blob: 936c87e832e8050753f0313160ce0fa8cf52fcd3 [file] [log] [blame]
/*
* 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.
*/
#include "SkRegionPriv.h"
#include "SkTemplates.h"
#include "SkThread.h"
#include "SkUtils.h"
/* Region Layout
*
* TOP
*
* [ Bottom, X-Intervals, [Left, Right]..., X-Sentinel ]
* ...
*
* Y-Sentinel
*/
SkDEBUGCODE(int32_t gRgnAllocCounter;)
/////////////////////////////////////////////////////////////////////////////////////////////////
/* Pass in the beginning with the intervals.
* We back up 1 to read the interval-count.
* Return the beginning of the next scanline (i.e. the next Y-value)
*/
static SkRegion::RunType* skip_intervals(const SkRegion::RunType runs[]) {
int intervals = runs[-1];
#ifdef SK_DEBUG
if (intervals > 0) {
SkASSERT(runs[0] < runs[1]);
SkASSERT(runs[1] < SkRegion::kRunTypeSentinel);
} else {
SkASSERT(0 == intervals);
SkASSERT(SkRegion::kRunTypeSentinel == runs[0]);
}
#endif
runs += intervals * 2 + 1;
return const_cast<SkRegion::RunType*>(runs);
}
bool SkRegion::RunsAreARect(const SkRegion::RunType runs[], int count,
SkIRect* bounds) {
assert_sentinel(runs[0], false); // top
SkASSERT(count >= kRectRegionRuns);
if (count == kRectRegionRuns) {
assert_sentinel(runs[1], false); // bottom
SkASSERT(1 == runs[2]);
assert_sentinel(runs[3], false); // left
assert_sentinel(runs[4], false); // right
assert_sentinel(runs[5], true);
assert_sentinel(runs[6], true);
SkASSERT(runs[0] < runs[1]); // valid height
SkASSERT(runs[3] < runs[4]); // valid width
bounds->set(runs[3], runs[0], runs[4], runs[1]);
return true;
}
return false;
}
//////////////////////////////////////////////////////////////////////////
SkRegion::SkRegion() {
fBounds.set(0, 0, 0, 0);
fRunHead = SkRegion_gEmptyRunHeadPtr;
}
SkRegion::SkRegion(const SkRegion& src) {
fRunHead = SkRegion_gEmptyRunHeadPtr; // just need a value that won't trigger sk_free(fRunHead)
this->setRegion(src);
}
SkRegion::SkRegion(const SkIRect& rect) {
fRunHead = SkRegion_gEmptyRunHeadPtr; // just need a value that won't trigger sk_free(fRunHead)
this->setRect(rect);
}
SkRegion::~SkRegion() {
this->freeRuns();
}
void SkRegion::freeRuns() {
if (this->isComplex()) {
SkASSERT(fRunHead->fRefCnt >= 1);
if (sk_atomic_dec(&fRunHead->fRefCnt) == 1) {
//SkASSERT(gRgnAllocCounter > 0);
//SkDEBUGCODE(sk_atomic_dec(&gRgnAllocCounter));
//SkDEBUGF(("************** gRgnAllocCounter::free %d\n", gRgnAllocCounter));
sk_free(fRunHead);
}
}
}
void SkRegion::allocateRuns(int count, int ySpanCount, int intervalCount) {
fRunHead = RunHead::Alloc(count, ySpanCount, intervalCount);
}
void SkRegion::allocateRuns(int count) {
fRunHead = RunHead::Alloc(count);
}
void SkRegion::allocateRuns(const RunHead& head) {
fRunHead = RunHead::Alloc(head.fRunCount,
head.getYSpanCount(),
head.getIntervalCount());
}
SkRegion& SkRegion::operator=(const SkRegion& src) {
(void)this->setRegion(src);
