_PCODE_LEGACY_GRASS = 0x50 | LL_PCODE_LEGACY; // GRASS
+constexpr LLPCode LL_PCODE_TREE_NEW = 0x60 | LL_PCODE_LEGACY; // new trees
+//constexpr LLPCode LL_PCODE_LEGACY_ORACLE = 0x70 | LL_PCODE_LEGACY; // ORACLE
+constexpr LLPCode LL_PCODE_LEGACY_PART_SYS = 0x80 | LL_PCODE_LEGACY; // PART_SYS
+constexpr LLPCode LL_PCODE_LEGACY_ROCK = 0x90 | LL_PCODE_LEGACY; // ROCK
+//constexpr LLPCode LL_PCODE_LEGACY_SHOT = 0xA0 | LL_PCODE_LEGACY; // BASIC_SHOT
+//constexpr LLPCode LL_PCODE_LEGACY_SHOT_BIG = 0xB0 | LL_PCODE_LEGACY;
+//constexpr LLPCode LL_PCODE_LEGACY_SMOKE = 0xC0 | LL_PCODE_LEGACY; // SMOKE
+//constexpr LLPCode LL_PCODE_LEGACY_SPARK = 0xD0 | LL_PCODE_LEGACY;// SPARK
+constexpr LLPCode LL_PCODE_LEGACY_TEXT_BUBBLE = 0xE0 | LL_PCODE_LEGACY; // TEXTBUBBLE
+constexpr LLPCode LL_PCODE_LEGACY_TREE = 0xF0 | LL_PCODE_LEGACY; // TREE
// hemis
-const LLPCode LL_PCODE_CYLINDER_HEMI = LL_PCODE_CYLINDER | LL_PCODE_HEMI_MASK;
-const LLPCode LL_PCODE_CONE_HEMI = LL_PCODE_CONE | LL_PCODE_HEMI_MASK;
-const LLPCode LL_PCODE_SPHERE_HEMI = LL_PCODE_SPHERE | LL_PCODE_HEMI_MASK;
-const LLPCode LL_PCODE_TORUS_HEMI = LL_PCODE_TORUS | LL_PCODE_HEMI_MASK;
+constexpr LLPCode LL_PCODE_CYLINDER_HEMI = LL_PCODE_CYLINDER | LL_PCODE_HEMI_MASK;
+constexpr LLPCode LL_PCODE_CONE_HEMI = LL_PCODE_CONE | LL_PCODE_HEMI_MASK;
+constexpr LLPCode LL_PCODE_SPHERE_HEMI = LL_PCODE_SPHERE | LL_PCODE_HEMI_MASK;
+constexpr LLPCode LL_PCODE_TORUS_HEMI = LL_PCODE_TORUS | LL_PCODE_HEMI_MASK;
// Volumes consist of a profile at the base that is swept around
// a path to make a volume.
// The profile code
-const U8 LL_PCODE_PROFILE_MASK = 0x0f;
-const U8 LL_PCODE_PROFILE_MIN = 0x00;
-const U8 LL_PCODE_PROFILE_CIRCLE = 0x00;
-const U8 LL_PCODE_PROFILE_SQUARE = 0x01;
-const U8 LL_PCODE_PROFILE_ISOTRI = 0x02;
-const U8 LL_PCODE_PROFILE_EQUALTRI = 0x03;
-const U8 LL_PCODE_PROFILE_RIGHTTRI = 0x04;
-const U8 LL_PCODE_PROFILE_CIRCLE_HALF = 0x05;
-const U8 LL_PCODE_PROFILE_MAX = 0x05;
+constexpr U8 LL_PCODE_PROFILE_MASK = 0x0f;
+constexpr U8 LL_PCODE_PROFILE_MIN = 0x00;
+constexpr U8 LL_PCODE_PROFILE_CIRCLE = 0x00;
+constexpr U8 LL_PCODE_PROFILE_SQUARE = 0x01;
+constexpr U8 LL_PCODE_PROFILE_ISOTRI = 0x02;
+constexpr U8 LL_PCODE_PROFILE_EQUALTRI = 0x03;
+constexpr U8 LL_PCODE_PROFILE_RIGHTTRI = 0x04;
+constexpr U8 LL_PCODE_PROFILE_CIRCLE_HALF = 0x05;
+constexpr U8 LL_PCODE_PROFILE_MAX = 0x05;
// Stored in the profile byte
-const U8 LL_PCODE_HOLE_MASK = 0xf0;
-const U8 LL_PCODE_HOLE_MIN = 0x00;
-const U8 LL_PCODE_HOLE_SAME = 0x00; // same as outside profile
-const U8 LL_PCODE_HOLE_CIRCLE = 0x10;
-const U8 LL_PCODE_HOLE_SQUARE = 0x20;
-const U8 LL_PCODE_HOLE_TRIANGLE = 0x30;
-const U8 LL_PCODE_HOLE_MAX = 0x03; // min/max needs to be >> 4 of real min/max
-
-const U8 LL_PCODE_PATH_IGNORE = 0x00;
-const U8 LL_PCODE_PATH_MIN = 0x01; // min/max needs to be >> 4 of real min/max
-const U8 LL_PCODE_PATH_LINE = 0x10;
-const U8 LL_PCODE_PATH_CIRCLE = 0x20;
-const U8 LL_PCODE_PATH_CIRCLE2 = 0x30;
-const U8 LL_PCODE_PATH_TEST = 0x40;
-const U8 LL_PCODE_PATH_FLEXIBLE = 0x80;
-const U8 LL_PCODE_PATH_MAX = 0x08;
+constexpr U8 LL_PCODE_HOLE_MASK = 0xf0;
+constexpr U8 LL_PCODE_HOLE_MIN = 0x00;
+constexpr U8 LL_PCODE_HOLE_SAME = 0x00; // same as outside profile
+constexpr U8 LL_PCODE_HOLE_CIRCLE = 0x10;
+constexpr U8 LL_PCODE_HOLE_SQUARE = 0x20;
+constexpr U8 LL_PCODE_HOLE_TRIANGLE = 0x30;
+constexpr U8 LL_PCODE_HOLE_MAX = 0x03; // min/max needs to be >> 4 of real min/max
+
+constexpr U8 LL_PCODE_PATH_IGNORE = 0x00;
+constexpr U8 LL_PCODE_PATH_MIN = 0x01; // min/max needs to be >> 4 of real min/max
+constexpr U8 LL_PCODE_PATH_LINE = 0x10;
+constexpr U8 LL_PCODE_PATH_CIRCLE = 0x20;
+constexpr U8 LL_PCODE_PATH_CIRCLE2 = 0x30;
+constexpr U8 LL_PCODE_PATH_TEST = 0x40;
+constexpr U8 LL_PCODE_PATH_FLEXIBLE = 0x80;
+constexpr U8 LL_PCODE_PATH_MAX = 0x08;
//============================================================================
// face identifiers
typedef U16 LLFaceID;
-const LLFaceID LL_FACE_PATH_BEGIN = 0x1 << 0;
-const LLFaceID LL_FACE_PATH_END = 0x1 << 1;
-const LLFaceID LL_FACE_INNER_SIDE = 0x1 << 2;
-const LLFaceID LL_FACE_PROFILE_BEGIN = 0x1 << 3;
-const LLFaceID LL_FACE_PROFILE_END = 0x1 << 4;
-const LLFaceID LL_FACE_OUTER_SIDE_0 = 0x1 << 5;
-const LLFaceID LL_FACE_OUTER_SIDE_1 = 0x1 << 6;
-const LLFaceID LL_FACE_OUTER_SIDE_2 = 0x1 << 7;
-const LLFaceID LL_FACE_OUTER_SIDE_3 = 0x1 << 8;
+constexpr LLFaceID LL_FACE_PATH_BEGIN = 0x1 << 0;
+constexpr LLFaceID LL_FACE_PATH_END = 0x1 << 1;
+constexpr LLFaceID LL_FACE_INNER_SIDE = 0x1 << 2;
+constexpr LLFaceID LL_FACE_PROFILE_BEGIN = 0x1 << 3;
+constexpr LLFaceID LL_FACE_PROFILE_END = 0x1 << 4;
+constexpr LLFaceID LL_FACE_OUTER_SIDE_0 = 0x1 << 5;
+constexpr LLFaceID LL_FACE_OUTER_SIDE_1 = 0x1 << 6;
+constexpr LLFaceID LL_FACE_OUTER_SIDE_2 = 0x1 << 7;
+constexpr LLFaceID LL_FACE_OUTER_SIDE_3 = 0x1 << 8;
//============================================================================
// sculpt types + flags
-const U8 LL_SCULPT_TYPE_NONE = 0;
-const U8 LL_SCULPT_TYPE_SPHERE = 1;
-const U8 LL_SCULPT_TYPE_TORUS = 2;
-const U8 LL_SCULPT_TYPE_PLANE = 3;
-const U8 LL_SCULPT_TYPE_CYLINDER = 4;
-const U8 LL_SCULPT_TYPE_MESH = 5;
-const U8 LL_SCULPT_TYPE_MASK = LL_SCULPT_TYPE_SPHERE | LL_SCULPT_TYPE_TORUS | LL_SCULPT_TYPE_PLANE |
- LL_SCULPT_TYPE_CYLINDER | LL_SCULPT_TYPE_MESH;
+constexpr U8 LL_SCULPT_TYPE_NONE = 0;
+constexpr U8 LL_SCULPT_TYPE_SPHERE = 1;
+constexpr U8 LL_SCULPT_TYPE_TORUS = 2;
+constexpr U8 LL_SCULPT_TYPE_PLANE = 3;
+constexpr U8 LL_SCULPT_TYPE_CYLINDER = 4;
+constexpr U8 LL_SCULPT_TYPE_MESH = 5;
+constexpr U8 LL_SCULPT_TYPE_GLTF = 6;
+constexpr U8 LL_SCULPT_TYPE_MAX = LL_SCULPT_TYPE_GLTF;
+
+constexpr U8 LL_SCULPT_TYPE_MASK = LL_SCULPT_TYPE_SPHERE | LL_SCULPT_TYPE_TORUS | LL_SCULPT_TYPE_PLANE |
+ LL_SCULPT_TYPE_CYLINDER | LL_SCULPT_TYPE_MESH | LL_SCULPT_TYPE_GLTF;
// for value checks, assign new value after adding new types
-const U8 LL_SCULPT_TYPE_MAX = LL_SCULPT_TYPE_MESH;
-const U8 LL_SCULPT_FLAG_INVERT = 64;
-const U8 LL_SCULPT_FLAG_MIRROR = 128;
-const U8 LL_SCULPT_FLAG_MASK = LL_SCULPT_FLAG_INVERT | LL_SCULPT_FLAG_MIRROR;
+constexpr U8 LL_SCULPT_FLAG_INVERT = 64;
+constexpr U8 LL_SCULPT_FLAG_MIRROR = 128;
+constexpr U8 LL_SCULPT_FLAG_MASK = LL_SCULPT_FLAG_INVERT | LL_SCULPT_FLAG_MIRROR;
-const S32 LL_SCULPT_MESH_MAX_FACES = 8;
+constexpr S32 LL_SCULPT_MESH_MAX_FACES = 8;
-extern BOOL gDebugGL;
+extern bool gDebugGL;
class LLProfileParams
{
@@ -255,11 +257,11 @@ public:
void copyParams(const LLProfileParams &params);
- BOOL importFile(LLFILE *fp);
- BOOL exportFile(LLFILE *fp) const;
+ bool importFile(LLFILE *fp);
+ bool exportFile(LLFILE *fp) const;
- BOOL importLegacyStream(std::istream& input_stream);
- BOOL exportLegacyStream(std::ostream& output_stream) const;
+ bool importLegacyStream(std::istream& input_stream);
+ bool exportLegacyStream(std::ostream& output_stream) const;
LLSD asLLSD() const;
operator LLSD() const { return asLLSD(); }
@@ -391,11 +393,11 @@ public:
void copyParams(const LLPathParams &params);
- BOOL importFile(LLFILE *fp);
- BOOL exportFile(LLFILE *fp) const;
+ bool importFile(LLFILE *fp);
+ bool exportFile(LLFILE *fp) const;
- BOOL importLegacyStream(std::istream& input_stream);
- BOOL exportLegacyStream(std::ostream& output_stream) const;
+ bool importLegacyStream(std::istream& input_stream);
+ bool exportLegacyStream(std::ostream& output_stream) const;
LLSD asLLSD() const;
operator LLSD() const { return asLLSD(); }
@@ -583,11 +585,11 @@ public:
const LLPathParams &getPathParams() const {return mPathParams;}
LLPathParams &getPathParams() {return mPathParams;}
- BOOL importFile(LLFILE *fp);
- BOOL exportFile(LLFILE *fp) const;
+ bool importFile(LLFILE *fp);
+ bool exportFile(LLFILE *fp) const;
- BOOL importLegacyStream(std::istream& input_stream);
- BOOL exportLegacyStream(std::ostream& output_stream) const;
+ bool importLegacyStream(std::istream& input_stream);
+ bool exportLegacyStream(std::ostream& output_stream) const;
LLSD sculptAsLLSD() const;
bool sculptFromLLSD(LLSD& sd);
@@ -621,7 +623,7 @@ public:
bool setRevolutions(const F32 revolutions); // 1 to 4
bool setRadiusOffset(const F32 radius_offset);
bool setSkew(const F32 skew);
- bool setSculptID(const LLUUID sculpt_id, U8 sculpt_type);
+ bool setSculptID(const LLUUID& sculpt_id, U8 sculpt_type);
static bool validate(U8 prof_curve, F32 prof_begin, F32 prof_end, F32 hollow,
U8 path_curve, F32 path_begin, F32 path_end,
@@ -653,7 +655,7 @@ public:
const U8& getSculptType() const { return mSculptType; }
bool isSculpt() const;
bool isMeshSculpt() const;
- BOOL isConvex() const;
+ bool isConvex() const;
// 'begin' and 'end' should be in range [0, 1] (they will be clamped)
// (begin, end) = (0, 1) will not change the volume
@@ -688,9 +690,9 @@ class LLProfile
public:
LLProfile()
- : mOpen(FALSE),
- mConcave(FALSE),
- mDirty(TRUE),
+ : mOpen(false),
+ mConcave(false),
+ mDirty(true),
mTotalOut(0),
mTotal(2)
{
@@ -698,23 +700,23 @@ public:
S32 getTotal() const { return mTotal; }
S32 getTotalOut() const { return mTotalOut; } // Total number of outside points
- BOOL isFlat(S32 face) const { return (mFaces[face].mCount == 2); }
- BOOL isOpen() const { return mOpen; }
- void setDirty() { mDirty = TRUE; }
-
- static S32 getNumPoints(const LLProfileParams& params, BOOL path_open, F32 detail = 1.0f, S32 split = 0,
- BOOL is_sculpted = FALSE, S32 sculpt_size = 0);
- BOOL generate(const LLProfileParams& params, BOOL path_open, F32 detail = 1.0f, S32 split = 0,
- BOOL is_sculpted = FALSE, S32 sculpt_size = 0);
- BOOL isConcave() const { return mConcave; }
+ bool isFlat(S32 face) const { return (mFaces[face].mCount == 2); }
+ bool isOpen() const { return mOpen; }
+ void setDirty() { mDirty = true; }
+
+ static S32 getNumPoints(const LLProfileParams& params, bool path_open, F32 detail = 1.0f, S32 split = 0,
+ bool is_sculpted = false, S32 sculpt_size = 0);
+ bool generate(const LLProfileParams& params, bool path_open, F32 detail = 1.0f, S32 split = 0,
+ bool is_sculpted = false, S32 sculpt_size = 0);
+ bool isConcave() const { return mConcave; }
public:
struct Face
{
S32 mIndex;
S32 mCount;
F32 mScaleU;
- BOOL mCap;
- BOOL mFlat;
+ bool mCap;
+ bool mFlat;
LLFaceID mFaceID;
};
@@ -733,14 +735,14 @@ protected:
static S32 getNumNGonPoints(const LLProfileParams& params, S32 sides, F32 offset=0.0f, F32 bevel = 0.0f, F32 ang_scale = 1.f, S32 split = 0);
void genNGon(const LLProfileParams& params, S32 sides, F32 offset=0.0f, F32 bevel = 0.0f, F32 ang_scale = 1.f, S32 split = 0);
- Face* addHole(const LLProfileParams& params, BOOL flat, F32 sides, F32 offset, F32 box_hollow, F32 ang_scale, S32 split = 0);
+ Face* addHole(const LLProfileParams& params, bool flat, F32 sides, F32 offset, F32 box_hollow, F32 ang_scale, S32 split = 0);
Face* addCap (S16 faceID);
- Face* addFace(S32 index, S32 count, F32 scaleU, S16 faceID, BOOL flat);
+ Face* addFace(S32 index, S32 count, F32 scaleU, S16 faceID, bool flat);
protected:
- BOOL mOpen;
- BOOL mConcave;
- BOOL mDirty;
+ bool mOpen;
+ bool mConcave;
+ bool mDirty;
S32 mTotalOut;
S32 mTotal;
@@ -780,9 +782,9 @@ public:
public:
LLPath()
- : mOpen(FALSE),
+ : mOpen(false),
mTotal(0),
- mDirty(TRUE),
+ mDirty(true),
mStep(1)
{
}
@@ -793,12 +795,12 @@ public:
static S32 getNumNGonPoints(const LLPathParams& params, S32 sides, F32 offset=0.0f, F32 end_scale = 1.f, F32 twist_scale = 1.f);
void genNGon(const LLPathParams& params, S32 sides, F32 offset=0.0f, F32 end_scale = 1.f, F32 twist_scale = 1.f);
- virtual BOOL generate(const LLPathParams& params, F32 detail=1.0f, S32 split = 0,
- BOOL is_sculpted = FALSE, S32 sculpt_size = 0);
+ virtual bool generate(const LLPathParams& params, F32 detail=1.0f, S32 split = 0,
+ bool is_sculpted = false, S32 sculpt_size = 0);
- BOOL isOpen() const { return mOpen; }
+ bool isOpen() const { return mOpen; }
F32 getStep() const { return mStep; }
- void setDirty() { mDirty = TRUE; }
+ void setDirty() { mDirty = true; }
S32 getPathLength() const { return (S32)mPath.size(); }
@@ -810,9 +812,9 @@ public:
LLAlignedArray<PathPt, 64> mPath;
protected:
- BOOL mOpen;
+ bool mOpen;
S32 mTotal;
- BOOL mDirty;
+ bool mDirty;
F32 mStep;
};
@@ -820,8 +822,8 @@ class LLDynamicPath : public LLPath
{
public:
LLDynamicPath() : LLPath() { }
- /*virtual*/ BOOL generate(const LLPathParams& params, F32 detail=1.0f, S32 split = 0,
- BOOL is_sculpted = FALSE, S32 sculpt_size = 0);
+ /*virtual*/ bool generate(const LLPathParams& params, F32 detail=1.0f, S32 split = 0,
+ bool is_sculpted = false, S32 sculpt_size = 0);
};
// Yet another "face" class - caches volume-specific, but not instance-specific data for faces)
@@ -871,7 +873,7 @@ private:
void freeData();
public:
- BOOL create(LLVolume* volume, BOOL partial_build = FALSE);
+ bool create(LLVolume* volume, bool partial_build = false);
void createTangents();
void resizeVertices(S32 num_verts);
@@ -973,14 +975,14 @@ public:
U8* mJointIndices;
#endif
- mutable BOOL mWeightsScrubbed;
+ mutable bool mWeightsScrubbed;
// Which joints are rigged to, and the bounding box of any rigged
// vertices per joint.
LLJointRiggingInfoTab mJointRiggingInfoTab;
//whether or not face has been cache optimized
- BOOL mOptimized;
+ bool mOptimized;
// if this is a mesh asset, scale and translation that were applied
// when encoding the source mesh into a unit cube
@@ -991,9 +993,9 @@ private:
LLVolumeOctree* mOctree;
LLVolumeTriangle* mOctreeTriangles;
- BOOL createUnCutCubeCap(LLVolume* volume, BOOL partial_build = FALSE);
- BOOL createCap(LLVolume* volume, BOOL partial_build = FALSE);
- BOOL createSide(LLVolume* volume, BOOL partial_build = FALSE);
+ bool createUnCutCubeCap(LLVolume* volume, bool partial_build = false);
+ bool createCap(LLVolume* volume, bool partial_build = false);
+ bool createSide(LLVolume* volume, bool partial_build = false);
};
class LLVolume : public LLRefCount
@@ -1015,12 +1017,12 @@ public:
S32 mCountT;
};
- LLVolume(const LLVolumeParams &params, const F32 detail, const BOOL generate_single_face = FALSE, const BOOL is_unique = FALSE);
+ LLVolume(const LLVolumeParams &params, const F32 detail, const bool generate_single_face = false, const bool is_unique = false);
U8 getProfileType() const { return mParams.getProfileParams().getCurveType(); }
U8 getPathType() const { return mParams.getPathParams().getCurveType(); }
S32 getNumFaces() const;
- S32 getNumVolumeFaces() const { return mVolumeFaces.size(); }
+ S32 getNumVolumeFaces() const { return static_cast<S32>(mVolumeFaces.size()); }
F32 getDetail() const { return mDetail; }
F32 getSurfaceArea() const { return mSurfaceArea; }
const LLVolumeParams& getParams() const { return mParams; }
@@ -1037,10 +1039,10 @@ public:
void regen();
void genTangents(S32 face);
- BOOL isConvex() const;
- BOOL isCap(S32 face);
- BOOL isFlat(S32 face);
- BOOL isUnique() const { return mUnique; }
+ bool isConvex() const;
+ bool isCap(S32 face);
+ bool isFlat(S32 face);
+ bool isUnique() const { return mUnique; }
S32 getSculptLevel() const { return mSculptLevel; }
void setSculptLevel(S32 level) { mSculptLevel = level; }
@@ -1048,7 +1050,7 @@ public:
static void getLoDTriangleCounts(const LLVolumeParams& params, S32* counts);
- S32 getNumTriangles(S32* vcount = NULL) const;
+ S32 getNumTriangles(S32* vcount = nullptr) const;
void generateSilhouetteVertices(std::vector<LLVector3> &vertices,
std::vector<LLVector3> &normals,
@@ -1062,15 +1064,15 @@ public:
//Line segment must be in volume space.
