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/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef GFX_MATRIX_H
#define GFX_MATRIX_H
#include "gfxPoint.h"
#include "gfxTypes.h"
#include "gfxRect.h"
#include "mozilla/Attributes.h"
#include "mozilla/gfx/MatrixFwd.h"
// XX - I don't think this class should use gfxFloat at all,
// but should use 'double' and be called gfxDoubleMatrix;
// we can then typedef that to gfxMatrix where we typedef
// double to be gfxFloat.
/**
* A matrix that represents an affine transformation. Projective
* transformations are not supported. This matrix looks like:
*
* / a b 0 \
* | c d 0 |
* \ tx ty 1 /
*
* So, transforming a point (x, y) results in:
*
* / a b 0 \ / a * x + c * y + tx \ T
* (x y 1) * | c d 0 | = | b * x + d * y + ty |
* \ tx ty 1 / \ 1 /
*
*/
class gfxMatrix {
public:
double _11; double _12;
double _21; double _22;
double _31; double _32;
/**
* Initializes this matrix as the identity matrix.
*/
gfxMatrix() { Reset(); }
/**
* Initializes the matrix from individual components. See the class
* description for the layout of the matrix.
*/
gfxMatrix(gfxFloat a, gfxFloat b, gfxFloat c, gfxFloat d, gfxFloat tx, gfxFloat ty) :
_11(a), _12(b),
_21(c), _22(d),
_31(tx), _32(ty) { }
MOZ_ALWAYS_INLINE gfxMatrix Copy() const {
return gfxMatrix(*this);
}
friend std::ostream& operator<<(std::ostream& stream, const gfxMatrix& m) {
if (m.IsIdentity()) {
return stream << "[identity]";
}
return stream << "["
<< m._11 << " " << m._12
<< m._21 << " " << m._22
<< m._31 << " " << m._32
<< "]";
}
/**
* Post-multiplies m onto the matrix.
*/
const gfxMatrix& operator *= (const gfxMatrix& m);
/**
* Multiplies *this with m and returns the result.
*/
gfxMatrix operator * (const gfxMatrix& m) const {
return gfxMatrix(*this) *= m;
}
/**
* Multiplies *this with aMatrix and returns the result.
*/
mozilla::gfx::Matrix4x4 operator * (const mozilla::gfx::Matrix4x4& aMatrix) const;
/* Returns true if the other matrix is fuzzy-equal to this matrix.
* Note that this isn't a cheap comparison!
*/
bool operator==(const gfxMatrix& other) const
{
return FuzzyEqual(_11, other._11) && FuzzyEqual(_12, other._12) &&
FuzzyEqual(_21, other._21) && FuzzyEqual(_22, other._22) &&
FuzzyEqual(_31, other._31) && FuzzyEqual(_32, other._32);
}
bool operator!=(const gfxMatrix& other) const
{
return !(*this == other);
}
// matrix operations
/**
* Resets this matrix to the identity matrix.
*/
const gfxMatrix& Reset();
bool IsIdentity() const {
return _11 == 1.0 && _12 == 0.0 &&
_21 == 0.0 && _22 == 1.0 &&
_31 == 0.0 && _32 == 0.0;
}
/* Returns true if the matrix is a rectilinear transformation (i.e.
* grid-aligned rectangles are transformed to grid-aligned rectangles)
*/
bool IsRectilinear() const {
if (FuzzyEqual(_12, 0) && FuzzyEqual(_21, 0)) {
return true;
} else if (FuzzyEqual(_22, 0) && FuzzyEqual(_11, 0)) {
return true;
}
return false;
}
/**
* Inverts this matrix, if possible. Otherwise, the matrix is left
* unchanged.
*
* XXX should this do something with the return value of
* cairo_matrix_invert?
*/
bool Invert();
/**
* Check if matrix is singular (no inverse exists).
*/
bool IsSingular() const {
// if the determinant (ad - bc) is zero it's singular
return (_11 * _22) == (_12 * _21);
}
/**
* Scales this matrix. The scale is pre-multiplied onto this matrix,
* i.e. the scaling takes place before the other transformations.
*/
gfxMatrix& Scale(gfxFloat x, gfxFloat y);
/**
* Translates this matrix. The translation is pre-multiplied onto this matrix,
* i.e. the translation takes place before the other transformations.
*/
gfxMatrix& Translate(const gfxPoint& pt);
gfxMatrix& Translate(gfxFloat x, gfxFloat y) {
return Translate(gfxPoint(x, y));
}
/**
* Rotates this matrix. The rotation is pre-multiplied onto this matrix,
* i.e. the translation takes place after the other transformations.