return *this;
}
void SkRegion::swap(SkRegion& other) {
SkTSwap<SkIRect>(fBounds, other.fBounds);
SkTSwap<RunHead*>(fRunHead, other.fRunHead);
}
bool SkRegion::setEmpty() {
this->freeRuns();
fBounds.set(0, 0, 0, 0);
fRunHead = SkRegion_gEmptyRunHeadPtr;
return false;
}
bool SkRegion::setRect(int32_t left, int32_t top,
int32_t right, int32_t bottom) {
if (left >= right || top >= bottom) {
return this->setEmpty();
}
this->freeRuns();
fBounds.set(left, top, right, bottom);
fRunHead = SkRegion_gRectRunHeadPtr;
return true;
}
bool SkRegion::setRect(const SkIRect& r) {
return this->setRect(r.fLeft, r.fTop, r.fRight, r.fBottom);
}
bool SkRegion::setRegion(const SkRegion& src) {
if (this != &src) {
this->freeRuns();
fBounds = src.fBounds;
fRunHead = src.fRunHead;
if (this->isComplex()) {
sk_atomic_inc(&fRunHead->fRefCnt);
}
}
return fRunHead != SkRegion_gEmptyRunHeadPtr;
}
bool SkRegion::op(const SkIRect& rect, const SkRegion& rgn, Op op) {
SkRegion tmp(rect);
return this->op(tmp, rgn, op);
}
bool SkRegion::op(const SkRegion& rgn, const SkIRect& rect, Op op) {
SkRegion tmp(rect);
return this->op(rgn, tmp, op);
}
///////////////////////////////////////////////////////////////////////////////
#ifdef SK_BUILD_FOR_ANDROID
char* SkRegion::toString() {
Iterator iter(*this);
int count = 0;
while (!iter.done()) {
count++;
iter.next();
}
// 4 ints, up to 10 digits each plus sign, 3 commas, '(', ')', SkRegion() and '\0'
const int max = (count*((11*4)+5))+11+1;
char* result = (char*)malloc(max);
if (result == NULL) {
return NULL;
}
count = sprintf(result, "SkRegion(");
iter.reset(*this);
while (!iter.done()) {
const SkIRect& r = iter.rect();
count += sprintf(result+count, "(%d,%d,%d,%d)", r.fLeft, r.fTop, r.fRight, r.fBottom);
iter.next();
}
count += sprintf(result+count, ")");
return result;
}
#endif
///////////////////////////////////////////////////////////////////////////////
int SkRegion::count_runtype_values(int* itop, int* ibot) const {
if (this == NULL) {
*itop = SK_MinS32;
*ibot = SK_MaxS32;
return 0;
}
int maxT;
if (this->isRect()) {
maxT = 2;
} else {
SkASSERT(this->isComplex());
maxT = fRunHead->getIntervalCount() * 2;
}
*itop = fBounds.fTop;
*ibot = fBounds.fBottom;
return maxT;
}
static bool isRunCountEmpty(int count) {
return count <= 2;
}
bool SkRegion::setRuns(RunType runs[], int count) {
SkDEBUGCODE(this->validate();)
SkASSERT(count > 0);
if (isRunCountEmpty(count)) {
// SkDEBUGF(("setRuns: empty\n"));
assert_sentinel(runs[count-1], true);
return this->setEmpty();
}
// trim off any empty spans from the top and bottom
// weird I should need this, perhaps op() could be smarter...
if (count > kRectRegionRuns) {
RunType* stop = runs + count;
assert_sentinel(runs[0], false); // top
assert_sentinel(runs[1], false); // bottom
// runs[2] is uncomputed intervalCount
if (runs[3] == SkRegion::kRunTypeSentinel) { // should be first left...