S32 lineSegmentIntersect(const LLVector4a& start, const LLVector4a& end,
S32 face = -1, // which face to check, -1 = ALL_SIDES
- LLVector4a* intersection = NULL, // return the intersection point
- LLVector2* tex_coord = NULL, // return the texture coordinates of the intersection point
- LLVector4a* normal = NULL, // return the surface normal at the intersection point
- LLVector4a* tangent = NULL // return the surface tangent at the intersection point
+ LLVector4a* intersection = nullptr, // return the intersection point
+ LLVector2* tex_coord = nullptr, // return the texture coordinates of the intersection point
+ LLVector4a* normal = nullptr, // return the surface normal at the intersection point
+ LLVector4a* tangent = nullptr // return the surface tangent at the intersection point
);
LLFaceID generateFaceMask();
- BOOL isFaceMaskValid(LLFaceID face_mask);
+ bool isFaceMaskValid(LLFaceID face_mask);
static S32 sNumMeshPoints;
friend std::ostream& operator<<(std::ostream &s, const LLVolume &volume);
@@ -1099,11 +1101,9 @@ private:
F32 sculptGetSurfaceArea();
void sculptGenerateEmptyPlaceholder();
void sculptGenerateSpherePlaceholder();
- void sculptCalcMeshResolution(U16 width, U16 height, U8 type, S32& s, S32& t);
-
protected:
- BOOL generate();
+ bool generate();
void createVolumeFaces();
public:
bool unpackVolumeFaces(std::istream& is, S32 size);
@@ -1118,7 +1118,7 @@ public:
virtual bool isMeshAssetUnavaliable();
protected:
- BOOL mUnique;
+ bool mUnique;
F32 mDetail;
S32 mSculptLevel;
F32 mSurfaceArea; //unscaled surface area
@@ -1131,7 +1131,7 @@ public:
LLAlignedArray<LLVector4a,64> mMesh;
- BOOL mGenerateSingleFace;
+ bool mGenerateSingleFace;
face_list_t mVolumeFaces;
public:
@@ -1145,18 +1145,13 @@ std::ostream& operator<<(std::ostream &s, const LLVolumeParams &volume_params);
void LLCalculateTangentArray(U32 vertexCount, const LLVector4a *vertex, const LLVector4a *normal, const LLVector2 *texcoord, U32 triangleCount, const U16* index_array, LLVector4a *tangent);
-BOOL LLLineSegmentBoxIntersect(const F32* start, const F32* end, const F32* center, const F32* size);
-BOOL LLLineSegmentBoxIntersect(const LLVector3& start, const LLVector3& end, const LLVector3& center, const LLVector3& size);
-BOOL LLLineSegmentBoxIntersect(const LLVector4a& start, const LLVector4a& end, const LLVector4a& center, const LLVector4a& size);
-
-//BOOL LLTriangleRayIntersect(const LLVector3& vert0, const LLVector3& vert1, const LLVector3& vert2, const LLVector3& orig, const LLVector3& dir,
-// F32& intersection_a, F32& intersection_b, F32& intersection_t, BOOL two_sided);
+bool LLLineSegmentBoxIntersect(const F32* start, const F32* end, const F32* center, const F32* size);
+bool LLLineSegmentBoxIntersect(const LLVector3& start, const LLVector3& end, const LLVector3& center, const LLVector3& size);
+bool LLLineSegmentBoxIntersect(const LLVector4a& start, const LLVector4a& end, const LLVector4a& center, const LLVector4a& size);
-BOOL LLTriangleRayIntersect(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
+bool LLTriangleRayIntersect(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
F32& intersection_a, F32& intersection_b, F32& intersection_t);
-BOOL LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
+bool LLTriangleRayIntersectTwoSided(const LLVector4a& vert0, const LLVector4a& vert1, const LLVector4a& vert2, const LLVector4a& orig, const LLVector4a& dir,
F32& intersection_a, F32& intersection_b, F32& intersection_t);
-
-
#endif
diff --git a/indra/llmath/llvolumemgr.cpp b/indra/llmath/llvolumemgr.cpp
index 6f82335b3f..bb0c94d513 100644
--- a/indra/llmath/llvolumemgr.cpp
+++ b/indra/llmath/llvolumemgr.cpp
@@ -59,9 +59,9 @@ LLVolumeMgr::~LLVolumeMgr()
mDataMutex = NULL;
}
-BOOL LLVolumeMgr::cleanup()
+bool LLVolumeMgr::cleanup()
{
- BOOL no_refs = TRUE;
+ bool no_refs = true;
if (mDataMutex)
{
mDataMutex->lock();
@@ -71,9 +71,9 @@ BOOL LLVolumeMgr::cleanup()
iter != end; iter++)
{
LLVolumeLODGroup *volgroupp = iter->second;
- if (volgroupp->cleanupRefs() == false)
+ if (!volgroupp->cleanupRefs())
{
- no_refs = FALSE;
+ no_refs = false;
}
delete volgroupp;
}
@@ -301,7 +301,7 @@ LLVolume* LLVolumeLODGroup::refLOD(const S32 lod)
return mVolumeLODs[lod];
}
-BOOL LLVolumeLODGroup::derefLOD(LLVolume *volumep)
+bool LLVolumeLODGroup::derefLOD(LLVolume *volumep)
{
llassert_always(mRefs > 0);
mRefs--;
@@ -317,11 +317,11 @@ BOOL LLVolumeLODGroup::derefLOD(LLVolume *volumep)
mVolumeLODs[i] = NULL;
}
#endif
- return TRUE;
+ return true;
}
}
LL_ERRS() << "Deref of non-matching LOD in volume LOD group" << LL_ENDL;
- return FALSE;
+ return false;
}
S32 LLVolumeLODGroup::getDetailFromTan(const F32 tan_angle)
diff --git a/indra/llmath/llvolumemgr.h b/indra/llmath/llvolumemgr.h
index b46e9aa725..2e0ce3e88a 100644
--- a/indra/llmath/llvolumemgr.h
+++ b/indra/llmath/llvolumemgr.h
@@ -56,7 +56,7 @@ public:
static S32 getVolumeDetailFromScale(F32 scale);
LLVolume* refLOD(const S32 detail);
- BOOL derefLOD(LLVolume *volumep);
+ bool derefLOD(LLVolume *volumep);
S32 getNumRefs() const { return mRefs; }
const LLVolumeParams* getVolumeParams() const { return &mVolumeParams; };
@@ -80,7 +80,7 @@ class LLVolumeMgr
public:
LLVolumeMgr();
virtual ~LLVolumeMgr();
- BOOL cleanup(); // Cleanup all volumes being managed, returns TRUE if no dangling references
+ bool cleanup(); // Cleanup all volumes being managed, returns true if no dangling references
virtual LLVolumeLODGroup* getGroup( const LLVolumeParams& volume_params ) const;
diff --git a/indra/llmath/llvolumeoctree.cpp b/indra/llmath/llvolumeoctree.cpp
index 341b9a6465..71288daa89 100644
--- a/indra/llmath/llvolumeoctree.cpp
+++ b/indra/llmath/llvolumeoctree.cpp
@@ -27,7 +27,7 @@
#include "llvolumeoctree.h"
#include "llvector4a.h"
-BOOL LLLineSegmentBoxIntersect(const LLVector4a& start, const LLVector4a& end, const LLVector4a& center, const LLVector4a& size)
+bool LLLineSegmentBoxIntersect(const LLVector4a& start, const LLVector4a& end, const LLVector4a& center, const LLVector4a& size)
{
LLVector4a fAWdU;
LLVector4a dir;
@@ -71,10 +71,9 @@ BOOL LLLineSegmentBoxIntersect(const LLVector4a& start, const LLVector4a& end, c
grt = f.greaterThan(rhs).getGatheredBits();
- return (grt & 0x7) ? false : true;
+ return (grt & 0x7) == 0;
}
-
LLVolumeOctreeListener::LLVolumeOctreeListener(LLOctreeNode<LLVolumeTriangle, LLVolumeTriangle*>* node)
{
node->addListener(this);
@@ -114,7 +113,7 @@ void LLOctreeTriangleRayIntersect::traverse(const LLOctreeNode<LLVolumeTriangle,
if (LLLineSegmentBoxIntersect(mStart, mEnd, vl->mBounds[0], vl->mBounds[1]))
{
node->accept(this);
- for (S32 i = 0; i < node->getChildCount(); ++i)
+ for (U32 i = 0; i < node->getChildCount(); ++i)
{
traverse(node->getChild(i));
}
@@ -152,7 +151,7 @@ void LLOctreeTriangleRayIntersect::visit(const LLOctreeNode<LLVolumeTriangle, LL
U32 idx1 = tri->mIndex[1];
U32 idx2 = tri->mIndex[2];
- if (mTexCoord != NULL)
+ if (mTexCoord != NULL && mFace->mTexCoords)
{
LLVector2* tc = (LLVector2*) mFace->mTexCoords;
*mTexCoord = ((1.f - a - b) * tc[idx0] +
@@ -161,7 +160,7 @@ void LLOctreeTriangleRayIntersect::visit(const LLOctreeNode<LLVolumeTriangle, LL
}
- if (mNormal != NULL)
+ if (mNormal != NULL && mFace->mNormals)
{
LLVector4a* norm = mFace->mNormals;
@@ -181,7 +180,7 @@ void LLOctreeTriangleRayIntersect::visit(const LLOctreeNode<LLVolumeTriangle, LL
*mNormal = n1;
}
- if (mTangent != NULL)
+ if (mTangent != NULL && mFace->mTangents)
{
LLVector4a* tangents = mFace->mTangents;
diff --git a/indra/llmath/llvolumeoctree.h b/indra/llmath/llvolumeoctree.h
index cf176b5afe..05d45f7b5f 100644
--- a/indra/llmath/llvolumeoctree.h
+++ b/indra/llmath/llvolumeoctree.h
@@ -48,12 +48,6 @@ public:
*this = rhs;
}
- const LLVolumeTriangle& operator=(const LLVolumeTriangle& rhs)
- {
- LL_ERRS() << "Illegal operation!" << LL_ENDL;
- return *this;
- }
-
~LLVolumeTriangle()
{
@@ -192,7 +186,7 @@ public:
llassert(!branch->isLeaf()); // Empty leaf
}
- for (S32 i = 0; i < branch->getChildCount(); ++i)
+ for (U32 i = 0; i < branch->getChildCount(); ++i)
{ //stretch by child extents
LLVolumeOctreeListener* child = (LLVolumeOctreeListener*)branch->getChild(i)->getListener(0);
min.setMin(min, child->mExtents[0]);
diff --git a/indra/llmath/m3math.cpp b/indra/llmath/m3math.cpp
index 2cefc44da3..472d340af5 100644
--- a/indra/llmath/m3math.cpp
+++ b/indra/llmath/m3math.cpp
@@ -528,10 +528,10 @@ bool operator==(const LLMatrix3 &a, const LLMatrix3 &b)
for (j = 0; j < NUM_VALUES_IN_MAT3; j++)
{
if (a.mMatrix[j][i] != b.mMatrix[j][i])
- return FALSE;
+ return false;
}
}
- return TRUE;
+ return true;
}
bool operator!=(const LLMatrix3 &a, const LLMatrix3 &b)
@@ -542,10 +542,10 @@ bool operator!=(const LLMatrix3 &a, const LLMatrix3 &b)
for (j = 0; j < NUM_VALUES_IN_MAT3; j++)
{
if (a.mMatrix[j][i] != b.mMatrix[j][i])
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
const LLMatrix3& operator*=(LLMatrix3 &a, const LLMatrix3 &b)
diff --git a/indra/llmath/m4math.cpp b/indra/llmath/m4math.cpp
index 16ce00d963..c46ee587cb 100644
--- a/indra/llmath/m4math.cpp
+++ b/indra/llmath/m4math.cpp
@@ -744,10 +744,10 @@ bool operator==(const LLMatrix4 &a, const LLMatrix4 &b)
for (j = 0; j < NUM_VALUES_IN_MAT4; j++)
{
if (a.mMatrix[j][i] != b.mMatrix[j][i])
- return FALSE;
+ return false;
}
}
- return TRUE;
+ return true;
}
bool operator!=(const LLMatrix4 &a, const LLMatrix4 &b)
@@ -758,10 +758,10 @@ bool operator!=(const LLMatrix4 &a, const LLMatrix4 &b)
for (j = 0; j < NUM_VALUES_IN_MAT4; j++)
{
if (a.mMatrix[j][i] != b.mMatrix[j][i])
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
bool operator<(const LLMatrix4& a, const LLMatrix4 &b)
diff --git a/indra/llmath/raytrace.cpp b/indra/llmath/raytrace.cpp
index de51313fa2..893bf1fc70 100644
--- a/indra/llmath/raytrace.cpp
+++ b/indra/llmath/raytrace.cpp
@@ -34,7 +34,7 @@
#include "raytrace.h"
-BOOL line_plane(const LLVector3 &line_point, const LLVector3 &line_direction,
+bool line_plane(const LLVector3 &line_point, const LLVector3 &line_direction,
const LLVector3 &plane_point, const LLVector3 plane_normal,
LLVector3 &intersection)
{
@@ -43,18 +43,18 @@ BOOL line_plane(const LLVector3 &line_point, const LLVector3 &line_direction,
{
// line is perpendicular to plane normal
// so it is either entirely on plane, or not on plane at all
- return FALSE;
+ return false;
}
// Ax + By, + Cz + D = 0
// D = - (plane_point * plane_normal)
// N = line_direction * plane_normal
// intersection = line_point - ((D + plane_normal * line_point) / N) * line_direction
intersection = line_point - ((plane_normal * line_point - plane_point * plane_normal) / N) * line_direction;
- return TRUE;
+ return true;
}
-BOOL ray_plane(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_plane(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &plane_point, const LLVector3 plane_normal,
LLVector3 &intersection)
{
@@ -63,7 +63,7 @@ BOOL ray_plane(const LLVector3 &ray_point, const LLVector3 &ray_direction,
{
// ray is perpendicular to plane normal
// so it is either entirely on plane, or not on plane at all
- return FALSE;
+ return false;
}
// Ax + By, + Cz + D = 0
// D = - (plane_point * plane_normal)
@@ -73,14 +73,14 @@ BOOL ray_plane(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (alpha < 0.0f)
{
// ray points away from plane
- return FALSE;
+ return false;
}
intersection = ray_point + alpha * ray_direction;
- return TRUE;
+ return true;
}
-BOOL ray_circle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_circle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &circle_center, const LLVector3 plane_normal, F32 circle_radius,
LLVector3 &intersection)
{
@@ -88,14 +88,14 @@ BOOL ray_circle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
{
if (circle_radius >= (intersection - circle_center).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL ray_triangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_triangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -112,15 +112,15 @@ BOOL ray_triangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
intersection_normal * (side_12 % (intersection - point_1)) >= 0.0f &&
intersection_normal * (side_20 % (intersection - point_2)) >= 0.0f)
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
// assumes a parallelogram
-BOOL ray_quadrangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_quadrangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -140,14 +140,14 @@ BOOL ray_quadrangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
intersection_normal * (side_23 % (intersection - point_2)) >= 0.0f &&
intersection_normal * (side_30 % (intersection - point_3)) >= 0.0f)
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &sphere_center, F32 sphere_radius,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -160,7 +160,7 @@ BOOL ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
F32 radius_squared = sphere_radius * sphere_radius;
if (shortest_distance > radius_squared)
{
- return FALSE;
+ return false;
}
F32 half_chord = (F32) sqrt(radius_squared - shortest_distance);
@@ -170,7 +170,7 @@ BOOL ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (dot < 0.0f)
{
// ray shoots away from sphere and is not inside it
- return FALSE;
+ return false;
}
shortest_distance = ray_direction * ((closest_approach - half_chord * ray_direction) - ray_point);
@@ -195,11 +195,11 @@ BOOL ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
intersection_normal.setVec(0.0f, 0.0f, 0.0f);
}
- return TRUE;
+ return true;
}
-BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &cyl_center, const LLVector3 &cyl_scale, const LLQuaternion &cyl_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -242,7 +242,7 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (dot > 0.0f)
{
// ray points away from cylinder bottom
- return FALSE;
+ return false;
}
// ray hit bottom of cylinder from outside
intersection = ray_point - shortest_distance * cyl_axis;
@@ -270,15 +270,15 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (dot < 0.0f)
{
// ray points away from cylinder bottom
- return FALSE;
+ return false;
}
// ray hit top from outside
intersection = ray_point - (shortest_distance + cyl_length) * cyl_axis;
intersection_normal = -cyl_axis;
}
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
// check for intersection with infinite cylinder
@@ -298,8 +298,8 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
out = dist_to_closest_point + half_chord_length; // dist to exiting point
if (out < 0.0f)
{
- // cylinder is behind the ray, so we return FALSE
- return FALSE;
+ // cylinder is behind the ray, so we return false
+ return false;
}
in = dist_to_closest_point - half_chord_length; // dist to entering point
@@ -341,14 +341,14 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (shortest_distance > out)
{
// ray missed the finite cylinder
- return FALSE;
+ return false;
}
if (shortest_distance > in)
{
// ray intersects cylinder at top plane
intersection = temp_vector;
intersection_normal = -cyl_axis;
- return TRUE;
+ return true;
}
}
else
@@ -357,7 +357,7 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (shortest_distance < in)
{
// missed the finite cylinder
- return FALSE;
+ return false;
}
}
@@ -370,14 +370,14 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (shortest_distance > out)
{
// ray missed the finite cylinder
- return FALSE;
+ return false;
}
if (shortest_distance > in)
{
// ray intersects cylinder at bottom plane
intersection = temp_vector;
intersection_normal = cyl_axis;
- return TRUE;
+ return true;
}
}
else
@@ -386,7 +386,7 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (shortest_distance < in)
{
// ray missed the finite cylinder
- return FALSE;
+ return false;
}
}
@@ -399,14 +399,14 @@ BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (shortest_distance < 0.0f || shortest_distance > cyl_length)
{
// ray missed finite cylinder
- return FALSE;
+ return false;
}
}
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
@@ -710,7 +710,7 @@ U32 ray_box(const LLVector3 &ray_point, const LLVector3 &ray_direction,
}
-BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &prism_center, const LLVector3 &prism_scale, const LLQuaternion &prism_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -751,7 +751,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
point5 = (point5 * prism_rotation) + prism_center;
// test ray intersection for each face
- BOOL b_hit = FALSE;
+ bool b_hit = false;
LLVector3 face_intersection, face_normal;
F32 distance_squared = 0.0f;
F32 temp;
@@ -761,14 +761,14 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
ray_quadrangle(ray_point, ray_direction, point5, point2, point0, intersection, intersection_normal))
{
distance_squared = (ray_point - intersection).magVecSquared();
- b_hit = TRUE;
+ b_hit = true;
}
// face 1
if (ray_direction * ( (point0 - point3) % (point2 - point3)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point2, point3, point0, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -783,7 +783,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -791,7 +791,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point1 - point4) % (point3 - point4)) < 0.0f &&
ray_quadrangle(ray_point, ray_direction, point3, point4, point1, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -806,7 +806,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -814,7 +814,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point5 - point4) % (point1 - point4)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point1, point4, point5, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -829,7 +829,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -837,7 +837,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point4 - point5) % (point2 - point5)) < 0.0f &&
ray_quadrangle(ray_point, ray_direction, point2, point5, point4, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -852,7 +852,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -860,7 +860,7 @@ BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
}
-BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &t_center, const LLVector3 &t_scale, const LLQuaternion &t_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -890,7 +890,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
point3 = (point3 * t_rotation) + t_center;
// test ray intersection for each face
- BOOL b_hit = FALSE;
+ bool b_hit = false;
LLVector3 face_intersection, face_normal;
F32 distance_squared = 1.0e12f;
F32 temp;
@@ -900,14 +900,14 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
ray_triangle(ray_point, ray_direction, point1, point2, point0, intersection, intersection_normal))
{
distance_squared = (ray_point - intersection).magVecSquared();
- b_hit = TRUE;
+ b_hit = true;
}
// face 1
if (ray_direction * ( (point3 - point2) % (point0 - point2)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point2, point3, point0, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -922,7 +922,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -930,7 +930,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point1 - point3) % (point0 - point3)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point3, point1, point0, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -945,7 +945,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -953,7 +953,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point2 - point3) % (point1 - point3)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point3, point2, point1, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -966,7 +966,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
{
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -974,7 +974,7 @@ BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
}
-BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &p_center, const LLVector3 &p_scale, const LLQuaternion &p_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -997,7 +997,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
point4 = (point4 * p_rotation) + p_center;
// test ray intersection for each face
- BOOL b_hit = FALSE;
+ bool b_hit = false;
LLVector3 face_intersection, face_normal;
F32 distance_squared = 1.0e12f;
F32 temp;
@@ -1007,14 +1007,14 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
ray_triangle(ray_point, ray_direction, point4, point1, point0, intersection, intersection_normal))
{
distance_squared = (ray_point - intersection).magVecSquared();
- b_hit = TRUE;
+ b_hit = true;
}
// face 1
if (ray_direction * ( (point2 - point1) % (point0 - point1)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point1, point2, point0, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -1029,7 +1029,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -1037,7 +1037,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point3 - point2) % (point0 - point2)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point2, point3, point0, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -1052,7 +1052,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -1060,7 +1060,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point4 - point3) % (point0 - point3)) < 0.0f &&
ray_triangle(ray_point, ray_direction, point3, point4, point0, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -1075,7 +1075,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
distance_squared = (ray_point - face_intersection).magVecSquared();
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -1083,7 +1083,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
if (ray_direction * ( (point3 - point4) % (point2 - point4)) < 0.0f &&
ray_quadrangle(ray_point, ray_direction, point4, point3, point2, face_intersection, face_normal))
{
- if (TRUE == b_hit)
+ if (b_hit)
{
temp = (ray_point - face_intersection).magVecSquared();
if (temp < distance_squared)
@@ -1096,7 +1096,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
{
intersection = face_intersection;
intersection_normal = face_normal;
- b_hit = TRUE;
+ b_hit = true;
}
}
@@ -1104,7 +1104,7 @@ BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
}
-BOOL linesegment_circle(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_circle(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &circle_center, const LLVector3 plane_normal, F32 circle_radius,
LLVector3 &intersection)
{
@@ -1115,14 +1115,14 @@ BOOL linesegment_circle(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL linesegment_triangle(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_triangle(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1133,14 +1133,14 @@ BOOL linesegment_triangle(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL linesegment_quadrangle(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_quadrangle(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1151,14 +1151,14 @@ BOOL linesegment_quadrangle(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL linesegment_sphere(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_sphere(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &sphere_center, F32 sphere_radius,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1169,14 +1169,14 @@ BOOL linesegment_sphere(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL linesegment_cylinder(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_cylinder(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &cyl_center, const LLVector3 &cyl_scale, const LLQuaternion &cyl_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1187,10 +1187,10 @@ BOOL linesegment_cylinder(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
@@ -1215,7 +1215,7 @@ U32 linesegment_box(const LLVector3 &point_a, const LLVector3 &point_b,
}
-BOOL linesegment_prism(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_prism(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &prism_center, const LLVector3 &prism_scale, const LLQuaternion &prism_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1226,14 +1226,14 @@ BOOL linesegment_prism(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL linesegment_tetrahedron(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_tetrahedron(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &t_center, const LLVector3 &t_scale, const LLQuaternion &t_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1244,14 +1244,14 @@ BOOL linesegment_tetrahedron(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-BOOL linesegment_pyramid(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_pyramid(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &p_center, const LLVector3 &p_scale, const LLQuaternion &p_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal)
{
@@ -1262,13 +1262,8 @@ BOOL linesegment_pyramid(const LLVector3 &point_a, const LLVector3 &point_b,
{
if (segment_length >= (point_a - intersection).magVec())
{
- return TRUE;
+ return true;
}
}
- return FALSE;
+ return false;
}
-
-
-
-
-
diff --git a/indra/llmath/raytrace.h b/indra/llmath/raytrace.h
index 01b8ee64f4..b55f29aef6 100644
--- a/indra/llmath/raytrace.h
+++ b/indra/llmath/raytrace.h
@@ -38,8 +38,8 @@ class LLQuaternion;
// Vector arguments of the form "shape_scale" represent the scale of the
// object along the three axes.
//
-// All functions return the expected TRUE or FALSE, unless otherwise noted.
-// When FALSE is returned, any resulting values that might have been stored
+// All functions return the expected true or false, unless otherwise noted.
+// When false is returned, any resulting values that might have been stored
// are undefined.
//
// Rays are defined by a "ray_point" and a "ray_direction" (unit).
@@ -61,25 +61,25 @@ class LLQuaternion;
// frame.
-// returns TRUE iff line is not parallel to plane.
-BOOL line_plane(const LLVector3 &line_point, const LLVector3 &line_direction,
+// returns true if line is not parallel to plane.
+bool line_plane(const LLVector3 &line_point, const LLVector3 &line_direction,
const LLVector3 &plane_point, const LLVector3 plane_normal,
LLVector3 &intersection);
-// returns TRUE iff line is not parallel to plane.
-BOOL ray_plane(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+// returns true if line is not parallel to plane.
+bool ray_plane(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &plane_point, const LLVector3 plane_normal,
LLVector3 &intersection);
-BOOL ray_circle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_circle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &circle_center, const LLVector3 plane_normal, F32 circle_radius,
LLVector3 &intersection);
// point_0 through point_2 define the plane_normal via the right-hand rule:
// circle from point_0 to point_2 with fingers ==> thumb points in direction of normal
-BOOL ray_triangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_triangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal);
@@ -88,24 +88,24 @@ BOOL ray_triangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
// right-hand-rule... curl fingers from lower-left toward lower-right then toward upper-right
// ==> thumb points in direction of normal
// assumes a parallelogram, so point_3 is determined by the other points
-BOOL ray_quadrangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_quadrangle(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_sphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &sphere_center, F32 sphere_radius,
LLVector3 &intersection, LLVector3 &intersection_normal);
// finite right cylinder is defined by end centers: "cyl_top", "cyl_bottom",
// and by the cylinder radius "cyl_radius"
-BOOL ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_cylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &cyl_center, const LLVector3 &cyl_scale, const LLQuaternion &cyl_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-// this function doesn't just return a BOOL because the return is currently
+// this function doesn't just return a bool because the return is currently
// used to decide how to break up boxes that have been hit by shots...