*
* @param radians Angle in radians.
*/
gfxMatrix& Rotate(gfxFloat radians);
/**
* Multiplies the current matrix with m.
* This is a pre-multiplication, i.e. the transformations of m are
* applied _before_ the existing transformations.
*/
gfxMatrix& PreMultiply(const gfxMatrix& m);
static gfxMatrix Translation(gfxFloat aX, gfxFloat aY)
{
return gfxMatrix(1.0, 0.0, 0.0, 1.0, aX, aY);
}
static gfxMatrix Translation(gfxPoint aPoint)
{
return Translation(aPoint.x, aPoint.y);
}
static gfxMatrix Rotation(gfxFloat aAngle);
static gfxMatrix Scaling(gfxFloat aX, gfxFloat aY)
{
return gfxMatrix(aX, 0.0, 0.0, aY, 0.0, 0.0);
}
/**
* Transforms a point according to this matrix.
*/
gfxPoint Transform(const gfxPoint& point) const;
/**
* Transform a distance according to this matrix. This does not apply
* any translation components.
*/
gfxSize Transform(const gfxSize& size) const;
/**
* Transforms both the point and distance according to this matrix.
*/
gfxRect Transform(const gfxRect& rect) const;
gfxRect TransformBounds(const gfxRect& rect) const;
/**
* Returns the translation component of this matrix.
*/
gfxPoint GetTranslation() const {
return gfxPoint(_31, _32);
}
/**
* Returns true if the matrix is anything other than a straight
* translation by integers.
*/
bool HasNonIntegerTranslation() const {
return HasNonTranslation() ||
!FuzzyEqual(_31, floor(_31 + 0.5)) ||
!FuzzyEqual(_32, floor(_32 + 0.5));
}
/**
* Returns true if the matrix has any transform other
* than a straight translation
*/
bool HasNonTranslation() const {
return !FuzzyEqual(_11, 1.0) || !FuzzyEqual(_22, 1.0) ||
!FuzzyEqual(_21, 0.0) || !FuzzyEqual(_12, 0.0);
}
/**
* Returns true if the matrix only has an integer translation.
*/
bool HasOnlyIntegerTranslation() const {
return !HasNonIntegerTranslation();
}
/**
* Returns true if the matrix has any transform other
* than a translation or a -1 y scale (y axis flip)
*/
bool HasNonTranslationOrFlip() const {
return !FuzzyEqual(_11, 1.0) ||
(!FuzzyEqual(_22, 1.0) && !FuzzyEqual(_22, -1.0)) ||
!FuzzyEqual(_21, 0.0) || !FuzzyEqual(_12, 0.0);
}
/**
* Returns true if the matrix has any transform other
* than a translation or scale; this is, if there is
* no rotation.
*/
bool HasNonAxisAlignedTransform() const {
return !FuzzyEqual(_21, 0.0) || !FuzzyEqual(_12, 0.0);
}
/**
* Computes the determinant of this matrix.
*/
double Determinant() const {
return _11*_22 - _12*_21;
}
/* Computes the scale factors of this matrix; that is,
* the amounts each basis vector is scaled by.
* The xMajor parameter indicates if the larger scale is
* to be assumed to be in the X direction or not.
*/
gfxSize ScaleFactors(bool xMajor) const {
double det = Determinant();
if (det == 0.0)
return gfxSize(0.0, 0.0);
gfxSize sz = xMajor ? gfxSize(1.0, 0.0) : gfxSize(0.0, 1.0);
sz = Transform(sz);
double major = sqrt(sz.width * sz.width + sz.height * sz.height);
double minor = 0.0;
// ignore mirroring
if (det < 0.0)
det = - det;
if (major)
minor = det / major;
if (xMajor)
return gfxSize(major, minor);
return gfxSize(minor, major);
}
/**
* Snap matrix components that are close to integers
* to integers. In particular, components that are integral when
* converted to single precision are set to those integers.
*/
gfxMatrix& NudgeToIntegers(void);
/**
* Returns true if matrix is multiple of 90 degrees rotation with flipping,
* scaling and translation.
*/
bool PreservesAxisAlignedRectangles() const {
return ((FuzzyEqual(_11, 0.0) && FuzzyEqual(_22, 0.0))
|| (FuzzyEqual(_21, 0.0) && FuzzyEqual(_12, 0.0)));
}
private:
static bool FuzzyEqual(gfxFloat aV1, gfxFloat aV2) {
return fabs(aV2 - aV1) < 1e-6;
}
};
#endif /* GFX_MATRIX_H */
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