runs += 3; // skip empty initial span
runs[0] = runs[-2]; // set new top to prev bottom
assert_sentinel(runs[1], false); // bot: a sentinal would mean two in a row
assert_sentinel(runs[2], false); // intervalcount
assert_sentinel(runs[3], false); // left
assert_sentinel(runs[4], false); // right
}
assert_sentinel(stop[-1], true);
assert_sentinel(stop[-2], true);
// now check for a trailing empty span
if (stop[-5] == SkRegion::kRunTypeSentinel) { // eek, stop[-4] was a bottom with no x-runs
stop[-4] = SkRegion::kRunTypeSentinel; // kill empty last span
stop -= 3;
assert_sentinel(stop[-1], true); // last y-sentinel
assert_sentinel(stop[-2], true); // last x-sentinel
assert_sentinel(stop[-3], false); // last right
assert_sentinel(stop[-4], false); // last left
assert_sentinel(stop[-5], false); // last interval-count
assert_sentinel(stop[-6], false); // last bottom
}
count = (int)(stop - runs);
}
SkASSERT(count >= kRectRegionRuns);
if (SkRegion::RunsAreARect(runs, count, &fBounds)) {
return this->setRect(fBounds);
}
// if we get here, we need to become a complex region
if (!this->isComplex() || fRunHead->fRunCount != count) {
this->freeRuns();
this->allocateRuns(count);
}
// must call this before we can write directly into runs()
// in case we are sharing the buffer with another region (copy on write)
fRunHead = fRunHead->ensureWritable();
memcpy(fRunHead->writable_runs(), runs, count * sizeof(RunType));
fRunHead->computeRunBounds(&fBounds);
SkDEBUGCODE(this->validate();)
return true;
}
void SkRegion::BuildRectRuns(const SkIRect& bounds,
RunType runs[kRectRegionRuns]) {
runs[0] = bounds.fTop;
runs[1] = bounds.fBottom;
runs[2] = 1; // 1 interval for this scanline
runs[3] = bounds.fLeft;
runs[4] = bounds.fRight;
runs[5] = kRunTypeSentinel;
runs[6] = kRunTypeSentinel;
}
bool SkRegion::contains(int32_t x, int32_t y) const {
SkDEBUGCODE(this->validate();)
if (!fBounds.contains(x, y)) {
return false;
}
if (this->isRect()) {
return true;
}
SkASSERT(this->isComplex());
const RunType* runs = fRunHead->findScanline(y);
// Skip the Bottom and IntervalCount
runs += 2;
// Just walk this scanline, checking each interval. The X-sentinel will
// appear as a left-inteval (runs[0]) and should abort the search.
//
// We could do a bsearch, using interval-count (runs[1]), but need to time
// when that would be worthwhile.
//
for (;;) {
if (x < runs[0]) {
break;
}
if (x < runs[1]) {
return true;
}
runs += 2;
}
return false;
}
static SkRegion::RunType scanline_bottom(const SkRegion::RunType runs[]) {
return runs[0];
}
static const SkRegion::RunType* scanline_next(const SkRegion::RunType runs[]) {
// skip [B N [L R]... S]
return runs + 2 + runs[1] * 2 + 1;
}
static bool scanline_contains(const SkRegion::RunType runs[],
SkRegion::RunType L, SkRegion::RunType R) {
runs += 2; // skip Bottom and IntervalCount
for (;;) {
if (L < runs[0]) {
break;
}
if (R <= runs[1]) {
return true;
}
runs += 2;
}
return false;
}
bool SkRegion::contains(const SkIRect& r) const {
SkDEBUGCODE(this->validate();)
if (!fBounds.contains(r)) {
return false;
}
if (this->isRect()) {
return true;
}
SkASSERT(this->isComplex());
const RunType* scanline = fRunHead->findScanline(r.fTop);
for (;;) {
if (!scanline_contains(scanline, r.fLeft, r.fRight)) {
return false;
}
if (r.fBottom <= scanline_bottom(scanline)) {