// a hack that will probably be changed later
//
@@ -117,66 +117,66 @@ U32 ray_box(const LLVector3 &ray_point, const LLVector3 &ray_direction,
/* TODO
-BOOL ray_ellipsoid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_ellipsoid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &e_center, const LLVector3 &e_scale, const LLQuaternion &e_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_cone(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_cone(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &cone_tip, const LLVector3 &cone_bottom,
const LLVector3 &cone_scale, const LLQuaternion &cone_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
*/
-BOOL ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_prism(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &prism_center, const LLVector3 &prism_scale, const LLQuaternion &prism_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_tetrahedron(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &t_center, const LLVector3 &t_scale, const LLQuaternion &t_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_pyramid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &p_center, const LLVector3 &p_scale, const LLQuaternion &p_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
/* TODO
-BOOL ray_hemiellipsoid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_hemiellipsoid(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &e_center, const LLVector3 &e_scale, const LLQuaternion &e_rotation,
const LLVector3 &e_cut_normal,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_hemisphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_hemisphere(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &sphere_center, F32 sphere_radius, const LLVector3 &sphere_cut_normal,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_hemicylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_hemicylinder(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &cyl_top, const LLVector3 &cyl_bottom, F32 cyl_radius,
const LLVector3 &cyl_cut_normal,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL ray_hemicone(const LLVector3 &ray_point, const LLVector3 &ray_direction,
+bool ray_hemicone(const LLVector3 &ray_point, const LLVector3 &ray_direction,
const LLVector3 &cone_tip, const LLVector3 &cone_bottom,
const LLVector3 &cone_scale, const LLVector3 &cyl_cut_normal,
LLVector3 &intersection, LLVector3 &intersection_normal);
*/
-BOOL linesegment_circle(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_circle(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &circle_center, const LLVector3 plane_normal, F32 circle_radius,
LLVector3 &intersection);
// point_0 through point_2 define the plane_normal via the right-hand rule:
// circle from point_0 to point_2 with fingers ==> thumb points in direction of normal
-BOOL linesegment_triangle(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_triangle(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal);
@@ -185,24 +185,24 @@ BOOL linesegment_triangle(const LLVector3 &point_a, const LLVector3 &point_b,
// right-hand-rule... curl fingers from lower-left toward lower-right then toward upper-right
// ==> thumb points in direction of normal
// assumes a parallelogram, so point_3 is determined by the other points
-BOOL linesegment_quadrangle(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_quadrangle(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &point_0, const LLVector3 &point_1, const LLVector3 &point_2,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL linesegment_sphere(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_sphere(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &sphere_center, F32 sphere_radius,
LLVector3 &intersection, LLVector3 &intersection_normal);
// finite right cylinder is defined by end centers: "cyl_top", "cyl_bottom",
// and by the cylinder radius "cyl_radius"
-BOOL linesegment_cylinder(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_cylinder(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &cyl_center, const LLVector3 &cyl_scale, const LLQuaternion &cyl_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-// this function doesn't just return a BOOL because the return is currently
+// this function doesn't just return a bool because the return is currently
// used to decide how to break up boxes that have been hit by shots...
// a hack that will probably be changed later
//
@@ -213,20 +213,17 @@ U32 linesegment_box(const LLVector3 &point_a, const LLVector3 &point_b,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL linesegment_prism(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_prism(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &prism_center, const LLVector3 &prism_scale, const LLQuaternion &prism_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL linesegment_tetrahedron(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_tetrahedron(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &t_center, const LLVector3 &t_scale, const LLQuaternion &t_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-BOOL linesegment_pyramid(const LLVector3 &point_a, const LLVector3 &point_b,
+bool linesegment_pyramid(const LLVector3 &point_a, const LLVector3 &point_b,
const LLVector3 &p_center, const LLVector3 &p_scale, const LLQuaternion &p_rotation,
LLVector3 &intersection, LLVector3 &intersection_normal);
-
-
#endif
-
diff --git a/indra/llmath/tests/llbbox_test.cpp b/indra/llmath/tests/llbbox_test.cpp
index 1f2cd96ab2..bd6bd9e4b0 100644
--- a/indra/llmath/tests/llbbox_test.cpp
+++ b/indra/llmath/tests/llbbox_test.cpp
@@ -340,11 +340,11 @@ namespace tut
LLBBox bbox1(LLVector3(1.0f, 1.0f, 1.0f), LLQuaternion(),
LLVector3(1.0f, 2.0f, 3.0f), LLVector3(3.0f, 4.0f, 5.0f));
- ensure("containsPointLocal(0,0,0)", bbox1.containsPointLocal(LLVector3(0.0f, 0.0f, 0.0f)) == FALSE);
- ensure("containsPointLocal(1,2,3)", bbox1.containsPointLocal(LLVector3(1.0f, 2.0f, 3.0f)) == TRUE);
- ensure("containsPointLocal(0.999,2,3)", bbox1.containsPointLocal(LLVector3(0.999f, 2.0f, 3.0f)) == FALSE);
- ensure("containsPointLocal(3,4,5)", bbox1.containsPointLocal(LLVector3(3.0f, 4.0f, 5.0f)) == TRUE);
- ensure("containsPointLocal(3,4,5.001)", bbox1.containsPointLocal(LLVector3(3.0f, 4.0f, 5.001f)) == FALSE);
+ ensure("containsPointLocal(0,0,0)", bbox1.containsPointLocal(LLVector3(0.0f, 0.0f, 0.0f)) == false);
+ ensure("containsPointLocal(1,2,3)", bbox1.containsPointLocal(LLVector3(1.0f, 2.0f, 3.0f)) == true);
+ ensure("containsPointLocal(0.999,2,3)", bbox1.containsPointLocal(LLVector3(0.999f, 2.0f, 3.0f)) == false);
+ ensure("containsPointLocal(3,4,5)", bbox1.containsPointLocal(LLVector3(3.0f, 4.0f, 5.0f)) == true);
+ ensure("containsPointLocal(3,4,5.001)", bbox1.containsPointLocal(LLVector3(3.0f, 4.0f, 5.001f)) == false);
}
template<> template<>
@@ -357,11 +357,11 @@ namespace tut
LLBBox bbox1(LLVector3(1.0f, 1.0f, 1.0f), LLQuaternion(),
LLVector3(1.0f, 2.0f, 3.0f), LLVector3(3.0f, 4.0f, 5.0f));
- ensure("containsPointAgent(0,0,0)", bbox1.containsPointAgent(LLVector3(0.0f, 0.0f, 0.0f)) == FALSE);
- ensure("containsPointAgent(2,3,4)", bbox1.containsPointAgent(LLVector3(2.0f, 3.0f, 4.0f)) == TRUE);
- ensure("containsPointAgent(2,2.999,4)", bbox1.containsPointAgent(LLVector3(2.0f, 2.999f, 4.0f)) == FALSE);
- ensure("containsPointAgent(4,5,6)", bbox1.containsPointAgent(LLVector3(4.0f, 5.0f, 6.0f)) == TRUE);
- ensure("containsPointAgent(4,5.001,6)", bbox1.containsPointAgent(LLVector3(4.0f, 5.001f, 6.0f)) == FALSE);
+ ensure("containsPointAgent(0,0,0)", bbox1.containsPointAgent(LLVector3(0.0f, 0.0f, 0.0f)) == false);
+ ensure("containsPointAgent(2,3,4)", bbox1.containsPointAgent(LLVector3(2.0f, 3.0f, 4.0f)) == true);
+ ensure("containsPointAgent(2,2.999,4)", bbox1.containsPointAgent(LLVector3(2.0f, 2.999f, 4.0f)) == false);
+ ensure("containsPointAgent(4,5,6)", bbox1.containsPointAgent(LLVector3(4.0f, 5.0f, 6.0f)) == true);
+ ensure("containsPointAgent(4,5.001,6)", bbox1.containsPointAgent(LLVector3(4.0f, 5.001f, 6.0f)) == false);
}
}
diff --git a/indra/llmath/tests/llrect_test.cpp b/indra/llmath/tests/llrect_test.cpp
index ca042a60d7..0fd5602d4a 100644
--- a/indra/llmath/tests/llrect_test.cpp
+++ b/indra/llmath/tests/llrect_test.cpp
@@ -471,13 +471,13 @@ namespace tut
LLRectf rect(1.0f, 3.0f, 3.0f, 1.0f);
- ensure("(0,0) not in rect", rect.pointInRect(0.0f, 0.0f) == FALSE);
- ensure("(2,2) in rect", rect.pointInRect(2.0f, 2.0f) == TRUE);
- ensure("(1,1) in rect", rect.pointInRect(1.0f, 1.0f) == TRUE);
- ensure("(3,3) not in rect", rect.pointInRect(3.0f, 3.0f) == FALSE);
- ensure("(2.999,2.999) in rect", rect.pointInRect(2.999f, 2.999f) == TRUE);
- ensure("(2.999,3.0) not in rect", rect.pointInRect(2.999f, 3.0f) == FALSE);
- ensure("(3.0,2.999) not in rect", rect.pointInRect(3.0f, 2.999f) == FALSE);
+ ensure("(0,0) not in rect", rect.pointInRect(0.0f, 0.0f) == false);
+ ensure("(2,2) in rect", rect.pointInRect(2.0f, 2.0f) == true);
+ ensure("(1,1) in rect", rect.pointInRect(1.0f, 1.0f) == true);
+ ensure("(3,3) not in rect", rect.pointInRect(3.0f, 3.0f) == false);
+ ensure("(2.999,2.999) in rect", rect.pointInRect(2.999f, 2.999f) == true);
+ ensure("(2.999,3.0) not in rect", rect.pointInRect(2.999f, 3.0f) == false);
+ ensure("(3.0,2.999) not in rect", rect.pointInRect(3.0f, 2.999f) == false);
}
template<> template<>
@@ -489,13 +489,13 @@ namespace tut
LLRectf rect(1.0f, 3.0f, 3.0f, 1.0f);
- ensure("(0,0) in local rect", rect.localPointInRect(0.0f, 0.0f) == TRUE);
- ensure("(-0.0001,-0.0001) not in local rect", rect.localPointInRect(-0.0001f, -0.001f) == FALSE);
- ensure("(1,1) in local rect", rect.localPointInRect(1.0f, 1.0f) == TRUE);
- ensure("(2,2) not in local rect", rect.localPointInRect(2.0f, 2.0f) == FALSE);
- ensure("(1.999,1.999) in local rect", rect.localPointInRect(1.999f, 1.999f) == TRUE);
- ensure("(1.999,2.0) not in local rect", rect.localPointInRect(1.999f, 2.0f) == FALSE);
- ensure("(2.0,1.999) not in local rect", rect.localPointInRect(2.0f, 1.999f) == FALSE);
+ ensure("(0,0) in local rect", rect.localPointInRect(0.0f, 0.0f) == true);
+ ensure("(-0.0001,-0.0001) not in local rect", rect.localPointInRect(-0.0001f, -0.001f) == false);
+ ensure("(1,1) in local rect", rect.localPointInRect(1.0f, 1.0f) == true);
+ ensure("(2,2) not in local rect", rect.localPointInRect(2.0f, 2.0f) == false);
+ ensure("(1.999,1.999) in local rect", rect.localPointInRect(1.999f, 1.999f) == true);
+ ensure("(1.999,2.0) not in local rect", rect.localPointInRect(1.999f, 2.0f) == false);
+ ensure("(2.0,1.999) not in local rect", rect.localPointInRect(2.0f, 1.999f) == false);
}
template<> template<>
diff --git a/indra/llmath/tests/mathmisc_test.cpp b/indra/llmath/tests/mathmisc_test.cpp
index 163cf02350..ff0899e975 100644
--- a/indra/llmath/tests/mathmisc_test.cpp
+++ b/indra/llmath/tests/mathmisc_test.cpp
@@ -454,7 +454,7 @@ namespace tut
template<> template<>
void line_object::test<1>()
{
- // this is a test for LLLine::intersects(point) which returns TRUE
+ // this is a test for LLLine::intersects(point) which returns true
// if the line passes within some tolerance of point
// these tests will have some floating point error,
diff --git a/indra/llmath/tests/v2math_test.cpp b/indra/llmath/tests/v2math_test.cpp
index f66142c6a7..860e3ef672 100644
--- a/indra/llmath/tests/v2math_test.cpp
+++ b/indra/llmath/tests/v2math_test.cpp
@@ -93,15 +93,15 @@ namespace tut
{
F32 x =-2.0f, y = -3.0f ;
LLVector2 vec2(x,y);
- ensure_equals("abs():Fail", vec2.abs(), TRUE);
+ ensure_equals("abs():Fail", vec2.abs(), true);
ensure("abs() x", is_approx_equal(vec2.mV[VX], 2.f));
ensure("abs() y", is_approx_equal(vec2.mV[VY], 3.f));
- ensure("isNull():Fail ", FALSE == vec2.isNull()); //Returns TRUE if vector has a _very_small_ length
+ ensure("isNull():Fail ", false == vec2.isNull()); //Returns true if vector has a _very_small_ length
x =.00000001f, y = .000001001f;
vec2.setVec(x, y);
- ensure("isNull(): Fail ", TRUE == vec2.isNull());
+ ensure("isNull(): Fail ", true == vec2.isNull());
}
template<> template<>
@@ -111,12 +111,12 @@ namespace tut
LLVector2 vec2(x, y), vec3;
vec3 = vec3.scaleVec(vec2);
ensure("scaleVec: Fail ", vec3.mV[VX] == 0. && vec3.mV[VY] == 0.);
- ensure("isExactlyZero(): Fail", TRUE == vec3.isExactlyZero());
+ ensure("isExactlyZero(): Fail", true == vec3.isExactlyZero());
vec3.setVec(2.f, 1.f);
vec3 = vec3.scaleVec(vec2);
ensure("scaleVec: Fail ", (2.f == vec3.mV[VX]) && (2.f == vec3.mV[VY]));
- ensure("isExactlyZero():Fail", FALSE == vec3.isExactlyZero());
+ ensure("isExactlyZero():Fail", false == vec3.isExactlyZero());
}
template<> template<>
@@ -254,7 +254,7 @@ namespace tut
vec3.clearVec();
vec2.setVec(x1, y1);
vec3.setVec(vec2);
- ensure("2:operator!= failed", (FALSE == (vec2 != vec3)));
+ ensure("2:operator!= failed", (false == (vec2 != vec3)));
}
template<> template<>
void v2math_object::test<13>()
@@ -373,7 +373,7 @@ namespace tut
x1 = 1.0f, y1 = 2.0f, x2 = 1.0f, y2 = 3.2234f;
vec2.setVec(x1, y1);
vec3.setVec(x2, y2);
- ensure("2:operator < failed", (FALSE == (vec3 < vec2)));
+ ensure("2:operator < failed", (false == (vec3 < vec2)));
}
template<> template<>
diff --git a/indra/llmath/tests/v3color_test.cpp b/indra/llmath/tests/v3color_test.cpp
index d1baa53a9b..8897d48365 100644
--- a/indra/llmath/tests/v3color_test.cpp
+++ b/indra/llmath/tests/v3color_test.cpp
@@ -209,7 +209,7 @@ namespace tut
ensure("1:operator!= failed",(llcolor3 != llcolor3a));
llcolor3.setToBlack();
llcolor3a.setVec(llcolor3);
- ensure("2:operator!= failed", ( FALSE == (llcolor3a != llcolor3)));
+ ensure("2:operator!= failed", ( false == (llcolor3a != llcolor3)));
}
template<> template<>
diff --git a/indra/llmath/tests/v3dmath_test.cpp b/indra/llmath/tests/v3dmath_test.cpp
index 6b58cbd007..db08419012 100644
--- a/indra/llmath/tests/v3dmath_test.cpp
+++ b/indra/llmath/tests/v3dmath_test.cpp
@@ -128,15 +128,15 @@ namespace tut
LLVector3d vec3D(x,y,z);
vec3D.abs();
ensure("1:abs:Fail ", ((-x == vec3D.mdV[VX]) && (y == vec3D.mdV[VY]) && (-z == vec3D.mdV[VZ])));
- ensure("2:isNull():Fail ", (FALSE == vec3D.isNull()));
+ ensure("2:isNull():Fail ", (false == vec3D.isNull()));
vec3D.clearVec();
x =.00000001, y = .000001001, z = .000001001;
vec3D.setVec(x,y,z);
- ensure("3:isNull():Fail ", (TRUE == vec3D.isNull()));
- ensure("4:isExactlyZero():Fail ", (FALSE == vec3D.isExactlyZero()));
+ ensure("3:isNull():Fail ", (true == vec3D.isNull()));
+ ensure("4:isExactlyZero():Fail ", (false == vec3D.isExactlyZero()));
x =.0000000, y = .00000000, z = .00000000;
vec3D.setVec(x,y,z);
- ensure("5:isExactlyZero():Fail ", (TRUE == vec3D.isExactlyZero()));
+ ensure("5:isExactlyZero():Fail ", (true == vec3D.isExactlyZero()));
}
template<> template<>
@@ -353,7 +353,7 @@ namespace tut
{
F64 x1 = 1., y1 = 2., z1 = -1.1;
LLVector3d vec3D(x1,y1,z1), vec3Da;
- ensure("1:operator!= failed",(TRUE == (vec3D !=vec3Da)));
+ ensure("1:operator!= failed",(true == (vec3D !=vec3Da)));
vec3Da = vec3D;
ensure("2:operator== failed",(vec3D ==vec3Da));
vec3D.clearVec();
@@ -362,7 +362,7 @@ namespace tut
vec3D.setVec(x1,y1,z1);
vec3Da.setVec(x1,y1,z1);
ensure("3:operator== failed",(vec3D ==vec3Da));
- ensure("4:operator!= failed",(FALSE == (vec3D !=vec3Da)));
+ ensure("4:operator!= failed",(false == (vec3D !=vec3Da)));
}
template<> template<>
@@ -482,10 +482,10 @@ namespace tut
F64 x = 2.32, y = 1.212, z = -.12;
F64 min = 0.0001, max = 3.0;
LLVector3d vec3d(x,y,z);
- ensure("1:clamp:Fail ", (TRUE == (vec3d.clamp(min, max))));
+ ensure("1:clamp:Fail ", (true == (vec3d.clamp(min, max))));
x = 0.000001f, z = 5.3f;
vec3d.setVec(x,y,z);
- ensure("2:clamp:Fail ", (TRUE == (vec3d.clamp(min, max))));
+ ensure("2:clamp:Fail ", (true == (vec3d.clamp(min, max))));
}
template<> template<>
@@ -494,11 +494,11 @@ namespace tut
F64 x = 10., y = 20., z = -15.;
F64 epsilon = .23425;
LLVector3d vec3Da(x,y,z), vec3Db(x,y,z);
- ensure("1:are_parallel: Fail ", (TRUE == are_parallel(vec3Da,vec3Db,epsilon)));
+ ensure("1:are_parallel: Fail ", (true == are_parallel(vec3Da,vec3Db,epsilon)));
F64 x1 = -12., y1 = -20., z1 = -100.;
vec3Db.clearVec();
vec3Db.setVec(x1,y1,z1);
- ensure("2:are_parallel: Fail ", (FALSE == are_parallel(vec3Da,vec3Db,epsilon)));
+ ensure("2:are_parallel: Fail ", (false == are_parallel(vec3Da,vec3Db,epsilon)));
}
template<> template<>
diff --git a/indra/llmath/tests/v3math_test.cpp b/indra/llmath/tests/v3math_test.cpp
index 7f93aba354..6d95a9e5b7 100644
--- a/indra/llmath/tests/v3math_test.cpp
+++ b/indra/llmath/tests/v3math_test.cpp
@@ -99,7 +99,7 @@ namespace tut
{
F32 x = 2.32f, y = 1.212f, z = -.12f;
LLVector3 vec3(x,y,z);
- ensure("1:isFinite= Fail to initialize ", (TRUE == vec3.isFinite()));//need more test cases:
+ ensure("1:isFinite= Fail to initialize ", (true == vec3.isFinite()));//need more test cases:
vec3.clearVec();
ensure("2:clearVec:Fail to set values ", ((0.f == vec3.mV[VX]) && (0.f == vec3.mV[VY]) && (0.f == vec3.mV[VZ])));
vec3.setVec(x,y,z);
@@ -137,10 +137,10 @@ namespace tut
F32 x = 2.32f, y = 3.212f, z = -.12f;
F32 min = 0.0001f, max = 3.0f;
LLVector3 vec3(x,y,z);
