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/*
* Copyright 2015 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrQuad_DEFINED
#define GrQuad_DEFINED
#include "SkMatrix.h"
#include "SkNx.h"
#include "SkPoint.h"
#include "SkPoint3.h"
#include "SkTArray.h"
enum class GrAAType : unsigned;
enum class GrQuadAAFlags;
// Rectangles transformed by matrices (view or local) can be classified in three ways:
// 1. Stays a rectangle - the matrix rectStaysRect() is true, or x(0) == x(1) && x(2) == x(3)
// and y(0) == y(2) && y(1) == y(3). Or under mirrors, x(0) == x(2) && x(1) == x(3) and
// y(0) == y(1) && y(2) == y(3).
// 2. Is rectilinear - the matrix does not have skew or perspective, but may rotate (unlike #1)
// 3. Is a quadrilateral - the matrix does not have perspective, but may rotate or skew, or
// ws() == all ones.
// 4. Is a perspective quad - the matrix has perspective, subsuming all previous quad types.
enum class GrQuadType {
kRect,
kRectilinear,
kStandard,
kPerspective,
kLast = kPerspective
};
static const int kGrQuadTypeCount = static_cast<int>(GrQuadType::kLast) + 1;
// If an SkRect is transformed by this matrix, what class of quad is required to represent it. Since
// quadType() is only provided on Gr[Persp]Quad in debug builds, production code should use this
// to efficiently determine quad types.
GrQuadType GrQuadTypeForTransformedRect(const SkMatrix& matrix);
// Resolve disagreements between the overall requested AA type and the per-edge quad AA flags.
// knownQuadType must have come from GrQuadTypeForTransformedRect with the matrix that created the
// provided quad. Both outAAType and outEdgeFlags will be updated.
template <typename Q>
void GrResolveAATypeForQuad(GrAAType requestedAAType, GrQuadAAFlags requestedEdgeFlags,
const Q& quad, GrQuadType knownQuadType,
GrAAType* outAAtype, GrQuadAAFlags* outEdgeFlags);
/**
* GrQuad is a collection of 4 points which can be used to represent an arbitrary quadrilateral. The
* points make a triangle strip with CCW triangles (top-left, bottom-left, top-right, bottom-right).
*/
class GrQuad {
public:
GrQuad() = default;
GrQuad(const GrQuad& that) = default;
explicit GrQuad(const SkRect& rect)
: fX{rect.fLeft, rect.fLeft, rect.fRight, rect.fRight}
, fY{rect.fTop, rect.fBottom, rect.fTop, rect.fBottom} {}
GrQuad(const Sk4f& xs, const Sk4f& ys) {
xs.store(fX);
ys.store(fY);
}
explicit GrQuad(const SkPoint pts[4])
: fX{pts[0].fX, pts[1].fX, pts[2].fX, pts[3].fX}
, fY{pts[0].fY, pts[1].fY, pts[2].fY, pts[3].fY} {}
/** Sets the quad to the rect as transformed by the matrix. */
static GrQuad MakeFromRect(const SkRect&, const SkMatrix&);
// Creates a GrQuad from the quadrilateral 'pts', transformed by the matrix. Unlike the explicit
// constructor, the input points array is arranged as per SkRect::toQuad (top-left, top-right,
// bottom-right, bottom-left). The returned instance's point order will still be CCW tri-strip
// order.