break;
}
scanline = scanline_next(scanline);
}
return true;
}
bool SkRegion::contains(const SkRegion& rgn) const {
SkDEBUGCODE(this->validate();)
SkDEBUGCODE(rgn.validate();)
if (this->isEmpty() || rgn.isEmpty() || !fBounds.contains(rgn.fBounds)) {
return false;
}
if (this->isRect()) {
return true;
}
if (rgn.isRect()) {
return this->contains(rgn.getBounds());
}
/*
* A contains B is equivalent to
* B - A == 0
*/
return !Oper(rgn, *this, kDifference_Op, NULL);
}
const SkRegion::RunType* SkRegion::getRuns(RunType tmpStorage[],
int* intervals) const {
SkASSERT(tmpStorage && intervals);
const RunType* runs = tmpStorage;
if (this->isEmpty()) {
tmpStorage[0] = kRunTypeSentinel;
*intervals = 0;
} else if (this->isRect()) {
BuildRectRuns(fBounds, tmpStorage);
*intervals = 1;
} else {
runs = fRunHead->readonly_runs();
*intervals = fRunHead->getIntervalCount();
}
return runs;
}
///////////////////////////////////////////////////////////////////////////////
static bool scanline_intersects(const SkRegion::RunType runs[],
SkRegion::RunType L, SkRegion::RunType R) {
runs += 2; // skip Bottom and IntervalCount
for (;;) {
if (R <= runs[0]) {
break;
}
if (L < runs[1]) {
return true;
}
runs += 2;
}
return false;
}
bool SkRegion::intersects(const SkIRect& r) const {
SkDEBUGCODE(this->validate();)
if (this->isEmpty() || r.isEmpty()) {
return false;
}
SkIRect sect;
if (!sect.intersect(fBounds, r)) {
return false;
}
if (this->isRect()) {
return true;
}
SkASSERT(this->isComplex());
const RunType* scanline = fRunHead->findScanline(sect.fTop);
for (;;) {
if (scanline_intersects(scanline, sect.fLeft, sect.fRight)) {
return true;
}
if (sect.fBottom <= scanline_bottom(scanline)) {
break;
}
scanline = scanline_next(scanline);
}
return false;
}
bool SkRegion::intersects(const SkRegion& rgn) const {
if (this->isEmpty() || rgn.isEmpty()) {
return false;
}
if (!SkIRect::Intersects(fBounds, rgn.fBounds)) {
return false;
}
bool weAreARect = this->isRect();
bool theyAreARect = rgn.isRect();
if (weAreARect && theyAreARect) {
return true;
}
if (weAreARect) {
return rgn.intersects(this->getBounds());
}
if (theyAreARect) {
return this->intersects(rgn.getBounds());
}
// both of us are complex
return Oper(*this, rgn, kIntersect_Op, NULL);
}
///////////////////////////////////////////////////////////////////////////////
bool SkRegion::operator==(const SkRegion& b) const {
SkDEBUGCODE(validate();)
SkDEBUGCODE(b.validate();)
if (this == &b) {
return true;
}
if (fBounds != b.fBounds) {
return false;
}
const SkRegion::RunHead* ah = fRunHead;
const SkRegion::RunHead* bh = b.fRunHead;
// this catches empties and rects being equal
if (ah == bh) {
return true;
}
// now we insist that both are complex (but different ptrs)
if (!this->isComplex() || !b.isComplex()) {
return false;
}
return ah->fRunCount == bh->fRunCount &&
!memcmp(ah->readonly_runs(), bh->readonly_runs(),
ah->fRunCount * sizeof(SkRegion::RunType));
}
void SkRegion::translate(int dx, int dy, SkRegion* dst) const {
SkDEBUGCODE(this->validate();)
if (NULL == dst) {
return;
}
if (this->isEmpty()) {
dst->setEmpty();
} else if (this->isRect()) {
dst->setRect(fBounds.fLeft + dx, fBounds.fTop + dy,
fBounds.fRight + dx, fBounds.fBottom + dy);
} else {
if (this == dst) {
dst->fRunHead = dst->fRunHead->ensureWritable();
} else {
SkRegion tmp;