- ensure("1:clamp:Fail ", TRUE == vec3.clamp(min, max) && x == vec3.mV[VX] && max == vec3.mV[VY] && min == vec3.mV[VZ]);
+ ensure("1:clamp:Fail ", true == vec3.clamp(min, max) && x == vec3.mV[VX] && max == vec3.mV[VY] && min == vec3.mV[VZ]);
x = 1.f, y = 2.2f, z = 2.8f;
vec3.setVec(x,y,z);
- ensure("2:clamp:Fail ", FALSE == vec3.clamp(min, max));
+ ensure("2:clamp:Fail ", false == vec3.clamp(min, max));
}
template<> template<>
@@ -157,11 +157,11 @@ namespace tut
{
F32 x =-2.0f, y = -3.0f, z = 1.23f ;
LLVector3 vec3(x,y,z);
- ensure("1:abs():Fail ", (TRUE == vec3.abs()));
- ensure("2:isNull():Fail", (FALSE == vec3.isNull())); //Returns TRUE if vector has a _very_small_ length
+ ensure("1:abs():Fail ", (true == vec3.abs()));
+ ensure("2:isNull():Fail", (false == vec3.isNull())); //Returns true if vector has a _very_small_ length
x =.00000001f, y = .000001001f, z = .000001001f;
vec3.setVec(x,y,z);
- ensure("3:isNull(): Fail ", (TRUE == vec3.isNull()));
+ ensure("3:isNull(): Fail ", (true == vec3.isNull()));
}
template<> template<>
@@ -169,13 +169,13 @@ namespace tut
{
F32 x =-2.0f, y = -3.0f, z = 1.f ;
LLVector3 vec3(x,y,z),vec3a;
- ensure("1:isExactlyZero():Fail ", (TRUE == vec3a.isExactlyZero()));
+ ensure("1:isExactlyZero():Fail ", (true == vec3a.isExactlyZero()));
vec3a = vec3a.scaleVec(vec3);
ensure("2:scaleVec: Fail ", vec3a.mV[VX] == 0.f && vec3a.mV[VY] == 0.f && vec3a.mV[VZ] == 0.f);
vec3a.setVec(x,y,z);
vec3a = vec3a.scaleVec(vec3);
ensure("3:scaleVec: Fail ", ((4 == vec3a.mV[VX]) && (9 == vec3a.mV[VY]) &&(1 == vec3a.mV[VZ])));
- ensure("4:isExactlyZero():Fail ", (FALSE == vec3.isExactlyZero()));
+ ensure("4:isExactlyZero():Fail ", (false == vec3.isExactlyZero()));
}
template<> template<>
@@ -356,7 +356,7 @@ namespace tut
vec3.clearVec();
vec3.clearVec();
vec3a.setVec(vec3);
- ensure("2:operator!= failed", ( FALSE == (vec3a != vec3)));
+ ensure("2:operator!= failed", ( false == (vec3a != vec3)));
}
template<> template<>
@@ -454,15 +454,15 @@ namespace tut
{
F32 x1 =-2.3f, y1 = 2.f,z1 = 1.2f, x2 = 1.3f, y2 = 1.11f, z2 = 1234.234f;
LLVector3 vec3(x1,y1,z1), vec3a(x2,y2,z2);
- ensure("1:operator< failed", (TRUE == (vec3 < vec3a)));
+ ensure("1:operator< failed", (true == (vec3 < vec3a)));
x1 =-2.3f, y1 = 2.f,z1 = 1.2f, x2 = 1.3f, y2 = 2.f, z2 = 1234.234f;
vec3.setVec(x1,y1,z1);
vec3a.setVec(x2,y2,z2);
- ensure("2:operator< failed ", (TRUE == (vec3 < vec3a)));
+ ensure("2:operator< failed ", (true == (vec3 < vec3a)));
x1 =2.3f, y1 = 2.f,z1 = 1.2f, x2 = 1.3f,
vec3.setVec(x1,y1,z1);
vec3a.setVec(x2,y2,z2);
- ensure("3:operator< failed ", (FALSE == (vec3 < vec3a)));
+ ensure("3:operator< failed ", (false == (vec3 < vec3a)));
}
template<> template<>
diff --git a/indra/llmath/tests/v4color_test.cpp b/indra/llmath/tests/v4color_test.cpp
index 3b3adbda0d..e5d914a065 100644
--- a/indra/llmath/tests/v4color_test.cpp
+++ b/indra/llmath/tests/v4color_test.cpp
@@ -49,23 +49,23 @@ namespace tut
void v4color_object::test<1>()
{
LLColor4 llcolor4;
- ensure("1:LLColor4:Fail to initialize ", ((0 == llcolor4.mV[VX]) && (0 == llcolor4.mV[VY]) && (0 == llcolor4.mV[VZ])&& (1.0f == llcolor4.mV[VW])));
+ ensure("1:LLColor4:Fail to initialize ", ((0 == llcolor4.mV[VRED]) && (0 == llcolor4.mV[VGREEN]) && (0 == llcolor4.mV[VBLUE])&& (1.0f == llcolor4.mV[VALPHA])));
F32 r = 0x20, g = 0xFFFF, b = 0xFF, a = 0xAF;
LLColor4 llcolor4a(r,g,b);
- ensure("2:LLColor4:Fail to initialize ", ((r == llcolor4a.mV[VX]) && (g == llcolor4a.mV[VY]) && (b == llcolor4a.mV[VZ])&& (1.0f == llcolor4a.mV[VW])));
+ ensure("2:LLColor4:Fail to initialize ", ((r == llcolor4a.mV[VRED]) && (g == llcolor4a.mV[VGREEN]) && (b == llcolor4a.mV[VBLUE])&& (1.0f == llcolor4a.mV[VALPHA])));
LLColor4 llcolor4b(r,g,b,a);
- ensure("3:LLColor4:Fail to initialize ", ((r == llcolor4b.mV[VX]) && (g == llcolor4b.mV[VY]) && (b == llcolor4b.mV[VZ])&& (a == llcolor4b.mV[VW])));
+ ensure("3:LLColor4:Fail to initialize ", ((r == llcolor4b.mV[VRED]) && (g == llcolor4b.mV[VGREEN]) && (b == llcolor4b.mV[VBLUE])&& (a == llcolor4b.mV[VALPHA])));
const F32 vec[4] = {.112f ,23.2f, -4.2f, -.0001f};
LLColor4 llcolor4c(vec);
- ensure("4:LLColor4:Fail to initialize ", ((vec[0] == llcolor4c.mV[VX]) && (vec[1] == llcolor4c.mV[VY]) && (vec[2] == llcolor4c.mV[VZ])&& (vec[3] == llcolor4c.mV[VW])));
+ ensure("4:LLColor4:Fail to initialize ", ((vec[0] == llcolor4c.mV[VRED]) && (vec[1] == llcolor4c.mV[VGREEN]) && (vec[2] == llcolor4c.mV[VBLUE])&& (vec[3] == llcolor4c.mV[VALPHA])));
LLColor3 llcolor3(-2.23f,1.01f,42.3f);
F32 val = -.1f;
LLColor4 llcolor4d(llcolor3,val);
- ensure("5:LLColor4:Fail to initialize ", ((llcolor3.mV[VX] == llcolor4d.mV[VX]) && (llcolor3.mV[VY] == llcolor4d.mV[VY]) && (llcolor3.mV[VZ] == llcolor4d.mV[VZ])&& (val == llcolor4d.mV[VW])));
+ ensure("5:LLColor4:Fail to initialize ", ((llcolor3.mV[VRED] == llcolor4d.mV[VRED]) && (llcolor3.mV[VGREEN] == llcolor4d.mV[VGREEN]) && (llcolor3.mV[VBLUE] == llcolor4d.mV[VBLUE])&& (val == llcolor4d.mV[VALPHA])));
LLSD sd = llcolor4d.getValue();
LLColor4 llcolor4e(sd);
@@ -76,7 +76,7 @@ namespace tut
LLColor4 llcolor4g(color4u);
const F32 SCALE = 1.f/255.f;
F32 r2 = r1*SCALE, g2 = g1* SCALE, b2 = b1* SCALE;
- ensure("7:LLColor4:Fail to initialize ", ((r2 == llcolor4g.mV[VX]) && (g2 == llcolor4g.mV[VY]) && (b2 == llcolor4g.mV[VZ])));
+ ensure("7:LLColor4:Fail to initialize ", ((r2 == llcolor4g.mV[VRED]) && (g2 == llcolor4g.mV[VGREEN]) && (b2 == llcolor4g.mV[VBLUE])));
}
template<> template<>
@@ -98,10 +98,10 @@ namespace tut
F32 r = 0x20, g = 0xFFFF, b = 0xFF,a = 0xAF;
LLColor4 llcolor4(r,g,b,a);
llcolor4.setToBlack();
- ensure("setToBlack:Fail to set the black ", ((0 == llcolor4.mV[VX]) && (0 == llcolor4.mV[VY]) && (0 == llcolor4.mV[VZ])&& (1.0f == llcolor4.mV[VW])));
+ ensure("setToBlack:Fail to set the black ", ((0 == llcolor4.mV[VRED]) && (0 == llcolor4.mV[VGREEN]) && (0 == llcolor4.mV[VBLUE])&& (1.0f == llcolor4.mV[VALPHA])));
llcolor4.setToWhite();
- ensure("setToWhite:Fail to set the white ", ((1.f == llcolor4.mV[VX]) && (1.f == llcolor4.mV[VY]) && (1.f == llcolor4.mV[VZ])&& (1.0f == llcolor4.mV[VW])));
+ ensure("setToWhite:Fail to set the white ", ((1.f == llcolor4.mV[VRED]) && (1.f == llcolor4.mV[VGREEN]) && (1.f == llcolor4.mV[VBLUE])&& (1.0f == llcolor4.mV[VALPHA])));
}
template<> template<>
@@ -110,10 +110,10 @@ namespace tut
F32 r = 0x20, g = 0xFFFF, b = 0xFF, a = 0xAF;
LLColor4 llcolor4;
llcolor4.setVec(r,g,b);
- ensure("1:setVec:Fail to set the values ", ((r == llcolor4.mV[VX]) && (g == llcolor4.mV[VY]) && (b == llcolor4.mV[VZ])&& (1.f == llcolor4.mV[VW])));
+ ensure("1:setVec:Fail to set the values ", ((r == llcolor4.mV[VRED]) && (g == llcolor4.mV[VGREEN]) && (b == llcolor4.mV[VBLUE])&& (1.f == llcolor4.mV[VALPHA])));
llcolor4.setVec(r,g,b,a);
- ensure("2:setVec:Fail to set the values ", ((r == llcolor4.mV[VX]) && (g == llcolor4.mV[VY]) && (b == llcolor4.mV[VZ])&& (a == llcolor4.mV[VW])));
+ ensure("2:setVec:Fail to set the values ", ((r == llcolor4.mV[VRED]) && (g == llcolor4.mV[VGREEN]) && (b == llcolor4.mV[VBLUE])&& (a == llcolor4.mV[VALPHA])));
LLColor4 llcolor4a;
llcolor4a.setVec(llcolor4);
@@ -121,23 +121,23 @@ namespace tut
LLColor3 llcolor3(-2.23f,1.01f,42.3f);
llcolor4a.setVec(llcolor3);
- ensure("4:setVec:Fail to set the values ", ((llcolor3.mV[VX] == llcolor4a.mV[VX]) && (llcolor3.mV[VY] == llcolor4a.mV[VY]) && (llcolor3.mV[VZ] == llcolor4a.mV[VZ])));
+ ensure("4:setVec:Fail to set the values ", ((llcolor3.mV[VRED] == llcolor4a.mV[VRED]) && (llcolor3.mV[VGREEN] == llcolor4a.mV[VGREEN]) && (llcolor3.mV[VBLUE] == llcolor4a.mV[VBLUE])));
F32 val = -.33f;
llcolor4a.setVec(llcolor3,val);
- ensure("4:setVec:Fail to set the values ", ((llcolor3.mV[VX] == llcolor4a.mV[VX]) && (llcolor3.mV[VY] == llcolor4a.mV[VY]) && (llcolor3.mV[VZ] == llcolor4a.mV[VZ]) && (val == llcolor4a.mV[VW])));
+ ensure("4:setVec:Fail to set the values ", ((llcolor3.mV[VRED] == llcolor4a.mV[VRED]) && (llcolor3.mV[VGREEN] == llcolor4a.mV[VGREEN]) && (llcolor3.mV[VBLUE] == llcolor4a.mV[VBLUE]) && (val == llcolor4a.mV[VALPHA])));
const F32 vec[4] = {.112f ,23.2f, -4.2f, -.0001f};
LLColor4 llcolor4c;
llcolor4c.setVec(vec);
- ensure("5:setVec:Fail to initialize ", ((vec[0] == llcolor4c.mV[VX]) && (vec[1] == llcolor4c.mV[VY]) && (vec[2] == llcolor4c.mV[VZ])&& (vec[3] == llcolor4c.mV[VW])));
+ ensure("5:setVec:Fail to initialize ", ((vec[0] == llcolor4c.mV[VRED]) && (vec[1] == llcolor4c.mV[VGREEN]) && (vec[2] == llcolor4c.mV[VBLUE])&& (vec[3] == llcolor4c.mV[VALPHA])));
U8 r1 = 0xF2, g1 = 0xFA, b1= 0xBF;
LLColor4U color4u(r1,g1,b1);
llcolor4.setVec(color4u);
const F32 SCALE = 1.f/255.f;
F32 r2 = r1*SCALE, g2 = g1* SCALE, b2 = b1* SCALE;
- ensure("6:setVec:Fail to initialize ", ((r2 == llcolor4.mV[VX]) && (g2 == llcolor4.mV[VY]) && (b2 == llcolor4.mV[VZ])));
+ ensure("6:setVec:Fail to initialize ", ((r2 == llcolor4.mV[VRED]) && (g2 == llcolor4.mV[VGREEN]) && (b2 == llcolor4.mV[VBLUE])));
}
template<> template<>
@@ -146,7 +146,7 @@ namespace tut
F32 alpha = 0xAF;
LLColor4 llcolor4;
llcolor4.setAlpha(alpha);
- ensure("setAlpha:Fail to initialize ", (alpha == llcolor4.mV[VW]));
+ ensure("setAlpha:Fail to initialize ", (alpha == llcolor4.mV[VALPHA]));
}
template<> template<>
@@ -209,7 +209,7 @@ namespace tut
LLColor3 llcolor3(r,g,b);
LLColor4 llcolor4a,llcolor4b;
llcolor4a = llcolor3;
- ensure("Operator=:Fail to initialize ", ((llcolor3.mV[0] == llcolor4a.mV[VX]) && (llcolor3.mV[1] == llcolor4a.mV[VY]) && (llcolor3.mV[2] == llcolor4a.mV[VZ])));
+ ensure("Operator=:Fail to initialize ", ((llcolor3.mV[0] == llcolor4a.mV[VRED]) && (llcolor3.mV[1] == llcolor4a.mV[VGREEN]) && (llcolor3.mV[2] == llcolor4a.mV[VBLUE])));
LLSD sd = llcolor4a.getValue();
llcolor4b = LLColor4(sd);
ensure_equals("Operator= LLSD:Fail ", llcolor4a, llcolor4b);
@@ -234,10 +234,10 @@ namespace tut
F32 r2 = 0xABF, g2 = 0xFB, b2 = 0xFFF;
LLColor4 llcolor4a(r1,g1,b1),llcolor4b(r2,g2,b2),llcolor4c;
llcolor4c = llcolor4b + llcolor4a;
- ensure("operator+:Fail to Add the values ", (is_approx_equal(r1+r2,llcolor4c.mV[VX]) && is_approx_equal(g1+g2,llcolor4c.mV[VY]) && is_approx_equal(b1+b2,llcolor4c.mV[VZ])));
+ ensure("operator+:Fail to Add the values ", (is_approx_equal(r1+r2,llcolor4c.mV[VRED]) && is_approx_equal(g1+g2,llcolor4c.mV[VGREEN]) && is_approx_equal(b1+b2,llcolor4c.mV[VBLUE])));
llcolor4b += llcolor4a;
- ensure("operator+=:Fail to Add the values ", (is_approx_equal(r1+r2,llcolor4b.mV[VX]) && is_approx_equal(g1+g2,llcolor4b.mV[VY]) && is_approx_equal(b1+b2,llcolor4b.mV[VZ])));
+ ensure("operator+=:Fail to Add the values ", (is_approx_equal(r1+r2,llcolor4b.mV[VRED]) && is_approx_equal(g1+g2,llcolor4b.mV[VGREEN]) && is_approx_equal(b1+b2,llcolor4b.mV[VBLUE])));
}
template<> template<>
@@ -247,10 +247,10 @@ namespace tut
F32 r2 = 0xABF, g2 = 0xFB, b2 = 0xFFF;
LLColor4 llcolor4a(r1,g1,b1),llcolor4b(r2,g2,b2),llcolor4c;
llcolor4c = llcolor4a - llcolor4b;
- ensure("operator-:Fail to subtract the values ", (is_approx_equal(r1-r2,llcolor4c.mV[VX]) && is_approx_equal(g1-g2,llcolor4c.mV[VY]) && is_approx_equal(b1-b2,llcolor4c.mV[VZ])));
+ ensure("operator-:Fail to subtract the values ", (is_approx_equal(r1-r2,llcolor4c.mV[VRED]) && is_approx_equal(g1-g2,llcolor4c.mV[VGREEN]) && is_approx_equal(b1-b2,llcolor4c.mV[VBLUE])));
llcolor4a -= llcolor4b;
- ensure("operator-=:Fail to subtract the values ", (is_approx_equal(r1-r2,llcolor4a.mV[VX]) && is_approx_equal(g1-g2,llcolor4a.mV[VY]) && is_approx_equal(b1-b2,llcolor4a.mV[VZ])));
+ ensure("operator-=:Fail to subtract the values ", (is_approx_equal(r1-r2,llcolor4a.mV[VRED]) && is_approx_equal(g1-g2,llcolor4a.mV[VGREEN]) && is_approx_equal(b1-b2,llcolor4a.mV[VBLUE])));
}
template<> template<>
@@ -260,20 +260,20 @@ namespace tut
F32 r2 = 0xABF, g2 = 0xFB, b2 = 0xFFF;
LLColor4 llcolor4a(r1,g1,b1),llcolor4b(r2,g2,b2),llcolor4c;
llcolor4c = llcolor4a * llcolor4b;
- ensure("1:operator*:Fail to multiply the values", (is_approx_equal(r1*r2,llcolor4c.mV[VX]) && is_approx_equal(g1*g2,llcolor4c.mV[VY]) && is_approx_equal(b1*b2,llcolor4c.mV[VZ])));
+ ensure("1:operator*:Fail to multiply the values", (is_approx_equal(r1*r2,llcolor4c.mV[VRED]) && is_approx_equal(g1*g2,llcolor4c.mV[VGREEN]) && is_approx_equal(b1*b2,llcolor4c.mV[VBLUE])));
F32 mulVal = 3.33f;
llcolor4c = llcolor4a * mulVal;
- ensure("2:operator*:Fail ", (is_approx_equal(r1*mulVal,llcolor4c.mV[VX]) && is_approx_equal(g1*mulVal,llcolor4c.mV[VY]) && is_approx_equal(b1*mulVal,llcolor4c.mV[VZ])));
+ ensure("2:operator*:Fail ", (is_approx_equal(r1*mulVal,llcolor4c.mV[VRED]) && is_approx_equal(g1*mulVal,llcolor4c.mV[VGREEN]) && is_approx_equal(b1*mulVal,llcolor4c.mV[VBLUE])));
llcolor4c = mulVal * llcolor4a;
- ensure("3:operator*:Fail to multiply the values", (is_approx_equal(r1*mulVal,llcolor4c.mV[VX]) && is_approx_equal(g1*mulVal,llcolor4c.mV[VY]) && is_approx_equal(b1*mulVal,llcolor4c.mV[VZ])));
+ ensure("3:operator*:Fail to multiply the values", (is_approx_equal(r1*mulVal,llcolor4c.mV[VRED]) && is_approx_equal(g1*mulVal,llcolor4c.mV[VGREEN]) && is_approx_equal(b1*mulVal,llcolor4c.mV[VBLUE])));
llcolor4a *= mulVal;
- ensure("4:operator*=:Fail to multiply the values ", (is_approx_equal(r1*mulVal,llcolor4a.mV[VX]) && is_approx_equal(g1*mulVal,llcolor4a.mV[VY]) && is_approx_equal(b1*mulVal,llcolor4a.mV[VZ])));
+ ensure("4:operator*=:Fail to multiply the values ", (is_approx_equal(r1*mulVal,llcolor4a.mV[VRED]) && is_approx_equal(g1*mulVal,llcolor4a.mV[VGREEN]) && is_approx_equal(b1*mulVal,llcolor4a.mV[VBLUE])));
LLColor4 llcolor4d(r1,g1,b1),llcolor4e(r2,g2,b2);
llcolor4e *= llcolor4d;
- ensure("5:operator*=:Fail to multiply the values ", (is_approx_equal(r1*r2,llcolor4e.mV[VX]) && is_approx_equal(g1*g2,llcolor4e.mV[VY]) && is_approx_equal(b1*b2,llcolor4e.mV[VZ])));
+ ensure("5:operator*=:Fail to multiply the values ", (is_approx_equal(r1*r2,llcolor4e.mV[VRED]) && is_approx_equal(g1*g2,llcolor4e.mV[VGREEN]) && is_approx_equal(b1*b2,llcolor4e.mV[VBLUE])));
}
template<> template<>
@@ -283,13 +283,13 @@ namespace tut
F32 div = 12.345f;
LLColor4 llcolor4a(r,g,b,a),llcolor4b;
llcolor4b = llcolor4a % div;//chnage only alpha value nor r,g,b;
- ensure("1operator%:Fail ", (is_approx_equal(r,llcolor4b.mV[VX]) && is_approx_equal(g,llcolor4b.mV[VY]) && is_approx_equal(b,llcolor4b.mV[VZ])&& is_approx_equal(div*a,llcolor4b.mV[VW])));
+ ensure("1operator%:Fail ", (is_approx_equal(r,llcolor4b.mV[VRED]) && is_approx_equal(g,llcolor4b.mV[VGREEN]) && is_approx_equal(b,llcolor4b.mV[VBLUE])&& is_approx_equal(div*a,llcolor4b.mV[VALPHA])));
llcolor4b = div % llcolor4a;
- ensure("2operator%:Fail ", (is_approx_equal(r,llcolor4b.mV[VX]) && is_approx_equal(g,llcolor4b.mV[VY]) && is_approx_equal(b,llcolor4b.mV[VZ])&& is_approx_equal(div*a,llcolor4b.mV[VW])));
+ ensure("2operator%:Fail ", (is_approx_equal(r,llcolor4b.mV[VRED]) && is_approx_equal(g,llcolor4b.mV[VGREEN]) && is_approx_equal(b,llcolor4b.mV[VBLUE])&& is_approx_equal(div*a,llcolor4b.mV[VALPHA])));
llcolor4a %= div;
- ensure("operator%=:Fail ", (is_approx_equal(a*div,llcolor4a.mV[VW])));
+ ensure("operator%=:Fail ", (is_approx_equal(a*div,llcolor4a.mV[VALPHA])));
}
template<> template<>
@@ -312,7 +312,7 @@ namespace tut
F32 r = 0x20, g = 0xFFFF, b = 0xFF;
LLColor4 llcolor4a(r,g,b),llcolor4b;
LLColor3 llcolor3 = vec4to3(llcolor4a);
- ensure("vec4to3:Fail to convert vec4 to vec3 ", (is_approx_equal(llcolor3.mV[VX],llcolor4a.mV[VX]) && is_approx_equal(llcolor3.mV[VY],llcolor4a.mV[VY]) && is_approx_equal(llcolor3.mV[VZ],llcolor4a.mV[VZ])));
+ ensure("vec4to3:Fail to convert vec4 to vec3 ", (is_approx_equal(llcolor3.mV[VRED],llcolor4a.mV[VRED]) && is_approx_equal(llcolor3.mV[VGREEN],llcolor4a.mV[VGREEN]) && is_approx_equal(llcolor3.mV[VBLUE],llcolor4a.mV[VBLUE])));
llcolor4b = vec3to4(llcolor3);
ensure_equals("vec3to4:Fail to convert vec3 to vec4 ", llcolor4b, llcolor4a);
}
@@ -324,7 +324,7 @@ namespace tut
F32 r2 = 0xABF, g2 = 0xFB, b2 = 0xFFF;
LLColor4 llcolor4a(r1,g1,b1),llcolor4b(r2,g2,b2),llcolor4c;
llcolor4c = lerp(llcolor4a,llcolor4b,val);
- ensure("lerp:Fail ", (is_approx_equal(r1 + (r2 - r1)* val,llcolor4c.mV[VX]) && is_approx_equal(g1 + (g2 - g1)* val,llcolor4c.mV[VY]) && is_approx_equal(b1 + (b2 - b1)* val,llcolor4c.mV[VZ])));
+ ensure("lerp:Fail ", (is_approx_equal(r1 + (r2 - r1)* val,llcolor4c.mV[VRED]) && is_approx_equal(g1 + (g2 - g1)* val,llcolor4c.mV[VGREEN]) && is_approx_equal(b1 + (b2 - b1)* val,llcolor4c.mV[VBLUE])));
}
template<> template<>
diff --git a/indra/llmath/tests/v4coloru_test.cpp b/indra/llmath/tests/v4coloru_test.cpp
index 2b6ee952a3..9d707d18c5 100644
--- a/indra/llmath/tests/v4coloru_test.cpp
+++ b/indra/llmath/tests/v4coloru_test.cpp
@@ -48,18 +48,18 @@ namespace tut
void v4coloru_object::test<1>()
{
LLColor4U llcolor4u;
- ensure("1:LLColor4u:Fail to initialize ", ((0 == llcolor4u.mV[VX]) && (0 == llcolor4u.mV[VY]) && (0 == llcolor4u.mV[VZ])&& (255 == llcolor4u.mV[VW])));
+ ensure("1:LLColor4u:Fail to initialize ", ((0 == llcolor4u.mV[VRED]) && (0 == llcolor4u.mV[VGREEN]) && (0 == llcolor4u.mV[VBLUE])&& (255 == llcolor4u.mV[VALPHA])));
U8 r = 0x12, g = 0xFF, b = 0xAF, a = 0x23;
LLColor4U llcolor4u1(r,g,b);
- ensure("2:LLColor4u:Fail to initialize ", ((r == llcolor4u1.mV[VX]) && (g == llcolor4u1.mV[VY]) && (b == llcolor4u1.mV[VZ])&& (255 == llcolor4u1.mV[VW])));