static GrQuad MakeFromSkQuad(const SkPoint pts[4], const SkMatrix&);
GrQuad& operator=(const GrQuad& that) = default;
SkPoint point(int i) const { return {fX[i], fY[i]}; }
SkRect bounds() const {
auto x = this->x4f(), y = this->y4f();
return {x.min(), y.min(), x.max(), y.max()};
}
float x(int i) const { return fX[i]; }
float y(int i) const { return fY[i]; }
Sk4f x4f() const { return Sk4f::Load(fX); }
Sk4f y4f() const { return Sk4f::Load(fY); }
// True if anti-aliasing affects this quad. Requires quadType() == kRect_QuadType
bool aaHasEffectOnRect() const;
#ifdef SK_DEBUG
GrQuadType quadType() const;
#endif
private:
template<typename T>
friend class GrQuadListBase;
float fX[4];
float fY[4];
};
class GrPerspQuad {
public:
GrPerspQuad() = default;
explicit GrPerspQuad(const SkRect& rect)
: fX{rect.fLeft, rect.fLeft, rect.fRight, rect.fRight}
, fY{rect.fTop, rect.fBottom, rect.fTop, rect.fBottom}
, fW{1.f, 1.f, 1.f, 1.f} {}
GrPerspQuad(const Sk4f& xs, const Sk4f& ys) {
xs.store(fX);
ys.store(fY);
fW[0] = fW[1] = fW[2] = fW[3] = 1.f;
}
GrPerspQuad(const Sk4f& xs, const Sk4f& ys, const Sk4f& ws) {
xs.store(fX);
ys.store(fY);
ws.store(fW);
}
static GrPerspQuad MakeFromRect(const SkRect&, const SkMatrix&);
// Creates a GrPerspQuad from the quadrilateral 'pts', transformed by the matrix. The input
// points array is arranged as per SkRect::toQuad (top-left, top-right, bottom-right,
// bottom-left). The returned instance's point order will still be CCW tri-strip order.
static GrPerspQuad MakeFromSkQuad(const SkPoint pts[4], const SkMatrix&);
GrPerspQuad& operator=(const GrPerspQuad&) = default;
SkPoint3 point(int i) const { return {fX[i], fY[i], fW[i]}; }
SkRect bounds(GrQuadType type) const {
SkASSERT(this->quadType() <= type);
Sk4f x = this->x4f();
Sk4f y = this->y4f();
if (type == GrQuadType::kPerspective) {
Sk4f iw = this->iw4f();
x *= iw;
y *= iw;
}
return {x.min(), y.min(), x.max(), y.max()};
}
float x(int i) const { return fX[i]; }
float y(int i) const { return fY[i]; }
float w(int i) const { return fW[i]; }
float iw(int i) const { return sk_ieee_float_divide(1.f, fW[i]); }
Sk4f x4f() const { return Sk4f::Load(fX); }
Sk4f y4f() const { return Sk4f::Load(fY); }
Sk4f w4f() const { return Sk4f::Load(fW); }
Sk4f iw4f() const { return this->w4f().invert(); }
bool hasPerspective() const { return (w4f() != Sk4f(1.f)).anyTrue(); }
// True if anti-aliasing affects this quad. Requires quadType() == kRect_QuadType
bool aaHasEffectOnRect() const;
#ifdef SK_DEBUG
GrQuadType quadType() const;
#endif
private:
template<typename T>
friend class GrQuadListBase;
// Copy 4 values from each of the arrays into the quad's components
GrPerspQuad(const float xs[4], const float ys[4], const float ws[4]);
float fX[4];
float fY[4];
float fW[4];
};
// Underlying data used by GrQuadListBase. It is defined outside of GrQuadListBase due to compiler
// issues related to specializing member types.
template<typename T>
struct QuadData {
float fX[4];
float fY[4];
T fMetadata;
};
template<>
struct QuadData<void> {
float fX[4];
float fY[4];
};
// A dynamic list of (possibly) perspective quads that tracks the most general quad type of all
// added quads. It avoids storing the 3rd component if the quad type never becomes perspective.
// Use GrQuadList subclass when only storing quads. Use GrTQuadList subclass when storing quads
// and per-quad templated metadata (such as color or domain).
template<typename T>
class GrQuadListBase {
public:
int count() const { return fXYs.count(); }
GrQuadType quadType() const { return fType; }
void reserve(int count, GrQuadType forType) {
fXYs.reserve(count);
if (forType == GrQuadType::kPerspective || fType == GrQuadType::kPerspective) {
fWs.reserve(4 * count);
}
}
GrPerspQuad operator[] (int i) const {
SkASSERT(i < this->count());
SkASSERT(i >= 0);
const QuadData<T>& item = fXYs[i];
if (fType == GrQuadType::kPerspective) {
// Read the explicit ws
return GrPerspQuad(item.fX, item.fY, fWs.begin() + 4 * i);
} else {
// Ws are implicitly 1s.
