/* * Copyright 2006 The Android Open Source Project * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef SkAnalyticEdge_DEFINED #define SkAnalyticEdge_DEFINED #include "SkEdge.h" #include "SkTo.h" #include struct SkAnalyticEdge { // Similar to SkEdge, the conic edges will be converted to quadratic edges enum Type { kLine_Type, kQuad_Type, kCubic_Type }; SkAnalyticEdge* fNext; SkAnalyticEdge* fPrev; // During aaa_walk_edges, if this edge is a left edge, // then fRiteE is its corresponding right edge. Otherwise it's nullptr. SkAnalyticEdge* fRiteE; SkFixed fX; SkFixed fDX; SkFixed fUpperX; // The x value when y = fUpperY SkFixed fY; // The current y SkFixed fUpperY; // The upper bound of y (our edge is from y = fUpperY to y = fLowerY) SkFixed fLowerY; // The lower bound of y (our edge is from y = fUpperY to y = fLowerY) SkFixed fDY; // abs(1/fDX); may be SK_MaxS32 when fDX is close to 0. // fDY is only used for blitting trapezoids. SkFixed fSavedX; // For deferred blitting SkFixed fSavedY; // For deferred blitting SkFixed fSavedDY; // For deferred blitting int8_t fCurveCount; // only used by kQuad(+) and kCubic(-) uint8_t fCurveShift; // appled to all Dx/DDx/DDDx except for fCubicDShift exception uint8_t fCubicDShift; // applied to fCDx and fCDy only in cubic int8_t fWinding; // 1 or -1 static const int kDefaultAccuracy = 2; // default accuracy for snapping static inline SkFixed SnapY(SkFixed y) { const int accuracy = kDefaultAccuracy; // This approach is safer than left shift, round, then right shift return ((unsigned)y + (SK_Fixed1 >> (accuracy + 1))) >> (16 - accuracy) << (16 - accuracy); } // Update fX, fY of this edge so fY = y inline void goY(SkFixed y) { if (y == fY + SK_Fixed1) { fX = fX + fDX; fY = y; } else if (y != fY) { // Drop lower digits as our alpha only has 8 bits // (fDX and y - fUpperY may be greater than SK_Fixed1) fX = fUpperX + SkFixedMul(fDX, y - fUpperY); fY = y; } } inline void goY(SkFixed y, int yShift) { SkASSERT(yShift >= 0 && yShift <= kDefaultAccuracy); SkASSERT(fDX == 0 || y - fY == SK_Fixed1 >> yShift); fY = y; fX += fDX >> yShift; } inline void saveXY(SkFixed x, SkFixed y, SkFixed dY) { fSavedX = x; fSavedY = y; fSavedDY = dY; } bool setLine(const SkPoint& p0, const SkPoint& p1); bool updateLine(SkFixed ax, SkFixed ay, SkFixed bx, SkFixed by, SkFixed slope); // return true if we're NOT done with this edge bool update(SkFixed last_y, bool sortY = true); #ifdef SK_DEBUG void dump() const { SkDebugf("edge: upperY:%d lowerY:%d y:%g x:%g dx:%g w:%d\n", fUpperY, fLowerY, SkFixedToFloat(fY), SkFixedToFloat(fX), SkFixedToFloat(fDX), fWinding); } void validate() const { SkASSERT(fPrev && fNext); SkASSERT(fPrev->fNext == this); SkASSERT(fNext->fPrev == this); SkASSERT(fUpperY < fLowerY); SkASSERT(SkAbs32(fWinding) == 1); } #endif }; struct SkAnalyticQuadraticEdge : public SkAnalyticEdge { SkQuadraticEdge fQEdge; // snap y to integer points in the middle of the curve to accelerate AAA path filling SkFixed fSnappedX, fSnappedY; bool setQuadratic(const SkPoint pts[3]); bool updateQuadratic(); inline void keepContinuous() { // We use fX as the starting x to ensure the continuouty. // Without it, we may break the sorted edge list. SkASSERT(SkAbs32(fX - SkFixedMul(fY - fSnappedY, fDX) - fSnappedX) < SK_Fixed1); SkASSERT(SkAbs32(fY - fSnappedY) < SK_Fixed1); // This may differ due to smooth jump fSnappedX = fX; fSnappedY = fY; } }; struct SkAnalyticCubicEdge : public SkAnalyticEdge { SkCubicEdge fCEdge; SkFixed fSnappedY; // to make sure that y is increasing with smooth jump and snapping bool setCubic(const SkPoint pts[4], bool sortY = true); bool updateCubic(bool sortY = true); inline void keepContinuous() { SkASSERT(SkAbs32(fX - SkFixedMul(fDX, fY - SnapY(fCEdge.fCy)) - fCEdge.fCx) < SK_Fixed1); fCEdge.fCx = fX; fSnappedY = fY; } }; struct SkBezier { int fCount; // 2 line, 3 quad, 4 cubic SkPoint fP0; SkPoint fP1; // See if left shift, covert to SkFDot6, and round has the same top and bottom y. // If so, the edge will be empty. static inline bool IsEmpty(SkScalar y0, SkScalar y1, int shift = 2) { #ifdef SK_RASTERIZE_EVEN_ROUNDING return SkScalarRoundToFDot6(y0, shift) == SkScalarRoundToFDot6(y1, shift); #else SkScalar scale = (1 << (shift + 6)); return SkFDot6Round(int(y0 * scale)) == SkFDot6Round(int(y1 * scale)); #endif } }; struct SkLine : public SkBezier { bool set(const SkPoint pts[2]){ if (IsEmpty(pts[0].fY, pts[1].fY)) { return false; } fCount = 2; fP0 = pts[0]; fP1 = pts[1]; return true; } }; struct SkQuad : public SkBezier { SkPoint fP2; bool set(const SkPoint pts[3]){ if (IsEmpty(pts[0].fY, pts[2].fY)) { return false; } fCount = 3; fP0 = pts[0]; fP1 = pts[1]; fP2 = pts[2]; return true; } }; struct SkCubic : public SkBezier { SkPoint fP2; SkPoint fP3; bool set(const SkPoint pts[4]){ // We do not chop at y extrema for cubics so pts[0], pts[1], pts[2], pts[3] may not be // monotonic. Therefore, we have to check the emptiness for all three pairs, instead of just // checking IsEmpty(pts[0].fY, pts[3].fY). if (IsEmpty(pts[0].fY, pts[1].fY) && IsEmpty(pts[1].fY, pts[2].fY) && IsEmpty(pts[2].fY, pts[3].fY)) { return false; } fCount = 4; fP0 = pts[0]; fP1 = pts[1]; fP2 = pts[2]; fP3 = pts[3]; return true; } }; #endif