+ ensure("2:LLColor4u:Fail to initialize ", ((r == llcolor4u1.mV[VRED]) && (g == llcolor4u1.mV[VGREEN]) && (b == llcolor4u1.mV[VBLUE])&& (255 == llcolor4u1.mV[VALPHA])));
LLColor4U llcolor4u2(r,g,b,a);
- ensure("3:LLColor4u:Fail to initialize ", ((r == llcolor4u2.mV[VX]) && (g == llcolor4u2.mV[VY]) && (b == llcolor4u2.mV[VZ])&& (a == llcolor4u2.mV[VW])));
+ ensure("3:LLColor4u:Fail to initialize ", ((r == llcolor4u2.mV[VRED]) && (g == llcolor4u2.mV[VGREEN]) && (b == llcolor4u2.mV[VBLUE])&& (a == llcolor4u2.mV[VALPHA])));
const U8 vec[4] = {0x12,0xFF,0xAF,0x23};
LLColor4U llcolor4u3(vec);
- ensure("4:LLColor4u:Fail to initialize ", ((vec[0] == llcolor4u3.mV[VX]) && (vec[1] == llcolor4u3.mV[VY]) && (vec[2] == llcolor4u3.mV[VZ])&& (vec[3] == llcolor4u3.mV[VW])));
+ ensure("4:LLColor4u:Fail to initialize ", ((vec[0] == llcolor4u3.mV[VRED]) && (vec[1] == llcolor4u3.mV[VGREEN]) && (vec[2] == llcolor4u3.mV[VBLUE])&& (vec[3] == llcolor4u3.mV[VALPHA])));
LLSD sd = llcolor4u3.getValue();
LLColor4U llcolor4u4(sd);
@@ -82,10 +82,10 @@ namespace tut
U8 r = 0x12, g = 0xFF, b = 0xAF, a = 0x23;
LLColor4U llcolor4u(r,g,b,a);
llcolor4u.setToBlack();
- ensure("setToBlack:Fail to set black ", ((0 == llcolor4u.mV[VX]) && (0 == llcolor4u.mV[VY]) && (0 == llcolor4u.mV[VZ])&& (255 == llcolor4u.mV[VW])));
+ ensure("setToBlack:Fail to set black ", ((0 == llcolor4u.mV[VRED]) && (0 == llcolor4u.mV[VGREEN]) && (0 == llcolor4u.mV[VBLUE])&& (255 == llcolor4u.mV[VALPHA])));
llcolor4u.setToWhite();
- ensure("setToWhite:Fail to white ", ((255 == llcolor4u.mV[VX]) && (255 == llcolor4u.mV[VY]) && (255 == llcolor4u.mV[VZ])&& (255 == llcolor4u.mV[VW])));
+ ensure("setToWhite:Fail to white ", ((255 == llcolor4u.mV[VRED]) && (255 == llcolor4u.mV[VGREEN]) && (255 == llcolor4u.mV[VBLUE])&& (255 == llcolor4u.mV[VALPHA])));
}
template<> template<>
@@ -104,11 +104,11 @@ namespace tut
U8 r = 0x12, g = 0xFF, b = 0xAF, a = 0x23;
LLColor4U llcolor4u;
llcolor4u.setVec(r,g,b,a);
- ensure("1:setVec:Fail to set the values ", ((r == llcolor4u.mV[VX]) && (g == llcolor4u.mV[VY]) && (b == llcolor4u.mV[VZ])&& (a == llcolor4u.mV[VW])));
+ ensure("1:setVec:Fail to set the values ", ((r == llcolor4u.mV[VRED]) && (g == llcolor4u.mV[VGREEN]) && (b == llcolor4u.mV[VBLUE])&& (a == llcolor4u.mV[VALPHA])));
llcolor4u.setToBlack();
llcolor4u.setVec(r,g,b);
- ensure("2:setVec:Fail to set the values ", ((r == llcolor4u.mV[VX]) && (g == llcolor4u.mV[VY]) && (b == llcolor4u.mV[VZ])&& (255 == llcolor4u.mV[VW])));
+ ensure("2:setVec:Fail to set the values ", ((r == llcolor4u.mV[VRED]) && (g == llcolor4u.mV[VGREEN]) && (b == llcolor4u.mV[VBLUE])&& (255 == llcolor4u.mV[VALPHA])));
LLColor4U llcolor4u1;
llcolor4u1.setVec(llcolor4u);
@@ -117,7 +117,7 @@ namespace tut
const U8 vec[4] = {0x12,0xFF,0xAF,0x23};
LLColor4U llcolor4u2;
llcolor4u2.setVec(vec);
- ensure("4:setVec:Fail to set the values ", ((vec[0] == llcolor4u2.mV[VX]) && (vec[1] == llcolor4u2.mV[VY]) && (vec[2] == llcolor4u2.mV[VZ])&& (vec[3] == llcolor4u2.mV[VW])));
+ ensure("4:setVec:Fail to set the values ", ((vec[0] == llcolor4u2.mV[VRED]) && (vec[1] == llcolor4u2.mV[VGREEN]) && (vec[2] == llcolor4u2.mV[VBLUE])&& (vec[3] == llcolor4u2.mV[VALPHA])));
}
template<> template<>
@@ -126,7 +126,7 @@ namespace tut
U8 alpha = 0x12;
LLColor4U llcolor4u;
llcolor4u.setAlpha(alpha);
- ensure("setAlpha:Fail to set alpha value ", (alpha == llcolor4u.mV[VW]));
+ ensure("setAlpha:Fail to set alpha value ", (alpha == llcolor4u.mV[VALPHA]));
}
template<> template<>
@@ -159,29 +159,29 @@ namespace tut
llcolor4u3 = llcolor4u1 + llcolor4u2;
ensure_equals(
"1a.operator+:Fail to Add the values ",
- llcolor4u3.mV[VX],
+ llcolor4u3.mV[VRED],
(U8)(r1+r2));
ensure_equals(
"1b.operator+:Fail to Add the values ",
- llcolor4u3.mV[VY],
+ llcolor4u3.mV[VGREEN],
(U8)(g1+g2));
ensure_equals(
"1c.operator+:Fail to Add the values ",
- llcolor4u3.mV[VZ],
+ llcolor4u3.mV[VBLUE],
(U8)(b1+b2));
llcolor4u2 += llcolor4u1;
ensure_equals(
"2a.operator+=:Fail to Add the values ",
- llcolor4u2.mV[VX],
+ llcolor4u2.mV[VRED],
(U8)(r1+r2));
ensure_equals(
"2b.operator+=:Fail to Add the values ",
- llcolor4u2.mV[VY],
+ llcolor4u2.mV[VGREEN],
(U8)(g1+g2));
ensure_equals(
"2c.operator+=:Fail to Add the values ",
- llcolor4u2.mV[VZ],
+ llcolor4u2.mV[VBLUE],
(U8)(b1+b2));
}
@@ -194,29 +194,29 @@ namespace tut
llcolor4u3 = llcolor4u1 - llcolor4u2;
ensure_equals(
"1a. operator-:Fail to Add the values ",
- llcolor4u3.mV[VX],
+ llcolor4u3.mV[VRED],
(U8)(r1-r2));
ensure_equals(
"1b. operator-:Fail to Add the values ",
- llcolor4u3.mV[VY],
+ llcolor4u3.mV[VGREEN],
(U8)(g1-g2));
ensure_equals(
"1c. operator-:Fail to Add the values ",
- llcolor4u3.mV[VZ],
+ llcolor4u3.mV[VBLUE],
(U8)(b1-b2));
llcolor4u1 -= llcolor4u2;
ensure_equals(
"2a. operator-=:Fail to Add the values ",
- llcolor4u1.mV[VX],
+ llcolor4u1.mV[VRED],
(U8)(r1-r2));
ensure_equals(
"2b. operator-=:Fail to Add the values ",
- llcolor4u1.mV[VY],
+ llcolor4u1.mV[VGREEN],
(U8)(g1-g2));
ensure_equals(
"2c. operator-=:Fail to Add the values ",
- llcolor4u1.mV[VZ],
+ llcolor4u1.mV[VBLUE],
(U8)(b1-b2));
}
@@ -229,30 +229,30 @@ namespace tut
llcolor4u3 = llcolor4u1 * llcolor4u2;
ensure_equals(
"1a. operator*:Fail to multiply the values",
- llcolor4u3.mV[VX],
+ llcolor4u3.mV[VRED],
(U8)(r1*r2));
ensure_equals(
"1b. operator*:Fail to multiply the values",
- llcolor4u3.mV[VY],
+ llcolor4u3.mV[VGREEN],
(U8)(g1*g2));
ensure_equals(
"1c. operator*:Fail to multiply the values",
- llcolor4u3.mV[VZ],
+ llcolor4u3.mV[VBLUE],
(U8)(b1*b2));
U8 mulVal = 123;
llcolor4u1 *= mulVal;
ensure_equals(
"2a. operator*=:Fail to multiply the values",
- llcolor4u1.mV[VX],
+ llcolor4u1.mV[VRED],
(U8)(r1*mulVal));
ensure_equals(
"2b. operator*=:Fail to multiply the values",
- llcolor4u1.mV[VY],
+ llcolor4u1.mV[VGREEN],
(U8)(g1*mulVal));
ensure_equals(
"2c. operator*=:Fail to multiply the values",
- llcolor4u1.mV[VZ],
+ llcolor4u1.mV[VBLUE],
(U8)(b1*mulVal));
}
@@ -274,7 +274,7 @@ namespace tut
LLColor4U llcolor4u(r,g,b,a);
U8 modVal = 45;
llcolor4u %= modVal;
- ensure_equals("operator%=:Fail ", llcolor4u.mV[VW], (U8)(a * modVal));
+ ensure_equals("operator%=:Fail ", llcolor4u.mV[VALPHA], (U8)(a * modVal));
}
template<> template<>
@@ -284,13 +284,13 @@ namespace tut
LLColor4U llcolor4u1(r,g,b,a);
std::string color("12, 23, 132, 50");
LLColor4U::parseColor4U(color, &llcolor4u1);
- ensure("parseColor4U() failed to parse the color value ", ((12 == llcolor4u1.mV[VX]) && (23 == llcolor4u1.mV[VY]) && (132 == llcolor4u1.mV[VZ])&& (50 == llcolor4u1.mV[VW])));
+ ensure("parseColor4U() failed to parse the color value ", ((12 == llcolor4u1.mV[VRED]) && (23 == llcolor4u1.mV[VGREEN]) && (132 == llcolor4u1.mV[VBLUE])&& (50 == llcolor4u1.mV[VALPHA])));
color = "12, 23, 132";
- ensure("2:parseColor4U() failed to parse the color value ", (FALSE == LLColor4U::parseColor4U(color, &llcolor4u1)));
+ ensure("2:parseColor4U() failed to parse the color value ", (false == LLColor4U::parseColor4U(color, &llcolor4u1)));
color = "12";
- ensure("2:parseColor4U() failed to parse the color value ", (FALSE == LLColor4U::parseColor4U(color, &llcolor4u1)));
+ ensure("2:parseColor4U() failed to parse the color value ", (false == LLColor4U::parseColor4U(color, &llcolor4u1)));
}
template<> template<>
@@ -300,8 +300,8 @@ namespace tut
LLColor4U llcolor4u(r,g,b,a),llcolor4u1;
const F32 fVal = 3.f;
llcolor4u1 = llcolor4u.multAll(fVal);
- ensure("multAll:Fail to multiply ", (((U8)ll_round(r * fVal) == llcolor4u1.mV[VX]) && (U8)ll_round(g * fVal) == llcolor4u1.mV[VY]
- && ((U8)ll_round(b * fVal) == llcolor4u1.mV[VZ])&& ((U8)ll_round(a * fVal) == llcolor4u1.mV[VW])));
+ ensure("multAll:Fail to multiply ", (((U8)ll_round(r * fVal) == llcolor4u1.mV[VRED]) && (U8)ll_round(g * fVal) == llcolor4u1.mV[VGREEN]
+ && ((U8)ll_round(b * fVal) == llcolor4u1.mV[VBLUE])&& ((U8)ll_round(a * fVal) == llcolor4u1.mV[VALPHA])));
}
template<> template<>
@@ -311,13 +311,13 @@ namespace tut
U8 r2 = 23, g2 = 230, b2 = 124, a2 = 255;
LLColor4U llcolor4u(r1,g1,b1,a1),llcolor4u1(r2,g2,b2,a2);
llcolor4u1 = llcolor4u1.addClampMax(llcolor4u);
- ensure("1:addClampMax():Fail to add the value ", ((r1+r2 == llcolor4u1.mV[VX]) && (255 == llcolor4u1.mV[VY]) && (b1+b2 == llcolor4u1.mV[VZ])&& (255 == llcolor4u1.mV[VW])));
+ ensure("1:addClampMax():Fail to add the value ", ((r1+r2 == llcolor4u1.mV[VRED]) && (255 == llcolor4u1.mV[VGREEN]) && (b1+b2 == llcolor4u1.mV[VBLUE])&& (255 == llcolor4u1.mV[VALPHA])));
r1 = 132, g1 = 3, b1 = 3, a1 = 2;
r2 = 123, g2 = 230, b2 = 154, a2 = 25;
LLColor4U llcolor4u2(r1,g1,b1,a1),llcolor4u3(r2,g2,b2,a2);
llcolor4u3 = llcolor4u3.addClampMax(llcolor4u2);
- ensure("2:addClampMax():Fail to add the value ", ((255 == llcolor4u3.mV[VX]) && (g1+g2 == llcolor4u3.mV[VY]) && (b1+b2 == llcolor4u3.mV[VZ])&& (a1+a2 == llcolor4u3.mV[VW])));
+ ensure("2:addClampMax():Fail to add the value ", ((255 == llcolor4u3.mV[VRED]) && (g1+g2 == llcolor4u3.mV[VGREEN]) && (b1+b2 == llcolor4u3.mV[VBLUE])&& (a1+a2 == llcolor4u3.mV[VALPHA])));
}
template<> template<>
@@ -331,6 +331,6 @@ namespace tut
F32 color_scale_factor = MAX_COLOR/r;
S32 r2 = ll_round(r * color_scale_factor);
S32 g2 = ll_round(g * color_scale_factor);
- ensure("setVecScaleClamp():Fail to add the value ", ((r2 == llcolor4u.mV[VX]) && (g2 == llcolor4u.mV[VY]) && (0 == llcolor4u.mV[VZ])&& (255 == llcolor4u.mV[VW])));
+ ensure("setVecScaleClamp():Fail to add the value ", ((r2 == llcolor4u.mV[VRED]) && (g2 == llcolor4u.mV[VGREEN]) && (0 == llcolor4u.mV[VBLUE])&& (255 == llcolor4u.mV[VALPHA])));
}
}
diff --git a/indra/llmath/tests/v4math_test.cpp b/indra/llmath/tests/v4math_test.cpp
index 07099cd417..236585f13b 100644
--- a/indra/llmath/tests/v4math_test.cpp
+++ b/indra/llmath/tests/v4math_test.cpp
@@ -123,9 +123,9 @@ namespace tut
vec4.abs();
ensure("abs:Fail " ,((x == vec4.mV[VX]) && (-y == vec4.mV[VY]) && (-z == vec4.mV[VZ])&& (-w == vec4.mV[VW])));
vec4.clearVec();
- ensure("isExactlyClear:Fail " ,(TRUE == vec4.isExactlyClear()));
+ ensure("isExactlyClear:Fail " ,(true == vec4.isExactlyClear()));
vec4.zeroVec();
- ensure("isExactlyZero:Fail " ,(TRUE == vec4.isExactlyZero()));
+ ensure("isExactlyZero:Fail " ,(true == vec4.isExactlyZero()));
}
template<> template<>
@@ -303,11 +303,11 @@ namespace tut
{
F32 x = 1.f, y = 2.f, z = -1.1f,epsilon = .23425f;
LLVector4 vec4(x,y,z), vec4a(x,y,z);
- ensure("1:are_parallel: Fail " ,(TRUE == are_parallel(vec4a,vec4,epsilon)));
+ ensure("1:are_parallel: Fail " ,(true == are_parallel(vec4a,vec4,epsilon)));
x = 21.f, y = 12.f, z = -123.1f;
vec4a.clearVec();
vec4a.setVec(x,y,z);
- ensure("2:are_parallel: Fail " ,(FALSE == are_parallel(vec4a,vec4,epsilon)));
+ ensure("2:are_parallel: Fail " ,(false == are_parallel(vec4a,vec4,epsilon)));
}
template<> template<>
diff --git a/indra/llmath/tests/xform_test.cpp b/indra/llmath/tests/xform_test.cpp
index ad56cdb15c..6d6a64ec4c 100644
--- a/indra/llmath/tests/xform_test.cpp
+++ b/indra/llmath/tests/xform_test.cpp
@@ -91,7 +91,7 @@ namespace tut
xform_obj.setPositionZ(z);
ensure("setPositionX/Y/Z failed: ", xform_obj.getPosition() == vec);
- xform_obj.setScaleChildOffset(TRUE);
+ xform_obj.setScaleChildOffset(true);
ensure("setScaleChildOffset failed: ", xform_obj.getScaleChildOffset());
vec.setVec(x, y, z);
@@ -121,7 +121,7 @@ namespace tut
// Is that the expected behavior?
}
- // test cases for inline BOOL setParent(LLXform *parent) and getParent() fn.
+ // test cases for inline bool setParent(LLXform *parent) and getParent() fn.
template<> template<>
void xform_test_object_t::test<3>()
{
@@ -216,7 +216,7 @@ namespace tut
parent.setPosition(llvecpospar);
LLVector3 llvecparentscale(1.0, 2.0, 0);
- parent.setScaleChildOffset(TRUE);
+ parent.setScaleChildOffset(true);
parent.setScale(llvecparentscale);
LLQuaternion quat(1, 2, 3, 4);
diff --git a/indra/llmath/v2math.cpp b/indra/llmath/v2math.cpp
index ecbfe7378c..4649e13376 100644
--- a/indra/llmath/v2math.cpp
+++ b/indra/llmath/v2math.cpp
@@ -42,13 +42,13 @@ LLVector2 LLVector2::zero(0,0);
// Non-member functions
// Sets all values to absolute value of their original values
-// Returns TRUE if data changed
-BOOL LLVector2::abs()
+// Returns true if data changed
+bool LLVector2::abs()
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mV[0] < 0.f) { mV[0] = -mV[0]; ret = TRUE; }
- if (mV[1] < 0.f) { mV[1] = -mV[1]; ret = TRUE; }
+ if (mV[0] < 0.f) { mV[0] = -mV[0]; ret = true; }
+ if (mV[1] < 0.f) { mV[1] = -mV[1]; ret = true; }
return ret;
}
@@ -67,7 +67,7 @@ F32 angle_between(const LLVector2& a, const LLVector2& b)
return angle;
}
-BOOL are_parallel(const LLVector2 &a, const LLVector2 &b, float epsilon)
+bool are_parallel(const LLVector2 &a, const LLVector2 &b, float epsilon)
{
LLVector2 an = a;
LLVector2 bn = b;
@@ -76,9 +76,9 @@ BOOL are_parallel(const LLVector2 &a, const LLVector2 &b, float epsilon)
F32 dot = an * bn;
if ( (1.0f - fabs(dot)) < epsilon)
{
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
diff --git a/indra/llmath/v2math.h b/indra/llmath/v2math.h
index 5c756a7f84..a61c946304 100644
--- a/indra/llmath/v2math.h
+++ b/indra/llmath/v2math.h
@@ -78,12 +78,12 @@ class LLVector2
F32 magVecSquared() const; // deprecated
F32 normVec(); // deprecated
- BOOL abs(); // sets all values to absolute value of original value (first octant), returns TRUE if changed
+ bool abs(); // sets all values to absolute value of original value (first octant), returns true if changed
const LLVector2& scaleVec(const LLVector2& vec); // scales per component by vec
- BOOL isNull(); // Returns TRUE if vector has a _very_small_ length
- BOOL isExactlyZero() const { return !mV[VX] && !mV[VY]; }
+ bool isNull(); // Returns true if vector has a _very_small_ length
+ bool isExactlyZero() const { return !mV[VX] && !mV[VY]; }
F32 operator[](int idx) const { return mV[idx]; }
F32 &operator[](int idx) { return mV[idx]; }
@@ -114,7 +114,7 @@ class LLVector2
// Non-member functions
F32 angle_between(const LLVector2 &a, const LLVector2 &b); // Returns angle (radians) between a and b
-BOOL are_parallel(const LLVector2 &a, const LLVector2 &b, F32 epsilon=F_APPROXIMATELY_ZERO); // Returns TRUE if a and b are very close to parallel
+bool are_parallel(const LLVector2 &a, const LLVector2 &b, F32 epsilon=F_APPROXIMATELY_ZERO); // Returns true if a and b are very close to parallel
F32 dist_vec(const LLVector2 &a, const LLVector2 &b); // Returns distance between a and b
F32 dist_vec_squared(const LLVector2 &a, const LLVector2 &b);// Returns distance squared between a and b
F32 dist_vec_squared2D(const LLVector2 &a, const LLVector2 &b);// Returns distance squared between a and b ignoring Z component
@@ -232,7 +232,7 @@ inline F32 LLVector2::lengthSquared(void) const
return mV[0]*mV[0] + mV[1]*mV[1];
}
-inline F32 LLVector2::normalize(void)
+inline F32 LLVector2::normalize(void)
{
F32 mag = (F32) sqrt(mV[0]*mV[0] + mV[1]*mV[1]);
F32 oomag;
@@ -299,13 +299,13 @@ inline const LLVector2& LLVector2::scaleVec(const LLVector2& vec)
return *this;
}
-inline BOOL LLVector2::isNull()
+inline bool LLVector2::isNull()
{
if ( F_APPROXIMATELY_ZERO > mV[VX]*mV[VX] + mV[VY]*mV[VY] )
{
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
diff --git a/indra/llmath/v3color.cpp b/indra/llmath/v3color.cpp
index 9fe9c8d5e5..4367b993f8 100644
--- a/indra/llmath/v3color.cpp
+++ b/indra/llmath/v3color.cpp
@@ -63,7 +63,7 @@ const LLColor3& LLColor3::operator=(const LLColor4 &a)
std::ostream& operator<<(std::ostream& s, const LLColor3 &a)
{
- s << "{ " << a.mV[VX] << ", " << a.mV[VY] << ", " << a.mV[VZ] << " }";
+ s << "{ " << a.mV[VRED] << ", " << a.mV[VGREEN] << ", " << a.mV[VBLUE] << " }";
return s;
}
diff --git a/indra/llmath/v3color.h b/indra/llmath/v3color.h
index ea26e9eb76..7b92f85a0c 100644
--- a/indra/llmath/v3color.h
+++ b/indra/llmath/v3color.h
@@ -196,17 +196,17 @@ inline LLColor3::LLColor3(void)
inline LLColor3::LLColor3(F32 r, F32 g, F32 b)
{
- mV[VX] = r;
- mV[VY] = g;
- mV[VZ] = b;
+ mV[VRED] = r;
+ mV[VGREEN] = g;
+ mV[VBLUE] = b;
}
inline LLColor3::LLColor3(const F32 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
}
#if LL_WINDOWS
@@ -226,11 +226,11 @@ inline LLColor3::LLColor3(const char* color_string) // takes a string of format
char tempstr[7];
strncpy(tempstr,color_string,6); /* Flawfinder: ignore */
tempstr[6] = '\0';
- mV[VZ] = (F32)strtol(&tempstr[4],NULL,16)/255.f;
+ mV[VBLUE] = (F32)strtol(&tempstr[4],NULL,16)/255.f;
tempstr[4] = '\0';
- mV[VY] = (F32)strtol(&tempstr[2],NULL,16)/255.f;
+ mV[VGREEN] = (F32)strtol(&tempstr[2],NULL,16)/255.f;
tempstr[2] = '\0';
- mV[VX] = (F32)strtol(&tempstr[0],NULL,16)/255.f;
+ mV[VRED] = (F32)strtol(&tempstr[0],NULL,16)/255.f;
}
inline const LLColor3& LLColor3::setToBlack(void)
diff --git a/indra/llmath/v3dmath.cpp b/indra/llmath/v3dmath.cpp
index 6ecd1a00ac..bb55c812b5 100644
--- a/indra/llmath/v3dmath.cpp
+++ b/indra/llmath/v3dmath.cpp
@@ -52,31 +52,31 @@ const LLVector3d LLVector3d::z_axis_neg(0, 0, -1);
// Clamps each values to range (min,max).
-// Returns TRUE if data changed.
-BOOL LLVector3d::clamp(F64 min, F64 max)
+// Returns true if data changed.