tmp.allocateRuns(*fRunHead);
tmp.fBounds = fBounds;
dst->swap(tmp);
}
dst->fBounds.offset(dx, dy);
const RunType* sruns = fRunHead->readonly_runs();
RunType* druns = dst->fRunHead->writable_runs();
*druns++ = (SkRegion::RunType)(*sruns++ + dy); // top
for (;;) {
int bottom = *sruns++;
if (bottom == kRunTypeSentinel) {
break;
}
*druns++ = (SkRegion::RunType)(bottom + dy); // bottom;
*druns++ = *sruns++; // copy intervalCount;
for (;;) {
int x = *sruns++;
if (x == kRunTypeSentinel) {
break;
}
*druns++ = (SkRegion::RunType)(x + dx);
*druns++ = (SkRegion::RunType)(*sruns++ + dx);
}
*druns++ = kRunTypeSentinel; // x sentinel
}
*druns++ = kRunTypeSentinel; // y sentinel
SkASSERT(sruns - fRunHead->readonly_runs() == fRunHead->fRunCount);
SkASSERT(druns - dst->fRunHead->readonly_runs() == dst->fRunHead->fRunCount);
}
SkDEBUGCODE(this->validate();)
}
///////////////////////////////////////////////////////////////////////////////
bool SkRegion::setRects(const SkIRect rects[], int count) {
if (0 == count) {
this->setEmpty();
} else {
this->setRect(rects[0]);
for (int i = 1; i < count; i++) {
this->op(rects[i], kUnion_Op);
}
}
return !this->isEmpty();
}
///////////////////////////////////////////////////////////////////////////////
#if defined _WIN32 && _MSC_VER >= 1300 // disable warning : local variable used without having been initialized
#pragma warning ( push )
#pragma warning ( disable : 4701 )
#endif
#ifdef SK_DEBUG
static void assert_valid_pair(int left, int rite)
{
SkASSERT(left == SkRegion::kRunTypeSentinel || left < rite);
}
#else
#define assert_valid_pair(left, rite)
#endif
struct spanRec {
const SkRegion::RunType* fA_runs;
const SkRegion::RunType* fB_runs;
int fA_left, fA_rite, fB_left, fB_rite;
int fLeft, fRite, fInside;
void init(const SkRegion::RunType a_runs[],
const SkRegion::RunType b_runs[]) {
fA_left = *a_runs++;
fA_rite = *a_runs++;
fB_left = *b_runs++;
fB_rite = *b_runs++;
fA_runs = a_runs;
fB_runs = b_runs;
}
bool done() const {
SkASSERT(fA_left <= SkRegion::kRunTypeSentinel);
SkASSERT(fB_left <= SkRegion::kRunTypeSentinel);
return fA_left == SkRegion::kRunTypeSentinel &&
fB_left == SkRegion::kRunTypeSentinel;
}
void next() {
assert_valid_pair(fA_left, fA_rite);
assert_valid_pair(fB_left, fB_rite);
int inside, left, rite SK_INIT_TO_AVOID_WARNING;
bool a_flush = false;
bool b_flush = false;
int a_left = fA_left;
int a_rite = fA_rite;
int b_left = fB_left;
int b_rite = fB_rite;
if (a_left < b_left) {
inside = 1;
left = a_left;
if (a_rite <= b_left) { // [...] <...>
rite = a_rite;
a_flush = true;
} else { // [...<..]...> or [...<...>...]
rite = a_left = b_left;
}
} else if (b_left < a_left) {
inside = 2;
left = b_left;
if (b_rite <= a_left) { // [...] <...>
rite = b_rite;
b_flush = true;
} else { // [...<..]...> or [...<...>...]
rite = b_left = a_left;
}
} else { // a_left == b_left
inside = 3;
left = a_left; // or b_left
if (a_rite <= b_rite) {
rite = b_left = a_rite;
a_flush = true;
}
if (b_rite <= a_rite) {
rite = a_left = b_rite;
b_flush = true;
}
}
if (a_flush) {
a_left = *fA_runs++;
a_rite = *fA_runs++;
}
if (b_flush) {
b_left = *fB_runs++;
b_rite = *fB_runs++;
}
SkASSERT(left <= rite);
// now update our state
fA_left = a_left;
fA_rite = a_rite;
fB_left = b_left;
fB_rite = b_rite;
fLeft = left;
fRite = rite;
fInside = inside;
}
};
