1 /*
2  * Copyright 2016 The Android Open Source Project
3  *
4  * Use of this source code is governed by a BSD-style license that can be
5  * found in the LICENSE file.
6  */
7 
8 #include "SkAnalyticEdge.h"
9 #include "SkAntiRun.h"
10 #include "SkAutoMalloc.h"
11 #include "SkBlitter.h"
12 #include "SkCoverageDelta.h"
13 #include "SkEdge.h"
14 #include "SkEdgeBuilder.h"
15 #include "SkGeometry.h"
16 #include "SkMask.h"
17 #include "SkPath.h"
18 #include "SkQuadClipper.h"
19 #include "SkRasterClip.h"
20 #include "SkRegion.h"
21 #include "SkScan.h"
22 #include "SkScanPriv.h"
23 #include "SkTSort.h"
24 #include "SkTemplates.h"
25 #include "SkUTF.h"
26 
27 #if defined(SK_DISABLE_DAA)
DAAFillPath(const SkPath & path,SkBlitter * blitter,const SkIRect & ir,const SkIRect & clipBounds,bool forceRLE,SkDAARecord * record)28 void SkScan::DAAFillPath(const SkPath& path, SkBlitter* blitter, const SkIRect& ir,
29                          const SkIRect& clipBounds, bool forceRLE, SkDAARecord* record) {
30     SkDEBUGFAIL("DAA Disabled");
31     return;
32 }
33 #else
34 ///////////////////////////////////////////////////////////////////////////////
35 
36 /*
37 
38 DAA stands for Delta-based Anti-Aliasing.
39 
40 This is an improved version of our analytic AA algorithm (in SkScan_AAAPath.cpp)
41 which first scan convert paths into coverage deltas (this step can happen out of order,
42 and we don't seem to be needed to worry about the intersection, clamping, etc.),
43 and then use a single blitter run to convert all those deltas into the final alphas.
44 
45 Before we go to the final blitter run, we'll use SkFixed for all delta values so we
46 don't ever have to worry about under/overflow.
47 
48 */
49 
50 ///////////////////////////////////////////////////////////////////////////////
51 
52 // The following helper functions are the same as those from SkScan_AAAPath.cpp
53 // except that we use SkFixed everywhere instead of SkAlpha.
54 
SkFixedMul_lowprec(SkFixed a,SkFixed b)55 static inline SkFixed SkFixedMul_lowprec(SkFixed a, SkFixed b) {
56     return (a >> 8) * (b >> 8);
57 }
58 
59 // Return the alpha of a trapezoid whose height is 1
trapezoidToAlpha(SkFixed l1,SkFixed l2)60 static inline SkFixed trapezoidToAlpha(SkFixed l1, SkFixed l2) {
61     SkASSERT(l1 >= 0 && l2 >= 0);
62     return (l1 + l2) >> 1;
63 }
64 
65 // The alpha of right-triangle (a, a*b)
partialTriangleToAlpha(SkFixed a,SkFixed b)66 static inline SkFixed partialTriangleToAlpha(SkFixed a, SkFixed b) {
67     SkASSERT(a <= SK_Fixed1);
68     // SkFixedMul(SkFixedMul(a, a), b) >> 1
69     // return ((((a >> 8) * (a >> 8)) >> 8) * (b >> 8)) >> 1;
70     return (a >> 11) * (a >> 11) * (b >> 11);
71 }
72 
getPartialAlpha(SkFixed alpha,SkFixed partialMultiplier)73 static inline SkFixed getPartialAlpha(SkFixed alpha, SkFixed partialMultiplier) {
74     // DAA should not be so sensitive to the precision (compared to AAA).
75     return SkFixedMul_lowprec(alpha, partialMultiplier);
76 }
77 
78 ///////////////////////////////////////////////////////////////////////////////
79 
80 template<bool isPartial, class Deltas>
add_coverage_delta_segment(int y,SkFixed rowHeight,const SkAnalyticEdge * edge,SkFixed nextX,Deltas * deltas)81 static inline void add_coverage_delta_segment(int y, SkFixed rowHeight, const SkAnalyticEdge* edge,
82         SkFixed nextX, Deltas* deltas) { // rowHeight=fullAlpha
83     SkASSERT(rowHeight <= SK_Fixed1 && rowHeight >= 0);
84 
85     // Let's see if multiplying sign is faster than multiplying edge->fWinding.