+bool LLVector3d::clamp(F64 min, F64 max)
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mdV[0] < min) { mdV[0] = min; ret = TRUE; }
- if (mdV[1] < min) { mdV[1] = min; ret = TRUE; }
- if (mdV[2] < min) { mdV[2] = min; ret = TRUE; }
+ if (mdV[0] < min) { mdV[0] = min; ret = true; }
+ if (mdV[1] < min) { mdV[1] = min; ret = true; }
+ if (mdV[2] < min) { mdV[2] = min; ret = true; }
- if (mdV[0] > max) { mdV[0] = max; ret = TRUE; }
- if (mdV[1] > max) { mdV[1] = max; ret = TRUE; }
- if (mdV[2] > max) { mdV[2] = max; ret = TRUE; }
+ if (mdV[0] > max) { mdV[0] = max; ret = true; }
+ if (mdV[1] > max) { mdV[1] = max; ret = true; }
+ if (mdV[2] > max) { mdV[2] = max; ret = true; }
return ret;
}
// Sets all values to absolute value of their original values
-// Returns TRUE if data changed
-BOOL LLVector3d::abs()
+// Returns true if data changed
+bool LLVector3d::abs()
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mdV[0] < 0.0) { mdV[0] = -mdV[0]; ret = TRUE; }
- if (mdV[1] < 0.0) { mdV[1] = -mdV[1]; ret = TRUE; }
- if (mdV[2] < 0.0) { mdV[2] = -mdV[2]; ret = TRUE; }
+ if (mdV[0] < 0.0) { mdV[0] = -mdV[0]; ret = true; }
+ if (mdV[1] < 0.0) { mdV[1] = -mdV[1]; ret = true; }
+ if (mdV[2] < 0.0) { mdV[2] = -mdV[2]; ret = true; }
return ret;
}
@@ -127,11 +127,11 @@ const LLVector3d& LLVector3d::rotVec(F64 angle, F64 x, F64 y, F64 z)
}
-BOOL LLVector3d::parseVector3d(const std::string& buf, LLVector3d* value)
+bool LLVector3d::parseVector3d(const std::string& buf, LLVector3d* value)
{
- if( buf.empty() || value == NULL)
+ if( buf.empty() || value == nullptr)
{
- return FALSE;
+ return false;
}
LLVector3d v;
@@ -139,9 +139,9 @@ BOOL LLVector3d::parseVector3d(const std::string& buf, LLVector3d* value)
if( 3 == count )
{
value->setVec( v );
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
diff --git a/indra/llmath/v3dmath.h b/indra/llmath/v3dmath.h
index 99c6905e70..ece8c54ea4 100644
--- a/indra/llmath/v3dmath.h
+++ b/indra/llmath/v3dmath.h
@@ -68,9 +68,9 @@ class LLVector3d
return ret;
}
- inline BOOL isFinite() const; // checks to see if all values of LLVector3d are finite
- BOOL clamp(const F64 min, const F64 max); // Clamps all values to (min,max), returns TRUE if data changed
- BOOL abs(); // sets all values to absolute value of original value (first octant), returns TRUE if changed
+ inline bool isFinite() const; // checks to see if all values of LLVector3d are finite
+ bool clamp(const F64 min, const F64 max); // Clamps all values to (min,max), returns true if data changed
+ bool abs(); // sets all values to absolute value of original value (first octant), returns true if changed
inline const LLVector3d& clear(); // Clears LLVector3d to (0, 0, 0, 1)
inline const LLVector3d& clearVec(); // deprecated
@@ -98,8 +98,8 @@ class LLVector3d
const LLVector3d& rotVec(const LLMatrix3 &mat); // Rotates by LLMatrix4 mat
const LLVector3d& rotVec(const LLQuaternion &q); // Rotates by LLQuaternion q
- BOOL isNull() const; // Returns TRUE if vector has a _very_small_ length
- BOOL isExactlyZero() const { return !mdV[VX] && !mdV[VY] && !mdV[VZ]; }
+ bool isNull() const; // Returns true if vector has a _very_small_ length
+ bool isExactlyZero() const { return !mdV[VX] && !mdV[VY] && !mdV[VZ]; }
const LLVector3d& operator=(const LLVector4 &a);
@@ -126,7 +126,7 @@ class LLVector3d
friend std::ostream& operator<<(std::ostream& s, const LLVector3d& a); // Stream a
- static BOOL parseVector3d(const std::string& buf, LLVector3d* value);
+ static bool parseVector3d(const std::string& buf, LLVector3d* value);
};
@@ -189,7 +189,7 @@ inline LLVector3d::LLVector3d(const LLVector3d &copy)
// Destructors
// checker
-inline BOOL LLVector3d::isFinite() const
+inline bool LLVector3d::isFinite() const
{
return (llfinite(mdV[VX]) && llfinite(mdV[VY]) && llfinite(mdV[VZ]));
}
@@ -472,13 +472,13 @@ inline LLVector3d lerp(const LLVector3d& a, const LLVector3d& b, const F64 u)
}
-inline BOOL LLVector3d::isNull() const
+inline bool LLVector3d::isNull() const
{
if ( F_APPROXIMATELY_ZERO > mdV[VX]*mdV[VX] + mdV[VY]*mdV[VY] + mdV[VZ]*mdV[VZ] )
{
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
@@ -495,7 +495,7 @@ inline F64 angle_between(const LLVector3d& a, const LLVector3d& b)
return angle;
}
-inline BOOL are_parallel(const LLVector3d& a, const LLVector3d& b, const F64 epsilon)
+inline bool are_parallel(const LLVector3d& a, const LLVector3d& b, const F64 epsilon)
{
LLVector3d an = a;
LLVector3d bn = b;
@@ -504,10 +504,9 @@ inline BOOL are_parallel(const LLVector3d& a, const LLVector3d& b, const F64 eps
F64 dot = an * bn;
if ( (1.0f - fabs(dot)) < epsilon)
{
- return TRUE;
+ return true;
}
- return FALSE;
-
+ return false;
}
inline LLVector3d projected_vec(const LLVector3d& a, const LLVector3d& b)
diff --git a/indra/llmath/v3math.cpp b/indra/llmath/v3math.cpp
index a867b9f578..73ad2a4ed6 100644
--- a/indra/llmath/v3math.cpp
+++ b/indra/llmath/v3math.cpp
@@ -53,27 +53,27 @@ const LLVector3 LLVector3::all_one(1.f,1.f,1.f);
// Clamps each values to range (min,max).
-// Returns TRUE if data changed.
-BOOL LLVector3::clamp(F32 min, F32 max)
+// Returns true if data changed.
+bool LLVector3::clamp(F32 min, F32 max)
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mV[0] < min) { mV[0] = min; ret = TRUE; }
- if (mV[1] < min) { mV[1] = min; ret = TRUE; }
- if (mV[2] < min) { mV[2] = min; ret = TRUE; }
+ if (mV[0] < min) { mV[0] = min; ret = true; }
+ if (mV[1] < min) { mV[1] = min; ret = true; }
+ if (mV[2] < min) { mV[2] = min; ret = true; }
- if (mV[0] > max) { mV[0] = max; ret = TRUE; }
- if (mV[1] > max) { mV[1] = max; ret = TRUE; }
- if (mV[2] > max) { mV[2] = max; ret = TRUE; }
+ if (mV[0] > max) { mV[0] = max; ret = true; }
+ if (mV[1] > max) { mV[1] = max; ret = true; }
+ if (mV[2] > max) { mV[2] = max; ret = true; }
return ret;
}
// Clamps length to an upper limit.
-// Returns TRUE if the data changed
-BOOL LLVector3::clampLength( F32 length_limit )
+// Returns true if the data changed
+bool LLVector3::clampLength( F32 length_limit )
{
- BOOL changed = FALSE;
+ bool changed{ false };
F32 len = length();
if (llfinite(len))
@@ -88,7 +88,7 @@ BOOL LLVector3::clampLength( F32 length_limit )
mV[0] *= length_limit;
mV[1] *= length_limit;
mV[2] *= length_limit;
- changed = TRUE;
+ changed = true;
}
}
else
@@ -108,7 +108,7 @@ BOOL LLVector3::clampLength( F32 length_limit )
{
// no it can't be salvaged --> clear it
clear();
- changed = TRUE;
+ changed = true;
break;
}
}
@@ -134,31 +134,31 @@ BOOL LLVector3::clampLength( F32 length_limit )
return changed;
}
-BOOL LLVector3::clamp(const LLVector3 &min_vec, const LLVector3 &max_vec)
+bool LLVector3::clamp(const LLVector3 &min_vec, const LLVector3 &max_vec)
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mV[0] < min_vec[0]) { mV[0] = min_vec[0]; ret = TRUE; }
- if (mV[1] < min_vec[1]) { mV[1] = min_vec[1]; ret = TRUE; }
- if (mV[2] < min_vec[2]) { mV[2] = min_vec[2]; ret = TRUE; }
+ if (mV[0] < min_vec[0]) { mV[0] = min_vec[0]; ret = true; }
+ if (mV[1] < min_vec[1]) { mV[1] = min_vec[1]; ret = true; }
+ if (mV[2] < min_vec[2]) { mV[2] = min_vec[2]; ret = true; }
- if (mV[0] > max_vec[0]) { mV[0] = max_vec[0]; ret = TRUE; }
- if (mV[1] > max_vec[1]) { mV[1] = max_vec[1]; ret = TRUE; }
- if (mV[2] > max_vec[2]) { mV[2] = max_vec[2]; ret = TRUE; }
+ if (mV[0] > max_vec[0]) { mV[0] = max_vec[0]; ret = true; }
+ if (mV[1] > max_vec[1]) { mV[1] = max_vec[1]; ret = true; }
+ if (mV[2] > max_vec[2]) { mV[2] = max_vec[2]; ret = true; }
return ret;
}
// Sets all values to absolute value of their original values
-// Returns TRUE if data changed
-BOOL LLVector3::abs()
+// Returns true if data changed
+bool LLVector3::abs()
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mV[0] < 0.f) { mV[0] = -mV[0]; ret = TRUE; }
- if (mV[1] < 0.f) { mV[1] = -mV[1]; ret = TRUE; }
- if (mV[2] < 0.f) { mV[2] = -mV[2]; ret = TRUE; }
+ if (mV[0] < 0.f) { mV[0] = -mV[0]; ret = true; }
+ if (mV[1] < 0.f) { mV[1] = -mV[1]; ret = true; }
+ if (mV[2] < 0.f) { mV[2] = -mV[2]; ret = true; }
return ret;
}
@@ -358,11 +358,11 @@ const LLVector3& operator*=(LLVector3 &a, const LLQuaternion &rot)
}
// static
-BOOL LLVector3::parseVector3(const std::string& buf, LLVector3* value)
+bool LLVector3::parseVector3(const std::string& buf, LLVector3* value)
{
- if( buf.empty() || value == NULL)
+ if( buf.empty() || value == nullptr)
{
- return FALSE;
+ return false;
}
LLVector3 v;
@@ -370,10 +370,10 @@ BOOL LLVector3::parseVector3(const std::string& buf, LLVector3* value)
if( 3 == count )
{
value->setVec( v );
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
// Displacement from query point to nearest neighbor point on bounding box.
diff --git a/indra/llmath/v3math.h b/indra/llmath/v3math.h
index 0f4a4a07ae..d063b15c74 100644
--- a/indra/llmath/v3math.h
+++ b/indra/llmath/v3math.h
@@ -71,16 +71,16 @@ class LLVector3
void setValue(const LLSD& sd);
- inline BOOL isFinite() const; // checks to see if all values of LLVector3 are finite
- BOOL clamp(F32 min, F32 max); // Clamps all values to (min,max), returns TRUE if data changed
- BOOL clamp(const LLVector3 &min_vec, const LLVector3 &max_vec); // Scales vector by another vector
- BOOL clampLength( F32 length_limit ); // Scales vector to limit length to a value
+ inline bool isFinite() const; // checks to see if all values of LLVector3 are finite
+ bool clamp(F32 min, F32 max); // Clamps all values to (min,max), returns true if data changed
+ bool clamp(const LLVector3 &min_vec, const LLVector3 &max_vec); // Scales vector by another vector
+ bool clampLength( F32 length_limit ); // Scales vector to limit length to a value
void quantize16(F32 lowerxy, F32 upperxy, F32 lowerz, F32 upperz); // changes the vector to reflect quatization
void quantize8(F32 lowerxy, F32 upperxy, F32 lowerz, F32 upperz); // changes the vector to reflect quatization
void snap(S32 sig_digits); // snaps x,y,z to sig_digits decimal places
- BOOL abs(); // sets all values to absolute value of original value (first octant), returns TRUE if changed
+ bool abs(); // sets all values to absolute value of original value (first octant), returns true if changed
inline void clear(); // Clears LLVector3 to (0, 0, 0)
inline void setZero(); // Clears LLVector3 to (0, 0, 0)
@@ -108,7 +108,7 @@ class LLVector3
inline F32 normalize(); // Normalizes and returns the magnitude of LLVector3
inline F32 normVec(); // deprecated
- inline BOOL inRange( F32 min, F32 max ) const; // Returns true if all values of the vector are between min and max
+ inline bool inRange( F32 min, F32 max ) const; // Returns true if all values of the vector are between min and max
const LLVector3& rotVec(F32 angle, const LLVector3 &vec); // Rotates about vec by angle radians
const LLVector3& rotVec(F32 angle, F32 x, F32 y, F32 z); // Rotates about x,y,z by angle radians
@@ -119,8 +119,8 @@ class LLVector3
const LLVector3& scaleVec(const LLVector3& vec); // scales per component by vec
LLVector3 scaledVec(const LLVector3& vec) const; // get a copy of this vector scaled by vec
- BOOL isNull() const; // Returns TRUE if vector has a _very_small_ length
- BOOL isExactlyZero() const { return !mV[VX] && !mV[VY] && !mV[VZ]; }
+ bool isNull() const; // Returns true if vector has a _very_small_ length
+ bool isExactlyZero() const { return !mV[VX] && !mV[VY] && !mV[VZ]; }
F32 operator[](int idx) const { return mV[idx]; }
F32 &operator[](int idx) { return mV[idx]; }
@@ -149,7 +149,7 @@ class LLVector3
friend std::ostream& operator<<(std::ostream& s, const LLVector3 &a); // Stream a
- static BOOL parseVector3(const std::string& buf, LLVector3* value);
+ static bool parseVector3(const std::string& buf, LLVector3* value);
};
typedef LLVector3 LLSimLocalVec;
@@ -157,7 +157,7 @@ typedef LLVector3 LLSimLocalVec;
// Non-member functions
F32 angle_between(const LLVector3 &a, const LLVector3 &b); // Returns angle (radians) between a and b
-BOOL are_parallel(const LLVector3 &a, const LLVector3 &b, F32 epsilon=F_APPROXIMATELY_ZERO); // Returns TRUE if a and b are very close to parallel
+bool are_parallel(const LLVector3 &a, const LLVector3 &b, F32 epsilon=F_APPROXIMATELY_ZERO); // Returns true if a and b are very close to parallel
F32 dist_vec(const LLVector3 &a, const LLVector3 &b); // Returns distance between a and b
F32 dist_vec_squared(const LLVector3 &a, const LLVector3 &b);// Returns distance squared between a and b
F32 dist_vec_squared2D(const LLVector3 &a, const LLVector3 &b);// Returns distance squared between a and b ignoring Z component
@@ -202,7 +202,7 @@ inline LLVector3::LLVector3(const LLVector3 &copy)
// Destructors
// checker
-inline BOOL LLVector3::isFinite() const
+inline bool LLVector3::isFinite() const
{
return (llfinite(mV[VX]) && llfinite(mV[VY]) && llfinite(mV[VZ]));
}
@@ -350,7 +350,7 @@ inline F32 LLVector3::magVecSquared(void) const
return mV[0]*mV[0] + mV[1]*mV[1] + mV[2]*mV[2];
}
-inline BOOL LLVector3::inRange( F32 min, F32 max ) const
+inline bool LLVector3::inRange( F32 min, F32 max ) const
{
return mV[0] >= min && mV[0] <= max &&
mV[1] >= min && mV[1] <= max &&
@@ -539,13 +539,13 @@ inline LLVector3 lerp(const LLVector3 &a, const LLVector3 &b, F32 u)
}
-inline BOOL LLVector3::isNull() const
+inline bool LLVector3::isNull() const
{
if ( F_APPROXIMATELY_ZERO > mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ] )
{
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
inline void update_min_max(LLVector3& min, LLVector3& max, const LLVector3& pos)
@@ -589,7 +589,7 @@ inline F32 angle_between(const LLVector3& a, const LLVector3& b)
return atan2f(sqrtf(c * c), ab); // return the angle
}
-inline BOOL are_parallel(const LLVector3 &a, const LLVector3 &b, F32 epsilon)
+inline bool are_parallel(const LLVector3 &a, const LLVector3 &b, F32 epsilon)
{
LLVector3 an = a;
LLVector3 bn = b;
@@ -598,9 +598,9 @@ inline BOOL are_parallel(const LLVector3 &a, const LLVector3 &b, F32 epsilon)
F32 dot = an * bn;
if ( (1.0f - fabs(dot)) < epsilon)
{
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
inline std::ostream& operator<<(std::ostream& s, const LLVector3 &a)
diff --git a/indra/llmath/v4color.cpp b/indra/llmath/v4color.cpp
index 497281c27e..ad13656bbd 100644
--- a/indra/llmath/v4color.cpp
+++ b/indra/llmath/v4color.cpp
@@ -133,57 +133,57 @@ LLColor4::operator LLColor4U() const
LLColor4::LLColor4(const LLColor3 &vec, F32 a)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = a;
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = a;
}
LLColor4::LLColor4(const LLColor4U& color4u)
{
const F32 SCALE = 1.f/255.f;
- mV[VX] = color4u.mV[VX] * SCALE;
- mV[VY] = color4u.mV[VY] * SCALE;
- mV[VZ] = color4u.mV[VZ] * SCALE;
- mV[VW] = color4u.mV[VW] * SCALE;
+ mV[VRED] = color4u.mV[VRED] * SCALE;
+ mV[VGREEN] = color4u.mV[VGREEN] * SCALE;
+ mV[VBLUE] = color4u.mV[VBLUE] * SCALE;
+ mV[VALPHA] = color4u.mV[VALPHA] * SCALE;
}
LLColor4::LLColor4(const LLVector4& vector4)
{
- mV[VX] = vector4.mV[VX];
- mV[VY] = vector4.mV[VY];
- mV[VZ] = vector4.mV[VZ];
- mV[VW] = vector4.mV[VW];
+ mV[VRED] = vector4.mV[VRED];
+ mV[VGREEN] = vector4.mV[VGREEN];
+ mV[VBLUE] = vector4.mV[VBLUE];
+ mV[VALPHA] = vector4.mV[VALPHA];
}
const LLColor4& LLColor4::set(const LLColor4U& color4u)
{
const F32 SCALE = 1.f/255.f;
- mV[VX] = color4u.mV[VX] * SCALE;
- mV[VY] = color4u.mV[VY] * SCALE;
- mV[VZ] = color4u.mV[VZ] * SCALE;
- mV[VW] = color4u.mV[VW] * SCALE;
+ mV[VRED] = color4u.mV[VRED] * SCALE;
+ mV[VGREEN] = color4u.mV[VGREEN] * SCALE;
+ mV[VBLUE] = color4u.mV[VBLUE] * SCALE;
+ mV[VALPHA] = color4u.mV[VALPHA] * SCALE;
return (*this);
}
const LLColor4& LLColor4::set(const LLColor3 &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
// no change to alpha!
-// mV[VW] = 1.f;
+// mV[VALPHA] = 1.f;
return (*this);
}
const LLColor4& LLColor4::set(const LLColor3 &vec, F32 a)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = a;
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = a;
return (*this);
}
@@ -191,22 +191,22 @@ const LLColor4& LLColor4::set(const LLColor3 &vec, F32 a)
const LLColor4& LLColor4::setVec(const LLColor4U& color4u)
{
const F32 SCALE = 1.f/255.f;
- mV[VX] = color4u.mV[VX] * SCALE;
- mV[VY] = color4u.mV[VY] * SCALE;
- mV[VZ] = color4u.mV[VZ] * SCALE;
- mV[VW] = color4u.mV[VW] * SCALE;
+ mV[VRED] = color4u.mV[VRED] * SCALE;
+ mV[VGREEN] = color4u.mV[VGREEN] * SCALE;
+ mV[VBLUE] = color4u.mV[VBLUE] * SCALE;
+ mV[VALPHA] = color4u.mV[VALPHA] * SCALE;
return (*this);
}
// deprecated -- use set()
const LLColor4& LLColor4::setVec(const LLColor3 &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
// no change to alpha!
-// mV[VW] = 1.f;
+// mV[VALPHA] = 1.f;
return (*this);
}
@@ -214,10 +214,10 @@ const LLColor4& LLColor4::setVec(const LLColor3 &vec)
// deprecated -- use set()
const LLColor4& LLColor4::setVec(const LLColor3 &vec, F32 a)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = a;
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = a;
return (*this);
}
@@ -257,45 +257,45 @@ void LLColor4::setValue(const LLSD& sd)
const LLColor4& LLColor4::operator=(const LLColor3 &a)
{
- mV[VX] = a.mV[VX];
- mV[VY] = a.mV[VY];
- mV[VZ] = a.mV[VZ];
+ mV[VRED] = a.mV[VRED];
+ mV[VGREEN] = a.mV[VGREEN];
+ mV[VBLUE] = a.mV[VBLUE];
// converting from an rgb sets a=1 (opaque)
- mV[VW] = 1.f;
+ mV[VALPHA] = 1.f;
return (*this);
}
std::ostream& operator<<(std::ostream& s, const LLColor4 &a)
{
- s << "{ " << a.mV[VX] << ", " << a.mV[VY] << ", " << a.mV[VZ] << ", " << a.mV[VW] << " }";
+ s << "{ " << a.mV[VRED] << ", " << a.mV[VGREEN] << ", " << a.mV[VBLUE] << ", " << a.mV[VALPHA] << " }";
return s;
}
bool operator==(const LLColor4 &a, const LLColor3 &b)
{
- return ( (a.mV[VX] == b.mV[VX])
- &&(a.mV[VY] == b.mV[VY])
- &&(a.mV[VZ] == b.mV[VZ]));
+ return ( (a.mV[VRED] == b.mV[VRED])
+ &&(a.mV[VGREEN] == b.mV[VGREEN])
+ &&(a.mV[VBLUE] == b.mV[VBLUE]));
}
bool operator!=(const LLColor4 &a, const LLColor3 &b)
{
- return ( (a.mV[VX] != b.mV[VX])
- ||(a.mV[VY] != b.mV[VY])
- ||(a.mV[VZ] != b.mV[VZ]));
+ return ( (a.mV[VRED] != b.mV[VRED])
+ ||(a.mV[VGREEN] != b.mV[VGREEN])
+ ||(a.mV[VBLUE] != b.mV[VBLUE]));
}
LLColor3 vec4to3(const LLColor4 &vec)
{
- LLColor3 temp(vec.mV[VX], vec.mV[VY], vec.mV[VZ]);
+ LLColor3 temp(vec.mV[VRED], vec.mV[VGREEN], vec.mV[VBLUE]);
return temp;
}
LLColor4 vec3to4(const LLColor3 &vec)
{
- LLColor3 temp(vec.mV[VX], vec.mV[VY], vec.mV[VZ]);
+ LLColor3 temp(vec.mV[VRED], vec.mV[VGREEN], vec.mV[VBLUE]);
return temp;
}
@@ -385,18 +385,18 @@ void LLColor4::calcHSL(F32* hue, F32* saturation, F32* luminance) const
}
// static
-BOOL LLColor4::parseColor(const std::string& buf, LLColor4* color)
+bool LLColor4::parseColor(const std::string& buf, LLColor4* color)
{
- if( buf.empty() || color == NULL)
+ if( buf.empty() || color == nullptr)
{
- return FALSE;
+ return false;
}
boost_tokenizer tokens(buf, boost::char_separator<char>(", "));
boost_tokenizer::iterator token_iter = tokens.begin();
if (token_iter == tokens.end())
{
- return FALSE;
+ return false;
}
// Grab the first token into a string, since we don't know
@@ -408,10 +408,10 @@ BOOL LLColor4::parseColor(const std::string& buf, LLColor4* color)
{
// There are more tokens to read. This must be a vector.