static SkRegion::RunType* operate_on_span(const SkRegion::RunType a_runs[],
const SkRegion::RunType b_runs[],
SkRegion::RunType dst[],
int min, int max) {
spanRec rec;
bool firstInterval = true;
rec.init(a_runs, b_runs);
while (!rec.done()) {
rec.next();
int left = rec.fLeft;
int rite = rec.fRite;
// add left,rite to our dst buffer (checking for coincidence
if ((unsigned)(rec.fInside - min) <= (unsigned)(max - min) &&
left < rite) { // skip if equal
if (firstInterval || dst[-1] < left) {
*dst++ = (SkRegion::RunType)(left);
*dst++ = (SkRegion::RunType)(rite);
firstInterval = false;
} else {
// update the right edge
dst[-1] = (SkRegion::RunType)(rite);
}
}
}
*dst++ = SkRegion::kRunTypeSentinel;
return dst;
}
#if defined _WIN32 && _MSC_VER >= 1300
#pragma warning ( pop )
#endif
static const struct {
uint8_t fMin;
uint8_t fMax;
} gOpMinMax[] = {
{ 1, 1 }, // Difference
{ 3, 3 }, // Intersection
{ 1, 3 }, // Union
{ 1, 2 } // XOR
};
class RgnOper {
public:
RgnOper(int top, SkRegion::RunType dst[], SkRegion::Op op) {
// need to ensure that the op enum lines up with our minmax array
SkASSERT(SkRegion::kDifference_Op == 0);
SkASSERT(SkRegion::kIntersect_Op == 1);
SkASSERT(SkRegion::kUnion_Op == 2);
SkASSERT(SkRegion::kXOR_Op == 3);
SkASSERT((unsigned)op <= 3);
fStartDst = dst;
fPrevDst = dst + 1;
fPrevLen = 0; // will never match a length from operate_on_span
fTop = (SkRegion::RunType)(top); // just a first guess, we might update this
fMin = gOpMinMax[op].fMin;
fMax = gOpMinMax[op].fMax;
}
void addSpan(int bottom, const SkRegion::RunType a_runs[],
const SkRegion::RunType b_runs[]) {
// skip X values and slots for the next Y+intervalCount
SkRegion::RunType* start = fPrevDst + fPrevLen + 2;
// start points to beginning of dst interval
SkRegion::RunType* stop = operate_on_span(a_runs, b_runs, start, fMin, fMax);
size_t len = stop - start;
SkASSERT(len >= 1 && (len & 1) == 1);
SkASSERT(SkRegion::kRunTypeSentinel == stop[-1]);
if (fPrevLen == len &&
(1 == len || !memcmp(fPrevDst, start,
(len - 1) * sizeof(SkRegion::RunType)))) {
// update Y value
fPrevDst[-2] = (SkRegion::RunType)(bottom);
} else { // accept the new span
if (len == 1 && fPrevLen == 0) {
fTop = (SkRegion::RunType)(bottom); // just update our bottom
} else {
start[-2] = (SkRegion::RunType)(bottom);
start[-1] = len >> 1;
fPrevDst = start;
fPrevLen = len;
}
}
}
int flush() {
fStartDst[0] = fTop;
fPrevDst[fPrevLen] = SkRegion::kRunTypeSentinel;
return (int)(fPrevDst - fStartDst + fPrevLen + 1);
}
bool isEmpty() const { return 0 == fPrevLen; }
uint8_t fMin, fMax;
private:
SkRegion::RunType* fStartDst;
SkRegion::RunType* fPrevDst;
size_t fPrevLen;
SkRegion::RunType fTop;
};
// want a unique value to signal that we exited due to quickExit
#define QUICK_EXIT_TRUE_COUNT (-1)
static int operate(const SkRegion::RunType a_runs[],
const SkRegion::RunType b_runs[],
SkRegion::RunType dst[],
SkRegion::Op op,
bool quickExit) {
const SkRegion::RunType gEmptyScanline[] = {
0, // dummy bottom value
0, // zero intervals
SkRegion::kRunTypeSentinel,
// just need a 2nd value, since spanRec.init() reads 2 values, even
// though if the first value is the sentinel, it ignores the 2nd value.
// w/o the 2nd value here, we might read uninitialized memory.
// This happens when we are using gSentinel, which is pointing at
// our sentinel value.