86     // (Compiler should be able to optimize multiplication with 1/-1?)
87     int sign = edge->fWinding == 1 ? 1 : -1;
88 
89     SkFixed l = SkTMin(edge->fX, nextX);
90     SkFixed r = edge->fX + nextX - l;
91     int     L = SkFixedFloorToInt(l);
92     int     R = SkFixedCeilToInt(r);
93     int     len = R - L;
94 
95     switch (len) {
96         case 0: {
97             deltas->addDelta(L, y, rowHeight * sign);
98             return;
99         }
100         case 1: {
101             SkFixed fixedR  = SkIntToFixed(R);
102             SkFixed alpha   = trapezoidToAlpha(fixedR - l, fixedR - r);
103             if (isPartial) {
104                 alpha = getPartialAlpha(alpha, rowHeight);
105             }
106             deltas->addDelta(L,     y,  alpha * sign);
107             deltas->addDelta(L + 1, y,  (rowHeight - alpha) * sign);
108             return;
109         }
110         case 2: {
111             SkFixed middle  = SkIntToFixed(L + 1);
112             SkFixed x1      = middle - l;
113             SkFixed x2      = r - middle;
114             SkFixed alpha1  = partialTriangleToAlpha(x1, edge->fDY);
115             SkFixed alpha2  = rowHeight - partialTriangleToAlpha(x2, edge->fDY);
116             deltas->addDelta(L,     y,  alpha1 * sign);
117             deltas->addDelta(L + 1, y,  (alpha2 - alpha1) * sign);
118             deltas->addDelta(L + 2, y,  (rowHeight - alpha2) * sign);
119             return;
120         }
121     }
122 
123     // When len > 2, computations are similar to computeAlphaAboveLine in SkScan_AAAPath.cpp
124     SkFixed dY      = edge->fDY;
125     SkFixed fixedL  = SkIntToFixed(L);
126     SkFixed fixedR  = SkIntToFixed(R);
127     SkFixed first   = SK_Fixed1 + fixedL - l; // horizontal edge of the left-most triangle
128     SkFixed last    = r - (fixedR - SK_Fixed1); // horizontal edge of the right-most triangle
129     SkFixed firstH  = SkFixedMul_lowprec(first, dY); // vertical edge of the left-most triangle
130 
131     SkFixed alpha0  = SkFixedMul_lowprec(first, firstH) >> 1;   // triangle alpha
132     SkFixed alpha1  = firstH + (dY >> 1);                       // rectangle plus triangle
133     deltas->addDelta(L, y, alpha0 * sign);
134     deltas->addDelta(L + 1, y, (alpha1 - alpha0) * sign);
135     for(int i = 2; i < len - 1; ++i) {
136         deltas->addDelta(L + i, y, dY * sign); // the increment is always a rect of height = dY
137     }
138 
139     SkFixed alphaR2     = alpha1 + dY * (len - 3);                      // the alpha at R - 2
140     SkFixed lastAlpha   = rowHeight - partialTriangleToAlpha(last, dY); // the alpha at R - 1
141     deltas->addDelta(R - 1, y, (lastAlpha - alphaR2) * sign);
142     deltas->addDelta(R,     y, (rowHeight - lastAlpha) * sign);
143 }
144 
145 class XLessThan {
146 public:
operator ()(const SkBezier * a,const SkBezier * b)147     bool operator()(const SkBezier* a, const SkBezier* b) {
148         return a->fP0.fX + a->fP1.fX < b->fP0.fX + b->fP1.fX;
149     }
150 };
151 
152 class YLessThan {
153 public:
operator ()(const SkBezier * a,const SkBezier * b)154     bool operator()(const SkBezier* a, const SkBezier* b) {
155         return a->fP0.fY + a->fP1.fY < b->fP0.fY + b->fP1.fY;
156     }
157 };
158 
159 template<class Deltas> static SK_ALWAYS_INLINE
gen_alpha_deltas(const SkPath & path,const SkIRect & clippedIR,const SkIRect & clipBounds,Deltas & result,SkBlitter * blitter,bool skipRect,bool pathContainedInClip)160 void gen_alpha_deltas(const SkPath& path, const SkIRect& clippedIR, const SkIRect& clipBounds,
161         Deltas& result, SkBlitter* blitter, bool skipRect, bool pathContainedInClip) {
162     // 1. Build edges
163     SkBezierEdgeBuilder builder;
164     // We have to use clipBounds instead of clippedIR to build edges because of "canCullToTheRight":
165     // if the builder finds a right edge past the right clip, it won't build that right edge.