LLColor4 v;
- LLStringUtil::convertToF32( color_name, v.mV[VX] );
- LLStringUtil::convertToF32( *token_iter, v.mV[VY] );
- v.mV[VZ] = 0.0f;
- v.mV[VW] = 1.0f;
+ LLStringUtil::convertToF32( color_name, v.mV[VRED] );
+ LLStringUtil::convertToF32( *token_iter, v.mV[VGREEN] );
+ v.mV[VBLUE] = 0.0f;
+ v.mV[VALPHA] = 1.0f;
++token_iter;
if (token_iter == tokens.end())
@@ -422,18 +422,18 @@ BOOL LLColor4::parseColor(const std::string& buf, LLColor4* color)
else
{
// There is a z-component.
- LLStringUtil::convertToF32( *token_iter, v.mV[VZ] );
+ LLStringUtil::convertToF32( *token_iter, v.mV[VBLUE] );
++token_iter;
if (token_iter != tokens.end())
{
// There is an alpha component.
- LLStringUtil::convertToF32( *token_iter, v.mV[VW] );
+ LLStringUtil::convertToF32( *token_iter, v.mV[VALPHA] );
}
}
// Make sure all values are between 0 and 1.
- if (v.mV[VX] > 1.f || v.mV[VY] > 1.f || v.mV[VZ] > 1.f || v.mV[VW] > 1.f)
+ if (v.mV[VRED] > 1.f || v.mV[VGREEN] > 1.f || v.mV[VBLUE] > 1.f || v.mV[VALPHA] > 1.f)
{
v = v * (1.f / 255.f);
}
@@ -708,15 +708,15 @@ BOOL LLColor4::parseColor(const std::string& buf, LLColor4* color)
}
}
- return TRUE;
+ return true;
}
// static
-BOOL LLColor4::parseColor4(const std::string& buf, LLColor4* value)
+bool LLColor4::parseColor4(const std::string& buf, LLColor4* value)
{
- if( buf.empty() || value == NULL)
+ if( buf.empty() || value == nullptr)
{
- return FALSE;
+ return false;
}
LLColor4 v;
@@ -729,10 +729,10 @@ BOOL LLColor4::parseColor4(const std::string& buf, LLColor4* value)
if( 4 == count )
{
value->setVec( v );
- return TRUE;
+ return true;
}
- return FALSE;
+ return false;
}
// EOF
diff --git a/indra/llmath/v4color.h b/indra/llmath/v4color.h
index 3168c8b43a..e9bb6a07ba 100644
--- a/indra/llmath/v4color.h
+++ b/indra/llmath/v4color.h
@@ -111,7 +111,7 @@ class LLColor4
F32 lengthSquared() const; // Returns magnitude squared of LLColor4
F32 normalize(); // deprecated -- use normalize()
- BOOL isOpaque() { return mV[VALPHA] == 1.f; }
+ bool isOpaque() { return mV[VALPHA] == 1.f; }
F32 operator[](int idx) const { return mV[idx]; }
F32 &operator[](int idx) { return mV[idx]; }
@@ -226,8 +226,8 @@ class LLColor4
static LLColor4 cyan5;
static LLColor4 cyan6;
- static BOOL parseColor(const std::string& buf, LLColor4* color);
- static BOOL parseColor4(const std::string& buf, LLColor4* color);
+ static bool parseColor(const std::string& buf, LLColor4* color);
+ static bool parseColor4(const std::string& buf, LLColor4* color);
inline void clamp();
};
@@ -242,10 +242,10 @@ LLColor4 lerp(const LLColor4 &a, const LLColor4 &b, F32 u);
inline LLColor4::LLColor4(void)
{
- mV[VX] = 0.f;
- mV[VY] = 0.f;
- mV[VZ] = 0.f;
- mV[VW] = 1.f;
+ mV[VRED] = 0.f;
+ mV[VGREEN] = 0.f;
+ mV[VBLUE] = 0.f;
+ mV[VALPHA] = 1.f;
}
inline LLColor4::LLColor4(const LLSD& sd)
@@ -255,113 +255,113 @@ inline LLColor4::LLColor4(const LLSD& sd)
inline LLColor4::LLColor4(F32 r, F32 g, F32 b)
{
- mV[VX] = r;
- mV[VY] = g;
- mV[VZ] = b;
- mV[VW] = 1.f;
+ mV[VRED] = r;
+ mV[VGREEN] = g;
+ mV[VBLUE] = b;
+ mV[VALPHA] = 1.f;
}
inline LLColor4::LLColor4(F32 r, F32 g, F32 b, F32 a)
{
- mV[VX] = r;
- mV[VY] = g;
- mV[VZ] = b;
- mV[VW] = a;
+ mV[VRED] = r;
+ mV[VGREEN] = g;
+ mV[VBLUE] = b;
+ mV[VALPHA] = a;
}
inline LLColor4::LLColor4(U32 clr)
{
- mV[VX] = (clr&0xff) * (1.0f/255.0f);
- mV[VY] = ((clr>>8)&0xff) * (1.0f/255.0f);
- mV[VZ] = ((clr>>16)&0xff) * (1.0f/255.0f);
- mV[VW] = (clr>>24) * (1.0f/255.0f);
+ mV[VRED] = (clr&0xff) * (1.0f/255.0f);
+ mV[VGREEN] = ((clr>>8)&0xff) * (1.0f/255.0f);
+ mV[VBLUE] = ((clr>>16)&0xff) * (1.0f/255.0f);
+ mV[VALPHA] = (clr>>24) * (1.0f/255.0f);
}
inline LLColor4::LLColor4(const F32 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
- mV[VW] = vec[VW];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
+ mV[VALPHA] = vec[VALPHA];
}
inline const LLColor4& LLColor4::setToBlack(void)
{
- mV[VX] = 0.f;
- mV[VY] = 0.f;
- mV[VZ] = 0.f;
- mV[VW] = 1.f;
+ mV[VRED] = 0.f;
+ mV[VGREEN] = 0.f;
+ mV[VBLUE] = 0.f;
+ mV[VALPHA] = 1.f;
return (*this);
}
inline const LLColor4& LLColor4::setToWhite(void)
{
- mV[VX] = 1.f;
- mV[VY] = 1.f;
- mV[VZ] = 1.f;
- mV[VW] = 1.f;
+ mV[VRED] = 1.f;
+ mV[VGREEN] = 1.f;
+ mV[VBLUE] = 1.f;
+ mV[VALPHA] = 1.f;
return (*this);
}
inline const LLColor4& LLColor4::set(F32 x, F32 y, F32 z)
{
- mV[VX] = x;
- mV[VY] = y;
- mV[VZ] = z;
+ mV[VRED] = x;
+ mV[VGREEN] = y;
+ mV[VBLUE] = z;
// no change to alpha!
-// mV[VW] = 1.f;
+// mV[VALPHA] = 1.f;
return (*this);
}
inline const LLColor4& LLColor4::set(F32 x, F32 y, F32 z, F32 a)
{
- mV[VX] = x;
- mV[VY] = y;
- mV[VZ] = z;
- mV[VW] = a;
+ mV[VRED] = x;
+ mV[VGREEN] = y;
+ mV[VBLUE] = z;
+ mV[VALPHA] = a;
return (*this);
}
inline const LLColor4& LLColor4::set(const LLColor4 &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = vec.mV[VW];
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = vec.mV[VALPHA];
return (*this);
}
inline const LLColor4& LLColor4::set(const F32 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
- mV[VW] = vec[VW];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
+ mV[VALPHA] = vec[VALPHA];
return (*this);
}
inline const LLColor4& LLColor4::set(const F64 *vec)
{
- mV[VX] = static_cast<F32>(vec[VX]);
- mV[VY] = static_cast<F32>(vec[VY]);
- mV[VZ] = static_cast<F32>(vec[VZ]);
- mV[VW] = static_cast<F32>(vec[VW]);
+ mV[VRED] = static_cast<F32>(vec[VRED]);
+ mV[VGREEN] = static_cast<F32>(vec[VGREEN]);
+ mV[VBLUE] = static_cast<F32>(vec[VBLUE]);
+ mV[VALPHA] = static_cast<F32>(vec[VALPHA]);
return (*this);
}
// deprecated
inline const LLColor4& LLColor4::setVec(F32 x, F32 y, F32 z)
{
- mV[VX] = x;
- mV[VY] = y;
- mV[VZ] = z;
+ mV[VRED] = x;
+ mV[VGREEN] = y;
+ mV[VBLUE] = z;
// no change to alpha!
-// mV[VW] = 1.f;
+// mV[VALPHA] = 1.f;
return (*this);
}
@@ -369,20 +369,20 @@ inline const LLColor4& LLColor4::setVec(F32 x, F32 y, F32 z)
// deprecated
inline const LLColor4& LLColor4::setVec(F32 x, F32 y, F32 z, F32 a)
{
- mV[VX] = x;
- mV[VY] = y;
- mV[VZ] = z;
- mV[VW] = a;
+ mV[VRED] = x;
+ mV[VGREEN] = y;
+ mV[VBLUE] = z;
+ mV[VALPHA] = a;
return (*this);
}
// deprecated
inline const LLColor4& LLColor4::setVec(const LLColor4 &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = vec.mV[VW];
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = vec.mV[VALPHA];
return (*this);
}
@@ -390,16 +390,16 @@ inline const LLColor4& LLColor4::setVec(const LLColor4 &vec)
// deprecated
inline const LLColor4& LLColor4::setVec(const F32 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
- mV[VW] = vec[VW];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
+ mV[VALPHA] = vec[VALPHA];
return (*this);
}
inline const LLColor4& LLColor4::setAlpha(F32 a)
{
- mV[VW] = a;
+ mV[VALPHA] = a;
return (*this);
}
@@ -407,25 +407,25 @@ inline const LLColor4& LLColor4::setAlpha(F32 a)
inline F32 LLColor4::length(void) const
{
- return (F32) sqrt(mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ]);
+ return (F32) sqrt(mV[VRED]*mV[VRED] + mV[VGREEN]*mV[VGREEN] + mV[VBLUE]*mV[VBLUE]);
}
inline F32 LLColor4::lengthSquared(void) const
{
- return mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ];
+ return mV[VRED]*mV[VRED] + mV[VGREEN]*mV[VGREEN] + mV[VBLUE]*mV[VBLUE];
}
inline F32 LLColor4::normalize(void)
{
- F32 mag = (F32) sqrt(mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ]);
+ F32 mag = (F32) sqrt(mV[VRED]*mV[VRED] + mV[VGREEN]*mV[VGREEN] + mV[VBLUE]*mV[VBLUE]);
F32 oomag;
if (mag)
{
oomag = 1.f/mag;
- mV[VX] *= oomag;
- mV[VY] *= oomag;
- mV[VZ] *= oomag;
+ mV[VRED] *= oomag;
+ mV[VGREEN] *= oomag;
+ mV[VBLUE] *= oomag;
}
return (mag);
}
@@ -433,27 +433,27 @@ inline F32 LLColor4::normalize(void)
// deprecated
inline F32 LLColor4::magVec(void) const
{
- return (F32) sqrt(mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ]);
+ return (F32) sqrt(mV[VRED]*mV[VRED] + mV[VGREEN]*mV[VGREEN] + mV[VBLUE]*mV[VBLUE]);
}
// deprecated
inline F32 LLColor4::magVecSquared(void) const
{
- return mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ];
+ return mV[VRED]*mV[VRED] + mV[VGREEN]*mV[VGREEN] + mV[VBLUE]*mV[VBLUE];
}
// deprecated
inline F32 LLColor4::normVec(void)
{
- F32 mag = (F32) sqrt(mV[VX]*mV[VX] + mV[VY]*mV[VY] + mV[VZ]*mV[VZ]);
+ F32 mag = (F32) sqrt(mV[VRED]*mV[VRED] + mV[VGREEN]*mV[VGREEN] + mV[VBLUE]*mV[VBLUE]);
F32 oomag;
if (mag)
{
oomag = 1.f/mag;
- mV[VX] *= oomag;
- mV[VY] *= oomag;
- mV[VZ] *= oomag;
+ mV[VRED] *= oomag;
+ mV[VGREEN] *= oomag;
+ mV[VBLUE] *= oomag;
}
return (mag);
}
@@ -464,135 +464,135 @@ inline F32 LLColor4::normVec(void)
inline LLColor4 operator+(const LLColor4 &a, const LLColor4 &b)
{
return LLColor4(
- a.mV[VX] + b.mV[VX],
- a.mV[VY] + b.mV[VY],
- a.mV[VZ] + b.mV[VZ],
- a.mV[VW] + b.mV[VW]);
+ a.mV[VRED] + b.mV[VRED],
+ a.mV[VGREEN] + b.mV[VGREEN],
+ a.mV[VBLUE] + b.mV[VBLUE],
+ a.mV[VALPHA] + b.mV[VALPHA]);
}
inline LLColor4 operator-(const LLColor4 &a, const LLColor4 &b)
{
return LLColor4(
- a.mV[VX] - b.mV[VX],
- a.mV[VY] - b.mV[VY],
- a.mV[VZ] - b.mV[VZ],
- a.mV[VW] - b.mV[VW]);
+ a.mV[VRED] - b.mV[VRED],
+ a.mV[VGREEN] - b.mV[VGREEN],
+ a.mV[VBLUE] - b.mV[VBLUE],
+ a.mV[VALPHA] - b.mV[VALPHA]);
}
inline LLColor4 operator*(const LLColor4 &a, const LLColor4 &b)
{
return LLColor4(
- a.mV[VX] * b.mV[VX],
- a.mV[VY] * b.mV[VY],
- a.mV[VZ] * b.mV[VZ],
- a.mV[VW] * b.mV[VW]);
+ a.mV[VRED] * b.mV[VRED],
+ a.mV[VGREEN] * b.mV[VGREEN],
+ a.mV[VBLUE] * b.mV[VBLUE],
+ a.mV[VALPHA] * b.mV[VALPHA]);
}
inline LLColor4 operator*(const LLColor4 &a, F32 k)
{
// only affects rgb (not a!)
return LLColor4(
- a.mV[VX] * k,
- a.mV[VY] * k,
- a.mV[VZ] * k,
- a.mV[VW]);
+ a.mV[VRED] * k,
+ a.mV[VGREEN] * k,
+ a.mV[VBLUE] * k,
+ a.mV[VALPHA]);
}
inline LLColor4 operator/(const LLColor4 &a, F32 k)
{
return LLColor4(
- a.mV[VX] / k,
- a.mV[VY] / k,
- a.mV[VZ] / k,
- a.mV[VW]);
+ a.mV[VRED] / k,
+ a.mV[VGREEN] / k,
+ a.mV[VBLUE] / k,
+ a.mV[VALPHA]);
}
inline LLColor4 operator*(F32 k, const LLColor4 &a)
{
// only affects rgb (not a!)
return LLColor4(
- a.mV[VX] * k,
- a.mV[VY] * k,
- a.mV[VZ] * k,
- a.mV[VW]);
+ a.mV[VRED] * k,
+ a.mV[VGREEN] * k,
+ a.mV[VBLUE] * k,
+ a.mV[VALPHA]);
}
inline LLColor4 operator%(F32 k, const LLColor4 &a)
{
// only affects alpha (not rgb!)
return LLColor4(
- a.mV[VX],
- a.mV[VY],
- a.mV[VZ],
- a.mV[VW] * k);
+ a.mV[VRED],
+ a.mV[VGREEN],
+ a.mV[VBLUE],
+ a.mV[VALPHA] * k);
}
inline LLColor4 operator%(const LLColor4 &a, F32 k)
{
// only affects alpha (not rgb!)
return LLColor4(
- a.mV[VX],
- a.mV[VY],
- a.mV[VZ],
- a.mV[VW] * k);
+ a.mV[VRED],
+ a.mV[VGREEN],
+ a.mV[VBLUE],
+ a.mV[VALPHA] * k);
}
inline bool operator==(const LLColor4 &a, const LLColor4 &b)
{
- return ( (a.mV[VX] == b.mV[VX])
- &&(a.mV[VY] == b.mV[VY])
- &&(a.mV[VZ] == b.mV[VZ])
- &&(a.mV[VW] == b.mV[VW]));
+ return ( (a.mV[VRED] == b.mV[VRED])
+ &&(a.mV[VGREEN] == b.mV[VGREEN])
+ &&(a.mV[VBLUE] == b.mV[VBLUE])
+ &&(a.mV[VALPHA] == b.mV[VALPHA]));
}
inline bool operator!=(const LLColor4 &a, const LLColor4 &b)
{
- return ( (a.mV[VX] != b.mV[VX])
- ||(a.mV[VY] != b.mV[VY])
- ||(a.mV[VZ] != b.mV[VZ])
- ||(a.mV[VW] != b.mV[VW]));
+ return ( (a.mV[VRED] != b.mV[VRED])
+ ||(a.mV[VGREEN] != b.mV[VGREEN])
+ ||(a.mV[VBLUE] != b.mV[VBLUE])
+ ||(a.mV[VALPHA] != b.mV[VALPHA]));
}
inline const LLColor4& operator+=(LLColor4 &a, const LLColor4 &b)
{
- a.mV[VX] += b.mV[VX];
- a.mV[VY] += b.mV[VY];
- a.mV[VZ] += b.mV[VZ];
- a.mV[VW] += b.mV[VW];
+ a.mV[VRED] += b.mV[VRED];
+ a.mV[VGREEN] += b.mV[VGREEN];
+ a.mV[VBLUE] += b.mV[VBLUE];
+ a.mV[VALPHA] += b.mV[VALPHA];
return a;
}
inline const LLColor4& operator-=(LLColor4 &a, const LLColor4 &b)
{
- a.mV[VX] -= b.mV[VX];
- a.mV[VY] -= b.mV[VY];
- a.mV[VZ] -= b.mV[VZ];
- a.mV[VW] -= b.mV[VW];
+ a.mV[VRED] -= b.mV[VRED];
+ a.mV[VGREEN] -= b.mV[VGREEN];
+ a.mV[VBLUE] -= b.mV[VBLUE];
+ a.mV[VALPHA] -= b.mV[VALPHA];
return a;
}
inline const LLColor4& operator*=(LLColor4 &a, F32 k)
{
// only affects rgb (not a!)
- a.mV[VX] *= k;
- a.mV[VY] *= k;
- a.mV[VZ] *= k;
+ a.mV[VRED] *= k;
+ a.mV[VGREEN] *= k;
+ a.mV[VBLUE] *= k;
return a;
}
inline const LLColor4& operator *=(LLColor4 &a, const LLColor4 &b)
{
- a.mV[VX] *= b.mV[VX];
- a.mV[VY] *= b.mV[VY];
- a.mV[VZ] *= b.mV[VZ];
-// a.mV[VW] *= b.mV[VW];
+ a.mV[VRED] *= b.mV[VRED];
+ a.mV[VGREEN] *= b.mV[VGREEN];
+ a.mV[VBLUE] *= b.mV[VBLUE];
+// a.mV[VALPHA] *= b.mV[VALPHA];
return a;
}
inline const LLColor4& operator%=(LLColor4 &a, F32 k)
{
// only affects alpha (not rgb!)
- a.mV[VW] *= k;
+ a.mV[VALPHA] *= k;
return a;
}
@@ -614,10 +614,10 @@ inline F32 distVec_squared(const LLColor4 &a, const LLColor4 &b)
inline LLColor4 lerp(const LLColor4 &a, const LLColor4 &b, F32 u)
{
return LLColor4(
- a.mV[VX] + (b.mV[VX] - a.mV[VX]) * u,
- a.mV[VY] + (b.mV[VY] - a.mV[VY]) * u,
- a.mV[VZ] + (b.mV[VZ] - a.mV[VZ]) * u,
- a.mV[VW] + (b.mV[VW] - a.mV[VW]) * u);
+ a.mV[VRED] + (b.mV[VRED] - a.mV[VRED]) * u,
+ a.mV[VGREEN] + (b.mV[VGREEN] - a.mV[VGREEN]) * u,
+ a.mV[VBLUE] + (b.mV[VBLUE] - a.mV[VBLUE]) * u,
+ a.mV[VALPHA] + (b.mV[VALPHA] - a.mV[VALPHA]) * u);
}
inline bool LLColor4::operator<(const LLColor4& rhs) const
diff --git a/indra/llmath/v4coloru.cpp b/indra/llmath/v4coloru.cpp
index 92127933b2..acf349245a 100644
--- a/indra/llmath/v4coloru.cpp
+++ b/indra/llmath/v4coloru.cpp
@@ -53,10 +53,10 @@ LLColor4U::operator LLColor4()
/*
LLColor4U::LLColor4U(const LLColor3 &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = 255;
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = 255;
}
*/
@@ -70,12 +70,12 @@ LLColor4U::LLColor4U(const LLColor3 &vec)
/*
LLColor4U LLColor4U::operator=(const LLColor3 &a)
{
- mV[VX] = a.mV[VX];
- mV[VY] = a.mV[VY];
- mV[VZ] = a.mV[VZ];
+ mV[VRED] = a.mV[VRED];
+ mV[VGREEN] = a.mV[VGREEN];
+ mV[VBLUE] = a.mV[VBLUE];
// converting from an rgb sets a=1 (opaque)
- mV[VW] = 255;
+ mV[VALPHA] = 255;
return (*this);
}
*/
@@ -83,16 +83,16 @@ LLColor4U LLColor4U::operator=(const LLColor3 &a)
std::ostream& operator<<(std::ostream& s, const LLColor4U &a)
{
- s << "{ " << (S32)a.mV[VX] << ", " << (S32)a.mV[VY] << ", " << (S32)a.mV[VZ] << ", " << (S32)a.mV[VW] << " }";
+ s << "{ " << (S32)a.mV[VRED] << ", " << (S32)a.mV[VGREEN] << ", " << (S32)a.mV[VBLUE] << ", " << (S32)a.mV[VALPHA] << " }";
return s;
}
// static
-BOOL LLColor4U::parseColor4U(const std::string& buf, LLColor4U* value)
+bool LLColor4U::parseColor4U(const std::string& buf, LLColor4U* value)
{
- if( buf.empty() || value == NULL)
+ if( buf.empty() || value == nullptr)
{
- return FALSE;
+ return false;
}
U32 v[4];
@@ -104,17 +104,17 @@ BOOL LLColor4U::parseColor4U(const std::string& buf, LLColor4U* value)
}
if( 4 != count )
{
- return FALSE;
+ return false;
}
for( S32 i = 0; i < 4; i++ )
{
if( v[i] > U8_MAX )
{
- return FALSE;
+ return false;
}
}
value->set( U8(v[0]), U8(v[1]), U8(v[2]), U8(v[3]) );
- return TRUE;
+ return true;
}
diff --git a/indra/llmath/v4coloru.h b/indra/llmath/v4coloru.h
index ecfecc167f..29128a08a7 100644
--- a/indra/llmath/v4coloru.h
+++ b/indra/llmath/v4coloru.h
@@ -112,12 +112,11 @@ public:
LLColor4U addClampMax(const LLColor4U &color); // Add and clamp the max
LLColor4U multAll(const F32 k); // Multiply ALL channels by scalar k
- const LLColor4U& combine();
inline void setVecScaleClamp(const LLColor3 &color);
inline void setVecScaleClamp(const LLColor4 &color);
- static BOOL parseColor4U(const std::string& buf, LLColor4U* value);
+ static bool parseColor4U(const std::string& buf, LLColor4U* value);
// conversion
operator LLColor4() const
@@ -143,34 +142,34 @@ F32 distVec_squared(const LLColor4U &a, const LLColor4U &b); // Returns d
inline LLColor4U::LLColor4U()
{
- mV[VX] = 0;
- mV[VY] = 0;
- mV[VZ] = 0;
- mV[VW] = 255;
+ mV[VRED] = 0;
+ mV[VGREEN] = 0;
+ mV[VBLUE] = 0;
+ mV[VALPHA] = 255;
}
inline LLColor4U::LLColor4U(U8 r, U8 g, U8 b)
{
- mV[VX] = r;
- mV[VY] = g;
- mV[VZ] = b;
- mV[VW] = 255;
+ mV[VRED] = r;
+ mV[VGREEN] = g;
+ mV[VBLUE] = b;
+ mV[VALPHA] = 255;
}
inline LLColor4U::LLColor4U(U8 r, U8 g, U8 b, U8 a)
{
- mV[VX] = r;
- mV[VY] = g;
- mV[VZ] = b;
- mV[VW] = a;
+ mV[VRED] = r;
+ mV[VGREEN] = g;
+ mV[VBLUE] = b;
+ mV[VALPHA] = a;
}
inline LLColor4U::LLColor4U(const U8 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
- mV[VW] = vec[VW];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
+ mV[VALPHA] = vec[VALPHA];
}
/*
@@ -182,30 +181,30 @@ inline LLColor4U::operator LLColor4()
inline const LLColor4U& LLColor4U::setToBlack(void)
{
- mV[VX] = 0;
- mV[VY] = 0;
- mV[VZ] = 0;
- mV[VW] = 255;
+ mV[VRED] = 0;
+ mV[VGREEN] = 0;
+ mV[VBLUE] = 0;
+ mV[VALPHA] = 255;
return (*this);
}
inline const LLColor4U& LLColor4U::setToWhite(void)
{
- mV[VX] = 255;
- mV[VY] = 255;
- mV[VZ] = 255;
- mV[VW] = 255;
+ mV[VRED] = 255;
+ mV[VGREEN] = 255;
+ mV[VBLUE] = 255;
+ mV[VALPHA] = 255;
return (*this);
}
inline const LLColor4U& LLColor4U::set(const U8 x, const U8 y, const U8 z)
{
- mV[VX] = x;
- mV[VY] = y;
- mV[VZ] = z;
+ mV[VRED] = x;
+ mV[VGREEN] = y;
+ mV[VBLUE] = z;
// no change to alpha!