0
};
const SkRegion::RunType* const gSentinel = &gEmptyScanline[2];
int a_top = *a_runs++;
int a_bot = *a_runs++;
int b_top = *b_runs++;
int b_bot = *b_runs++;
a_runs += 1; // skip the intervalCount;
b_runs += 1; // skip the intervalCount;
// Now a_runs and b_runs to their intervals (or sentinel)
assert_sentinel(a_top, false);
assert_sentinel(a_bot, false);
assert_sentinel(b_top, false);
assert_sentinel(b_bot, false);
RgnOper oper(SkMin32(a_top, b_top), dst, op);
int prevBot = SkRegion::kRunTypeSentinel; // so we fail the first test
while (a_bot < SkRegion::kRunTypeSentinel ||
b_bot < SkRegion::kRunTypeSentinel) {
int top, bot SK_INIT_TO_AVOID_WARNING;
const SkRegion::RunType* run0 = gSentinel;
const SkRegion::RunType* run1 = gSentinel;
bool a_flush = false;
bool b_flush = false;
if (a_top < b_top) {
top = a_top;
run0 = a_runs;
if (a_bot <= b_top) { // [...] <...>
bot = a_bot;
a_flush = true;
} else { // [...<..]...> or [...<...>...]
bot = a_top = b_top;
}
} else if (b_top < a_top) {
top = b_top;
run1 = b_runs;
if (b_bot <= a_top) { // [...] <...>
bot = b_bot;
b_flush = true;
} else { // [...<..]...> or [...<...>...]
bot = b_top = a_top;
}
} else { // a_top == b_top
top = a_top; // or b_top
run0 = a_runs;
run1 = b_runs;
if (a_bot <= b_bot) {
bot = b_top = a_bot;
a_flush = true;
}
if (b_bot <= a_bot) {
bot = a_top = b_bot;
b_flush = true;
}
}
if (top > prevBot) {
oper.addSpan(top, gSentinel, gSentinel);
}
oper.addSpan(bot, run0, run1);
if (quickExit && !oper.isEmpty()) {
return QUICK_EXIT_TRUE_COUNT;
}
if (a_flush) {
a_runs = skip_intervals(a_runs);
a_top = a_bot;
a_bot = *a_runs++;
a_runs += 1; // skip uninitialized intervalCount
if (a_bot == SkRegion::kRunTypeSentinel) {
a_top = a_bot;
}
}
if (b_flush) {
b_runs = skip_intervals(b_runs);
b_top = b_bot;
b_bot = *b_runs++;
b_runs += 1; // skip uninitialized intervalCount
if (b_bot == SkRegion::kRunTypeSentinel) {
b_top = b_bot;
}
}
prevBot = bot;
}
return oper.flush();
}
///////////////////////////////////////////////////////////////////////////////
/* Given count RunTypes in a complex region, return the worst case number of
logical intervals that represents (i.e. number of rects that would be
returned from the iterator).
We could just return count/2, since there must be at least 2 values per
interval, but we can first trim off the const overhead of the initial TOP
value, plus the final BOTTOM + 2 sentinels.
*/
#if 0 // UNUSED
static int count_to_intervals(int count) {
SkASSERT(count >= 6); // a single rect is 6 values
return (count - 4) >> 1;
}
#endif
/* Given a number of intervals, what is the worst case representation of that
many intervals?
Worst case (from a storage perspective), is a vertical stack of single
intervals: TOP + N * (BOTTOM INTERVALCOUNT LEFT RIGHT SENTINEL) + SENTINEL
*/
static int intervals_to_count(int intervals) {
return 1 + intervals * 5 + 1;
}
/* Given the intervalCounts of RunTypes in two regions, return the worst-case number
of RunTypes need to store the result after a region-op.
*/
static int compute_worst_case_count(int a_intervals, int b_intervals) {
// Our heuristic worst case is ai * (bi + 1) + bi * (ai + 1)
int intervals = 2 * a_intervals * b_intervals + a_intervals + b_intervals;
// convert back to number of RunType values
return intervals_to_count(intervals);
}
static bool setEmptyCheck(SkRegion* result) {
return result ? result->setEmpty() : false;
}
static bool setRectCheck(SkRegion* result, const SkIRect& rect) {
return result ? result->setRect(rect) : !rect.isEmpty();
}
static bool setRegionCheck(SkRegion* result, const SkRegion& rgn) {
return result ? result->setRegion(rgn) : !rgn.isEmpty();
}
bool SkRegion::Oper(const SkRegion& rgnaOrig, const SkRegion& rgnbOrig, Op op,
SkRegion* result) {
SkASSERT((unsigned)op < kOpCount);
if (kReplace_Op == op) {
return setRegionCheck(result, rgnbOrig);
}
// swith to using pointers, so we can swap them as needed
const SkRegion* rgna = &rgnaOrig;
const SkRegion* rgnb = &rgnbOrig;
// after this point, do not refer to rgnaOrig or rgnbOrig!!!