166     int  count = builder.buildEdges(path, pathContainedInClip ? nullptr : &clipBounds);
167 
168     if (count == 0) {
169         return;
170     }
171     SkBezier** list = builder.bezierList();
172 
173     // 2. Try to find the rect part because blitAntiRect is so much faster than blitCoverageDeltas
174     int rectTop = clippedIR.fBottom;   // the rect is initialized to be empty as top = bot
175     int rectBot = clippedIR.fBottom;
176     if (skipRect) {             // only find that rect is skipRect == true
177         YLessThan lessThan;     // sort edges in YX order
178         SkTQSort(list, list + count - 1, lessThan);
179         for(int i = 0; i < count - 1; ++i) {
180             SkBezier* lb = list[i];
181             SkBezier* rb = list[i + 1];
182 
183             // fCount == 2 ensures that lb and rb are lines instead of quads or cubics.
184             bool lDX0 = lb->fP0.fX == lb->fP1.fX && lb->fCount == 2;
185             bool rDX0 = rb->fP0.fX == rb->fP1.fX && rb->fCount == 2;
186             if (!lDX0 || !rDX0) { // make sure that the edges are vertical
187                 continue;
188             }
189 
190             SkAnalyticEdge l, r;
191             if (!l.setLine(lb->fP0, lb->fP1) || !r.setLine(rb->fP0, rb->fP1)) {
192                 continue;
193             }
194 
195             SkFixed xorUpperY = l.fUpperY ^ r.fUpperY;
196             SkFixed xorLowerY = l.fLowerY ^ r.fLowerY;
197             if ((xorUpperY | xorLowerY) == 0) { // equal upperY and lowerY
198                 rectTop = SkFixedCeilToInt(l.fUpperY);
199                 rectBot = SkFixedFloorToInt(l.fLowerY);
200                 if (rectBot > rectTop) { // if bot == top, the rect is too short for blitAntiRect
201                     int L = SkFixedCeilToInt(l.fUpperX);
202                     int R = SkFixedFloorToInt(r.fUpperX);
203                     if (L <= R) {
204                         SkAlpha la = (SkIntToFixed(L) - l.fUpperX) >> 8;
205                         SkAlpha ra = (r.fUpperX - SkIntToFixed(R)) >> 8;
206                         result.setAntiRect(L - 1, rectTop, R - L, rectBot - rectTop, la, ra);
207                     } else { // too thin to use blitAntiRect; reset the rect region to be emtpy
208                         rectTop = rectBot = clippedIR.fBottom;
209                     }
210                 }
211                 break;
212             }
213 
214         }
215     }
216 
217     // 3. Sort edges in x so we may need less sorting for delta based on x. This only helps
218     //    SkCoverageDeltaList. And we don't want to sort more than SORT_THRESHOLD edges where
219     //    the log(count) factor of the quick sort may become a bottleneck; when there are so
220     //    many edges, we're unlikely to make deltas sorted anyway.
221     constexpr int SORT_THRESHOLD = 256;
222     if (std::is_same<Deltas, SkCoverageDeltaList>::value && count < SORT_THRESHOLD) {
223         XLessThan lessThan;
224         SkTQSort(list, list + count - 1, lessThan);
225     }
226 
227     // Future todo: parallize and SIMD the following code.