-// mV[VW] = 255;
+// mV[VALPHA] = 255;
return (*this);
}
@@ -221,31 +220,31 @@ inline const LLColor4U& LLColor4U::set(const U8 r, const U8 g, const U8 b, U8 a)
inline const LLColor4U& LLColor4U::set(const LLColor4U &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = vec.mV[VW];
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = vec.mV[VALPHA];
return (*this);
}
inline const LLColor4U& LLColor4U::set(const U8 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
- mV[VW] = vec[VW];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
+ mV[VALPHA] = vec[VALPHA];
return (*this);
}
// deprecated
inline const LLColor4U& LLColor4U::setVec(const U8 x, const U8 y, const U8 z)
{
- mV[VX] = x;
- mV[VY] = y;
- mV[VZ] = z;
+ mV[VRED] = x;
+ mV[VGREEN] = y;
+ mV[VBLUE] = z;
// no change to alpha!
-// mV[VW] = 255;
+// mV[VALPHA] = 255;
return (*this);
}
@@ -263,26 +262,26 @@ inline const LLColor4U& LLColor4U::setVec(const U8 r, const U8 g, const U8 b, U8
// deprecated
inline const LLColor4U& LLColor4U::setVec(const LLColor4U &vec)
{
- mV[VX] = vec.mV[VX];
- mV[VY] = vec.mV[VY];
- mV[VZ] = vec.mV[VZ];
- mV[VW] = vec.mV[VW];
+ mV[VRED] = vec.mV[VRED];
+ mV[VGREEN] = vec.mV[VGREEN];
+ mV[VBLUE] = vec.mV[VBLUE];
+ mV[VALPHA] = vec.mV[VALPHA];
return (*this);
}
// deprecated
inline const LLColor4U& LLColor4U::setVec(const U8 *vec)
{
- mV[VX] = vec[VX];
- mV[VY] = vec[VY];
- mV[VZ] = vec[VZ];
- mV[VW] = vec[VW];
+ mV[VRED] = vec[VRED];
+ mV[VGREEN] = vec[VGREEN];
+ mV[VBLUE] = vec[VBLUE];
+ mV[VALPHA] = vec[VALPHA];
return (*this);
}
inline const LLColor4U& LLColor4U::setAlpha(U8 a)
{
- mV[VW] = a;
+ mV[VALPHA] = a;
return (*this);
}
@@ -290,159 +289,159 @@ inline const LLColor4U& LLColor4U::setAlpha(U8 a)
inline F32 LLColor4U::length(void) const
{
- return (F32) sqrt( ((F32)mV[VX]) * mV[VX] + ((F32)mV[VY]) * mV[VY] + ((F32)mV[VZ]) * mV[VZ] );
+ return (F32) sqrt( ((F32)mV[VRED]) * mV[VRED] + ((F32)mV[VGREEN]) * mV[VGREEN] + ((F32)mV[VBLUE]) * mV[VBLUE] );
}
inline F32 LLColor4U::lengthSquared(void) const
{
- return ((F32)mV[VX]) * mV[VX] + ((F32)mV[VY]) * mV[VY] + ((F32)mV[VZ]) * mV[VZ];
+ return ((F32)mV[VRED]) * mV[VRED] + ((F32)mV[VGREEN]) * mV[VGREEN] + ((F32)mV[VBLUE]) * mV[VBLUE];
}
// deprecated
inline F32 LLColor4U::magVec(void) const
{
- return (F32) sqrt( ((F32)mV[VX]) * mV[VX] + ((F32)mV[VY]) * mV[VY] + ((F32)mV[VZ]) * mV[VZ] );
+ return (F32) sqrt( ((F32)mV[VRED]) * mV[VRED] + ((F32)mV[VGREEN]) * mV[VGREEN] + ((F32)mV[VBLUE]) * mV[VBLUE] );
}
// deprecated
inline F32 LLColor4U::magVecSquared(void) const
{
- return ((F32)mV[VX]) * mV[VX] + ((F32)mV[VY]) * mV[VY] + ((F32)mV[VZ]) * mV[VZ];
+ return ((F32)mV[VRED]) * mV[VRED] + ((F32)mV[VGREEN]) * mV[VGREEN] + ((F32)mV[VBLUE]) * mV[VBLUE];
}
inline LLColor4U operator+(const LLColor4U &a, const LLColor4U &b)
{
return LLColor4U(
- a.mV[VX] + b.mV[VX],
- a.mV[VY] + b.mV[VY],
- a.mV[VZ] + b.mV[VZ],
- a.mV[VW] + b.mV[VW]);
+ a.mV[VRED] + b.mV[VRED],
+ a.mV[VGREEN] + b.mV[VGREEN],
+ a.mV[VBLUE] + b.mV[VBLUE],
+ a.mV[VALPHA] + b.mV[VALPHA]);
}
inline LLColor4U operator-(const LLColor4U &a, const LLColor4U &b)
{
return LLColor4U(
- a.mV[VX] - b.mV[VX],
- a.mV[VY] - b.mV[VY],
- a.mV[VZ] - b.mV[VZ],
- a.mV[VW] - b.mV[VW]);
+ a.mV[VRED] - b.mV[VRED],
+ a.mV[VGREEN] - b.mV[VGREEN],
+ a.mV[VBLUE] - b.mV[VBLUE],
+ a.mV[VALPHA] - b.mV[VALPHA]);
}
inline LLColor4U operator*(const LLColor4U &a, const LLColor4U &b)
{
return LLColor4U(
- a.mV[VX] * b.mV[VX],
- a.mV[VY] * b.mV[VY],
- a.mV[VZ] * b.mV[VZ],
- a.mV[VW] * b.mV[VW]);
+ a.mV[VRED] * b.mV[VRED],
+ a.mV[VGREEN] * b.mV[VGREEN],
+ a.mV[VBLUE] * b.mV[VBLUE],
+ a.mV[VALPHA] * b.mV[VALPHA]);
}
inline LLColor4U LLColor4U::addClampMax(const LLColor4U &color)
{
- return LLColor4U(llmin((S32)mV[VX] + color.mV[VX], 255),
- llmin((S32)mV[VY] + color.mV[VY], 255),
- llmin((S32)mV[VZ] + color.mV[VZ], 255),
- llmin((S32)mV[VW] + color.mV[VW], 255));
+ return LLColor4U(llmin((S32)mV[VRED] + color.mV[VRED], 255),
+ llmin((S32)mV[VGREEN] + color.mV[VGREEN], 255),
+ llmin((S32)mV[VBLUE] + color.mV[VBLUE], 255),
+ llmin((S32)mV[VALPHA] + color.mV[VALPHA], 255));
}
inline LLColor4U LLColor4U::multAll(const F32 k)
{
// Round to nearest
return LLColor4U(
- (U8)ll_round(mV[VX] * k),
- (U8)ll_round(mV[VY] * k),
- (U8)ll_round(mV[VZ] * k),
- (U8)ll_round(mV[VW] * k));
+ (U8)ll_round(mV[VRED] * k),
+ (U8)ll_round(mV[VGREEN] * k),
+ (U8)ll_round(mV[VBLUE] * k),
+ (U8)ll_round(mV[VALPHA] * k));
}
/*
inline LLColor4U operator*(const LLColor4U &a, U8 k)
{
// only affects rgb (not a!)
return LLColor4U(
- a.mV[VX] * k,
- a.mV[VY] * k,
- a.mV[VZ] * k,
- a.mV[VW]);
+ a.mV[VRED] * k,
+ a.mV[VGREEN] * k,
+ a.mV[VBLUE] * k,
+ a.mV[VALPHA]);
}
inline LLColor4U operator*(U8 k, const LLColor4U &a)
{
// only affects rgb (not a!)
return LLColor4U(
- a.mV[VX] * k,
- a.mV[VY] * k,
- a.mV[VZ] * k,
- a.mV[VW]);
+ a.mV[VRED] * k,
+ a.mV[VGREEN] * k,
+ a.mV[VBLUE] * k,
+ a.mV[VALPHA]);
}
inline LLColor4U operator%(U8 k, const LLColor4U &a)
{
// only affects alpha (not rgb!)
return LLColor4U(
- a.mV[VX],
- a.mV[VY],
- a.mV[VZ],
- a.mV[VW] * k );
+ a.mV[VRED],
+ a.mV[VGREEN],
+ a.mV[VBLUE],
+ a.mV[VALPHA] * k );
}
inline LLColor4U operator%(const LLColor4U &a, U8 k)
{
// only affects alpha (not rgb!)
return LLColor4U(
- a.mV[VX],
- a.mV[VY],
- a.mV[VZ],
- a.mV[VW] * k );
+ a.mV[VRED],
+ a.mV[VGREEN],
+ a.mV[VBLUE],
+ a.mV[VALPHA] * k );
}
*/
inline bool operator==(const LLColor4U &a, const LLColor4U &b)
{
- return ( (a.mV[VX] == b.mV[VX])
- &&(a.mV[VY] == b.mV[VY])
- &&(a.mV[VZ] == b.mV[VZ])
- &&(a.mV[VW] == b.mV[VW]));
+ return ( (a.mV[VRED] == b.mV[VRED])
+ &&(a.mV[VGREEN] == b.mV[VGREEN])
+ &&(a.mV[VBLUE] == b.mV[VBLUE])
+ &&(a.mV[VALPHA] == b.mV[VALPHA]));
}
inline bool operator!=(const LLColor4U &a, const LLColor4U &b)
{
- return ( (a.mV[VX] != b.mV[VX])
- ||(a.mV[VY] != b.mV[VY])
- ||(a.mV[VZ] != b.mV[VZ])
- ||(a.mV[VW] != b.mV[VW]));
+ return ( (a.mV[VRED] != b.mV[VRED])
+ ||(a.mV[VGREEN] != b.mV[VGREEN])
+ ||(a.mV[VBLUE] != b.mV[VBLUE])
+ ||(a.mV[VALPHA] != b.mV[VALPHA]));
}
inline const LLColor4U& operator+=(LLColor4U &a, const LLColor4U &b)
{
- a.mV[VX] += b.mV[VX];
- a.mV[VY] += b.mV[VY];
- a.mV[VZ] += b.mV[VZ];
- a.mV[VW] += b.mV[VW];
+ a.mV[VRED] += b.mV[VRED];
+ a.mV[VGREEN] += b.mV[VGREEN];
+ a.mV[VBLUE] += b.mV[VBLUE];
+ a.mV[VALPHA] += b.mV[VALPHA];
return a;
}
inline const LLColor4U& operator-=(LLColor4U &a, const LLColor4U &b)
{
- a.mV[VX] -= b.mV[VX];
- a.mV[VY] -= b.mV[VY];
- a.mV[VZ] -= b.mV[VZ];
- a.mV[VW] -= b.mV[VW];
+ a.mV[VRED] -= b.mV[VRED];
+ a.mV[VGREEN] -= b.mV[VGREEN];
+ a.mV[VBLUE] -= b.mV[VBLUE];
+ a.mV[VALPHA] -= b.mV[VALPHA];
return a;
}
inline const LLColor4U& operator*=(LLColor4U &a, U8 k)
{
// only affects rgb (not a!)
- a.mV[VX] *= k;
- a.mV[VY] *= k;
- a.mV[VZ] *= k;
+ a.mV[VRED] *= k;
+ a.mV[VGREEN] *= k;
+ a.mV[VBLUE] *= k;
return a;
}
inline const LLColor4U& operator%=(LLColor4U &a, U8 k)
{
// only affects alpha (not rgb!)
- a.mV[VW] *= k;
+ a.mV[VALPHA] *= k;
return a;
}
diff --git a/indra/llmath/v4math.cpp b/indra/llmath/v4math.cpp
index 8955145527..0aa6eb09c3 100644
--- a/indra/llmath/v4math.cpp
+++ b/indra/llmath/v4math.cpp
@@ -36,28 +36,6 @@
// LLVector4
// Axis-Angle rotations
-
-/*
-const LLVector4& LLVector4::rotVec(F32 angle, const LLVector4 &vec)
-{
- if ( !vec.isExactlyZero() && angle )
- {
- *this = *this * LLMatrix4(angle, vec);
- }
- return *this;
-}
-
-const LLVector4& LLVector4::rotVec(F32 angle, F32 x, F32 y, F32 z)
-{
- LLVector3 vec(x, y, z);
- if ( !vec.isExactlyZero() && angle )
- {
- *this = *this * LLMatrix4(angle, vec);
- }
- return *this;
-}
-*/
-
const LLVector4& LLVector4::rotVec(const LLMatrix4 &mat)
{
*this = *this * mat;
@@ -81,15 +59,15 @@ const LLVector4& LLVector4::scaleVec(const LLVector4& vec)
}
// Sets all values to absolute value of their original values
-// Returns TRUE if data changed
-BOOL LLVector4::abs()
+// Returns true if data changed
+bool LLVector4::abs()
{
- BOOL ret = FALSE;
+ bool ret{ false };
- if (mV[0] < 0.f) { mV[0] = -mV[0]; ret = TRUE; }
- if (mV[1] < 0.f) { mV[1] = -mV[1]; ret = TRUE; }
- if (mV[2] < 0.f) { mV[2] = -mV[2]; ret = TRUE; }
- if (mV[3] < 0.f) { mV[3] = -mV[3]; ret = TRUE; }
+ if (mV[0] < 0.f) { mV[0] = -mV[0]; ret = true; }
+ if (mV[1] < 0.f) { mV[1] = -mV[1]; ret = true; }
+ if (mV[2] < 0.f) { mV[2] = -mV[2]; ret = true; }
+ if (mV[3] < 0.f) { mV[3] = -mV[3]; ret = true; }
return ret;
}
@@ -117,7 +95,7 @@ F32 angle_between( const LLVector4& a, const LLVector4& b )
return angle;
}
-BOOL are_parallel(const LLVector4 &a, const LLVector4 &b, F32 epsilon)
+bool are_parallel(const LLVector4 &a, const LLVector4 &b, F32 epsilon)
{
LLVector4 an = a;
LLVector4 bn = b;
@@ -125,8 +103,8 @@ BOOL are_parallel(const LLVector4 &a, const LLVector4 &b, F32 epsilon)
bn.normalize();
F32 dot = an * bn;
if ( (1.0f - fabs(dot)) < epsilon)
- return TRUE;
- return FALSE;
+ return true;
+ return false;
}
diff --git a/indra/llmath/v4math.h b/indra/llmath/v4math.h
index 7f0020af6b..7ed22212d3 100644
--- a/indra/llmath/v4math.h
+++ b/indra/llmath/v4math.h
@@ -74,7 +74,7 @@ class LLVector4
}
- inline BOOL isFinite() const; // checks to see if all values of LLVector3 are finite
+ inline bool isFinite() const; // checks to see if all values of LLVector3 are finite
inline void clear(); // Clears LLVector4 to (0, 0, 0, 1)
inline void clearVec(); // deprecated
@@ -101,14 +101,12 @@ class LLVector4
F32 normVec(); // deprecated
// Sets all values to absolute value of their original values
- // Returns TRUE if data changed
- BOOL abs();
+ // Returns true if data changed
+ bool abs();
- BOOL isExactlyClear() const { return (mV[VW] == 1.0f) && !mV[VX] && !mV[VY] && !mV[VZ]; }
- BOOL isExactlyZero() const { return !mV[VW] && !mV[VX] && !mV[VY] && !mV[VZ]; }
+ bool isExactlyClear() const { return (mV[VW] == 1.0f) && !mV[VX] && !mV[VY] && !mV[VZ]; }
+ bool isExactlyZero() const { return !mV[VW] && !mV[VX] && !mV[VY] && !mV[VZ]; }
- const LLVector4& rotVec(F32 angle, const LLVector4 &vec); // Rotates about vec by angle radians
- const LLVector4& rotVec(F32 angle, F32 x, F32 y, F32 z); // Rotates about x,y,z by angle radians
const LLVector4& rotVec(const LLMatrix4 &mat); // Rotates by MAT4 mat
const LLVector4& rotVec(const LLQuaternion &q); // Rotates by QUAT q
@@ -139,7 +137,7 @@ class LLVector4
// Non-member functions
F32 angle_between(const LLVector4 &a, const LLVector4 &b); // Returns angle (radians) between a and b
-BOOL are_parallel(const LLVector4 &a, const LLVector4 &b, F32 epsilon=F_APPROXIMATELY_ZERO); // Returns TRUE if a and b are very close to parallel
+bool are_parallel(const LLVector4 &a, const LLVector4 &b, F32 epsilon = F_APPROXIMATELY_ZERO); // Returns true if a and b are very close to parallel
F32 dist_vec(const LLVector4 &a, const LLVector4 &b); // Returns distance between a and b
F32 dist_vec_squared(const LLVector4 &a, const LLVector4 &b); // Returns distance squared between a and b
LLVector3 vec4to3(const LLVector4 &vec);
@@ -226,7 +224,7 @@ inline LLVector4::LLVector4(const LLSD &sd)
}
-inline BOOL LLVector4::isFinite() const
+inline bool LLVector4::isFinite() const
{
return (llfinite(mV[VX]) && llfinite(mV[VY]) && llfinite(mV[VZ]) && llfinite(mV[VW]));
}
diff --git a/indra/llmath/xform.cpp b/indra/llmath/xform.cpp
index 6edad9664f..39bbb94c9f 100644
--- a/indra/llmath/xform.cpp
+++ b/indra/llmath/xform.cpp
@@ -52,12 +52,12 @@ LLXform* LLXform::getRoot() const
return (LLXform*)root;
}
-BOOL LLXform::isRoot() const
+bool LLXform::isRoot() const
{
return (!mParent);
}
-BOOL LLXform::isRootEdit() const
+bool LLXform::isRootEdit() const
{
return (!mParent);
}
@@ -86,7 +86,7 @@ void LLXformMatrix::update()
}
}
-void LLXformMatrix::updateMatrix(BOOL update_bounds)
+void LLXformMatrix::updateMatrix(bool update_bounds)
{
update();
diff --git a/indra/llmath/xform.h b/indra/llmath/xform.h
index 06ca526f4f..7434301670 100644
--- a/indra/llmath/xform.h
+++ b/indra/llmath/xform.h
@@ -30,12 +30,12 @@
#include "m4math.h"
#include "llquaternion.h"
-const F32 MAX_OBJECT_Z = 4096.f; // should match REGION_HEIGHT_METERS, Pre-havok4: 768.f
-const F32 MIN_OBJECT_Z = -256.f;
-const F32 DEFAULT_MAX_PRIM_SCALE = 64.f;
-const F32 DEFAULT_MAX_PRIM_SCALE_NO_MESH = 10.f;
-const F32 MIN_PRIM_SCALE = 0.01f;
-const F32 MAX_PRIM_SCALE = 65536.f; // something very high but not near FLT_MAX
+constexpr F32 MAX_OBJECT_Z = 4096.f; // should match REGION_HEIGHT_METERS, Pre-havok4: 768.f
+constexpr F32 MIN_OBJECT_Z = -256.f;
+constexpr F32 DEFAULT_MAX_PRIM_SCALE = 64.f;
+constexpr F32 DEFAULT_MAX_PRIM_SCALE_NO_MESH = 10.f;
+constexpr F32 MIN_PRIM_SCALE = 0.01f;
+constexpr F32 MAX_PRIM_SCALE = 65536.f; // something very high but not near FLT_MAX
class LLXform
{
@@ -52,7 +52,7 @@ protected:
LLXform* mParent;
U32 mChanged;
- BOOL mScaleChildOffset;
+ bool mScaleChildOffset;
public:
typedef enum e_changed_flags
@@ -78,7 +78,7 @@ public:
mScale. setVec(1,1,1);
mWorldPosition.clearVec();
mWorldRotation.loadIdentity();
- mScaleChildOffset = FALSE;
+ mScaleChildOffset = false;
}
LLXform();
@@ -86,7 +86,7 @@ public:
void getLocalMat4(LLMatrix4 &mat) const { mat.initAll(mScale, mRotation, mPosition); }
- inline BOOL setParent(LLXform *parent);
+ inline bool setParent(LLXform *parent);
inline void setPosition(const LLVector3& pos);
inline void setPosition(const F32 x, const F32 y, const F32 z);
@@ -109,18 +109,18 @@ public:
void warn(const char* const msg);
void setChanged(const U32 bits) { mChanged |= bits; }
- BOOL isChanged() const { return mChanged; }
- BOOL isChanged(const U32 bits) const { return mChanged & bits; }
+ bool isChanged() const { return mChanged; }
+ bool isChanged(const U32 bits) const { return mChanged & bits; }
void clearChanged() { mChanged = 0; }
void clearChanged(U32 bits) { mChanged &= ~bits; }
- void setScaleChildOffset(BOOL scale) { mScaleChildOffset = scale; }
- BOOL getScaleChildOffset() { return mScaleChildOffset; }
+ void setScaleChildOffset(bool scale) { mScaleChildOffset = scale; }
+ bool getScaleChildOffset() { return mScaleChildOffset; }
LLXform* getParent() const { return mParent; }
LLXform* getRoot() const;
- virtual BOOL isRoot() const;
- virtual BOOL isRootEdit() const;
+ virtual bool isRoot() const;
+ virtual bool isRootEdit() const;
const LLVector3& getPosition() const { return mPosition; }
const LLVector3& getScale() const { return mScale; }
@@ -149,7 +149,7 @@ public:
}
void update();
- void updateMatrix(BOOL update_bounds = TRUE);
+ void updateMatrix(bool update_bounds = true);
void getMinMax(LLVector3& min,LLVector3& max) const;
protected:
@@ -159,12 +159,12 @@ protected:
};
-BOOL LLXform::setParent(LLXform* parent)
+bool LLXform::setParent(LLXform* parent)
{
// Validate and make sure we're not creating a loop
if (parent == mParent)
{
- return TRUE;
+ return true;
}
if (parent)
{
@@ -174,13 +174,13 @@ BOOL LLXform::setParent(LLXform* parent)
if (cur_par == this)
{
//warn("LLXform::setParent Creating loop when setting parent!");
- return FALSE;
+ return false;
}
cur_par = cur_par->mParent;
}
}
mParent = parent;
- return TRUE;
+ return true;
}
void LLXform::setPosition(const LLVector3& pos)