static constexpr float kNoPerspectiveWs[4] = {1.f, 1.f, 1.f, 1.f};
return GrPerspQuad(item.fX, item.fY, kNoPerspectiveWs);
}
}
// Subclasses expose push_back(const GrQuad|GrPerspQuad&, GrQuadType, [const T&]), where
// the metadata argument is only present in GrTQuadList's push_back definition.
protected:
GrQuadListBase() : fType(GrQuadType::kRect) {}
void concatImpl(const GrQuadListBase<T>& that) {
this->upgradeType(that.fType);
fXYs.push_back_n(that.fXYs.count(), that.fXYs.begin());
if (fType == GrQuadType::kPerspective) {
if (that.fType == GrQuadType::kPerspective) {
// Copy the other's ws into the end of this list's data
fWs.push_back_n(that.fWs.count(), that.fWs.begin());
} else {
// This list stores ws but the appended list had implicit 1s, so add explicit 1s to
// fill out the total list
fWs.push_back_n(4 * that.count(), 1.f);
}
}
}
// Returns the added item data so that its metadata can be initialized if T is not void
QuadData<T>& pushBackImpl(const GrQuad& quad, GrQuadType type) {
SkASSERT(quad.quadType() <= type);
this->upgradeType(type);
QuadData<T>& item = fXYs.push_back();
memcpy(item.fX, quad.fX, 4 * sizeof(float));
memcpy(item.fY, quad.fY, 4 * sizeof(float));
if (fType == GrQuadType::kPerspective) {
fWs.push_back_n(4, 1.f);
}
return item;
}
QuadData<T>& pushBackImpl(const GrPerspQuad& quad, GrQuadType type) {
SkASSERT(quad.quadType() <= type);
this->upgradeType(type);
QuadData<T>& item = fXYs.push_back();
memcpy(item.fX, quad.fX, 4 * sizeof(float));
memcpy(item.fY, quad.fY, 4 * sizeof(float));
if (fType == GrQuadType::kPerspective) {
fWs.push_back_n(4, quad.fW);
}
return item;
}
const QuadData<T>& item(int i) const {
return fXYs[i];
}
QuadData<T>& item(int i) {
return fXYs[i];
}
private:
void upgradeType(GrQuadType type) {
// Possibly upgrade the overall type tracked by the list
if (type > fType) {
fType = type;
if (type == GrQuadType::kPerspective) {
// All existing quads were 2D, so the ws array just needs to be filled with 1s
fWs.push_back_n(4 * this->count(), 1.f);
}
}
}
// Interleaves xs, ys, and per-quad metadata so that all data for a single quad is together
// (barring ws, which can be dropped entirely if the quad type allows it).
SkSTArray<1, QuadData<T>, true> fXYs;
// The w channel is kept separate so that it can remain empty when only dealing with 2D quads.
SkTArray<float, true> fWs;
GrQuadType fType;
};
// This list only stores the quad data itself.
class GrQuadList : public GrQuadListBase<void> {
public:
GrQuadList() : INHERITED() {}
void concat(const GrQuadList& that) {
this->concatImpl(that);
}
void push_back(const GrQuad& quad, GrQuadType type) {
this->pushBackImpl(quad, type);
}
void push_back(const GrPerspQuad& quad, GrQuadType type) {
this->pushBackImpl(quad, type);
}
private:
typedef GrQuadListBase<void> INHERITED;
};
// This variant of the list allows simple metadata to be stored per quad as well, such as color
// or texture domain.
template<typename T>
class GrTQuadList : public GrQuadListBase<T> {
public:
GrTQuadList() : INHERITED() {}
void concat(const GrTQuadList<T>& that) {
this->concatImpl(that);
}
// Adding to the list requires metadata
void push_back(const GrQuad& quad, GrQuadType type, T&& metadata) {
QuadData<T>& item = this->pushBackImpl(quad, type);
item.fMetadata = std::move(metadata);
}
void push_back(const GrPerspQuad& quad, GrQuadType type, T&& metadata) {
QuadData<T>& item = this->pushBackImpl(quad, type);
item.fMetadata = std::move(metadata);
}
// And provide access to the metadata per quad
const T& metadata(int i) const {
return this->item(i).fMetadata;
}
T& metadata(int i) {
return this->item(i).fMetadata;
}
private:
typedef GrQuadListBase<T> INHERITED;
};
#endif