228     // 4. iterate through edges and generate deltas
229     for(int index = 0; index < count; ++index) {
230         SkAnalyticCubicEdge storage;
231         SkASSERT(sizeof(SkAnalyticQuadraticEdge) >= sizeof(SkAnalyticEdge));
232         SkASSERT(sizeof(SkAnalyticCubicEdge) >= sizeof(SkAnalyticQuadraticEdge));
233 
234         SkBezier* bezier        = list[index];
235         SkAnalyticEdge* currE   = &storage;
236         bool edgeSet            = false;
237 
238         int originalWinding = 1;
239         bool sortY = true;
240         switch (bezier->fCount) {
241             case 2: {
242                 edgeSet = currE->setLine(bezier->fP0, bezier->fP1);
243                 originalWinding = currE->fWinding;
244                 break;
245             }
246             case 3: {
247                 SkQuad* quad = static_cast<SkQuad*>(bezier);
248                 SkPoint pts[3] = {quad->fP0, quad->fP1, quad->fP2};
249                 edgeSet = static_cast<SkAnalyticQuadraticEdge*>(currE)->setQuadratic(pts);
250                 originalWinding = static_cast<SkAnalyticQuadraticEdge*>(currE)->fQEdge.fWinding;
251                 break;
252             }
253             case 4: {
254                 sortY = false;
255                 SkCubic* cubic = static_cast<SkCubic*>(bezier);
256                 SkPoint pts[4] = {cubic->fP0, cubic->fP1, cubic->fP2, cubic->fP3};
257                 edgeSet = static_cast<SkAnalyticCubicEdge*>(currE)->setCubic(pts, sortY);
258                 originalWinding = static_cast<SkAnalyticCubicEdge*>(currE)->fCEdge.fWinding;
259                 break;
260             }
261         }
262 
263         if (!edgeSet) {
264             continue;
265         }
266 
267         do {
268             currE->fX =  currE->fUpperX;
269 
270             SkFixed upperFloor  = SkFixedFloorToFixed(currE->fUpperY);
271             SkFixed lowerCeil   = SkFixedCeilToFixed(currE->fLowerY);
272             int     iy          = SkFixedFloorToInt(upperFloor);
273 
274             if (lowerCeil <= upperFloor + SK_Fixed1) { // only one row is affected by the currE
275                 SkFixed rowHeight = currE->fLowerY - currE->fUpperY;
276                 SkFixed nextX = currE->fX + SkFixedMul(currE->fDX, rowHeight);
277                 if (iy >= clippedIR.fTop && iy < clippedIR.fBottom) {
278                     add_coverage_delta_segment<true>(iy, rowHeight, currE, nextX, &result);
279                 }
280                 continue;
281             }
282 
283             // check first row
284             SkFixed rowHeight = upperFloor + SK_Fixed1 - currE->fUpperY;
285             SkFixed nextX;
286             if (rowHeight != SK_Fixed1) {   // it's a partial row
287                 nextX = currE->fX + SkFixedMul(currE->fDX, rowHeight);
288                 add_coverage_delta_segment<true>(iy, rowHeight, currE, nextX, &result);
289             } else {                        // it's a full row so we can leave it to the while loop
290                 iy--;                       // compensate the iy++ in the while loop
291                 nextX = currE->fX;
292             }
293 
294             while (true) { // process the full rows in the middle
295                 iy++;
296                 SkFixed y = SkIntToFixed(iy);
297                 currE->fX = nextX;
298                 nextX += currE->fDX;
299 
300                 if (y + SK_Fixed1 > currE->fLowerY) {
301                     break; // no full rows left, break
302                 }
303 
304                 // Check whether we're in the rect part that will be covered by blitAntiRect
305                 if (iy >= rectTop && iy < rectBot) {
306                     SkASSERT(currE->fDX == 0);  // If yes, we must be on an edge with fDX = 0.
307                     iy = rectBot - 1;           // Skip the rect part by advancing iy to the bottom.
308                     continue;
309                 }
310 
311                 // Add current edge's coverage deltas on this full row
312                 add_coverage_delta_segment<false>(iy, SK_Fixed1, currE, nextX, &result);
313             }
314 
315             // last partial row
316             if (SkIntToFixed(iy) < currE->fLowerY &&
317                     iy >= clippedIR.fTop && iy < clippedIR.fBottom) {
318                 rowHeight = currE->fLowerY - SkIntToFixed(iy);
319                 nextX = currE->fX + SkFixedMul(currE->fDX, rowHeight);
320                 add_coverage_delta_segment<true>(iy, rowHeight, currE, nextX, &result);
321             }
322         // Intended assignment to fWinding to restore the maybe-negated winding (during updateLine)
323         } while ((currE->fWinding = originalWinding) && currE->update(currE->fLowerY, sortY));
324     }
325 }
326 
DAAFillPath(const SkPath & path,SkBlitter * blitter,const SkIRect & ir,const SkIRect & clipBounds,bool forceRLE,SkDAARecord * record)327 void SkScan::DAAFillPath(const SkPath& path, SkBlitter* blitter, const SkIRect& ir,
328                          const SkIRect& clipBounds, bool forceRLE, SkDAARecord* record) {
329     bool containedInClip = clipBounds.contains(ir);
330     bool isEvenOdd  = path.getFillType() & 1;
331     bool isConvex   = path.isConvex();
332     bool isInverse  = path.isInverseFillType();
333     bool skipRect   = isConvex && !isInverse;
334     bool isInitOnce = record && record->fType == SkDAARecord::Type::kToBeComputed;
335 
336     SkIRect clippedIR = ir;
337     clippedIR.intersect(clipBounds);
338 
339     // The overhead of even constructing SkCoverageDeltaList/Mask is too big.
340     // So TryBlitFatAntiRect and return if it's successful.
341     if (!isInverse && TryBlitFatAntiRect(blitter, path, clipBounds)) {
342         SkDAARecord::SetEmpty(record);
343         return;
344     }
345 
346 #ifdef SK_BUILD_FOR_GOOGLE3
347     constexpr int STACK_SIZE = 12 << 10; // 12K stack size alloc; Google3 has 16K limit.
348 #else
349     constexpr int STACK_SIZE = 64 << 10; // 64k stack size to avoid heap allocation
350 #endif
351     SkSTArenaAlloc<STACK_SIZE> stackAlloc; // avoid heap allocation with SkSTArenaAlloc
352 
353     // Set alloc to record's alloc if and only if we're in the init-once phase. We have to do that
354     // during init phase because the mask or list needs to live longer. We can't do that during blit
355     // phase because the same record could be accessed by multiple threads simultaneously.
356     SkArenaAlloc* alloc = isInitOnce ? record->fAlloc : &stackAlloc;
357 
358     if (record == nullptr) {
359         record = alloc->make<SkDAARecord>(alloc);
360     }
361 
362     // Only blitter->blitXXX needs to be done in order in the threaded backend. Everything else can
363     // be done out of order in the init-once phase. We do that by calling DAAFillPath twice: first
364     // with a null blitter, and then second with the real blitter and the SkMask/SkCoverageDeltaList
365     // generated in the first step.
366     if (record->fType == SkDAARecord::Type::kToBeComputed) {
367         if (!forceRLE && !isInverse && SkCoverageDeltaMask::Suitable(clippedIR)) {
368             record->fType = SkDAARecord::Type::kMask;
369             SkCoverageDeltaMask deltaMask(alloc, clippedIR);
370             gen_alpha_deltas(path, clippedIR, clipBounds, deltaMask, blitter, skipRect,
371                              containedInClip);
372             deltaMask.convertCoverageToAlpha(isEvenOdd, isInverse, isConvex);
373             record->fMask = deltaMask.prepareSkMask();
374         } else {
375             record->fType = SkDAARecord::Type::kList;
376             SkCoverageDeltaList* deltaList = alloc->make<SkCoverageDeltaList>(
377                     alloc, clippedIR, forceRLE);
378             gen_alpha_deltas(path, clippedIR, clipBounds, *deltaList, blitter, skipRect,
379                              containedInClip);
380             record->fList = deltaList;
381         }
382     }
383 
384     if (!isInitOnce) {
385         SkASSERT(record->fType != SkDAARecord::Type::kToBeComputed);
386         if (record->fType == SkDAARecord::Type::kMask) {
387             blitter->blitMask(record->fMask, clippedIR);
388         } else {
389             blitter->blitCoverageDeltas(record->fList, clipBounds, isEvenOdd, isInverse, isConvex);
390         }
391     }
392 }
393 #endif //defined(SK_DISABLE_DAA)
394