// collaps difference and reverse-difference into just difference
if (kReverseDifference_Op == op) {
SkTSwap<const SkRegion*>(rgna, rgnb);
op = kDifference_Op;
}
SkIRect bounds;
bool a_empty = rgna->isEmpty();
bool b_empty = rgnb->isEmpty();
bool a_rect = rgna->isRect();
bool b_rect = rgnb->isRect();
switch (op) {
case kDifference_Op:
if (a_empty) {
return setEmptyCheck(result);
}
if (b_empty || !SkIRect::IntersectsNoEmptyCheck(rgna->fBounds,
rgnb->fBounds)) {
return setRegionCheck(result, *rgna);
}
if (b_rect && rgnb->fBounds.containsNoEmptyCheck(rgna->fBounds)) {
return setEmptyCheck(result);
}
break;
case kIntersect_Op:
if ((a_empty | b_empty)
|| !bounds.intersect(rgna->fBounds, rgnb->fBounds)) {
return setEmptyCheck(result);
}
if (a_rect & b_rect) {
return setRectCheck(result, bounds);
}
if (a_rect && rgna->fBounds.contains(rgnb->fBounds)) {
return setRegionCheck(result, *rgnb);
}
if (b_rect && rgnb->fBounds.contains(rgna->fBounds)) {
return setRegionCheck(result, *rgna);
}
break;
case kUnion_Op:
if (a_empty) {
return setRegionCheck(result, *rgnb);
}
if (b_empty) {
return setRegionCheck(result, *rgna);
}
if (a_rect && rgna->fBounds.contains(rgnb->fBounds)) {
return setRegionCheck(result, *rgna);
}
if (b_rect && rgnb->fBounds.contains(rgna->fBounds)) {
return setRegionCheck(result, *rgnb);
}
break;
case kXOR_Op:
if (a_empty) {
return setRegionCheck(result, *rgnb);
}
if (b_empty) {
return setRegionCheck(result, *rgna);
}
break;
default:
SkDEBUGFAIL("unknown region op");
return false;
}
RunType tmpA[kRectRegionRuns];
RunType tmpB[kRectRegionRuns];
int a_intervals, b_intervals;
const RunType* a_runs = rgna->getRuns(tmpA, &a_intervals);
const RunType* b_runs = rgnb->getRuns(tmpB, &b_intervals);
int dstCount = compute_worst_case_count(a_intervals, b_intervals);
SkAutoSTMalloc<256, RunType> array(dstCount);
#ifdef SK_DEBUG
// Sometimes helpful to seed everything with a known value when debugging
// sk_memset32((uint32_t*)array.get(), 0x7FFFFFFF, dstCount);
#endif
int count = operate(a_runs, b_runs, array.get(), op, NULL == result);
SkASSERT(count <= dstCount);
if (result) {
SkASSERT(count >= 0);
return result->setRuns(array.get(), count);
} else {
return (QUICK_EXIT_TRUE_COUNT == count) || !isRunCountEmpty(count);
}
}
bool SkRegion::op(const SkRegion& rgna, const SkRegion& rgnb, Op op) {
SkDEBUGCODE(this->validate();)
return SkRegion::Oper(rgna, rgnb, op, this);
}
///////////////////////////////////////////////////////////////////////////////
#include "SkBuffer.h"
uint32_t SkRegion::writeToMemory(void* storage) const {
if (NULL == storage) {
uint32_t size = sizeof(int32_t); // -1 (empty), 0 (rect), runCount
if (!this->isEmpty()) {
size += sizeof(fBounds);
if (this->isComplex()) {
size += 2 * sizeof(int32_t); // ySpanCount + intervalCount
size += fRunHead->fRunCount * sizeof(RunType);
}
}
return size;
}
SkWBuffer buffer(storage);
if (this->isEmpty()) {
buffer.write32(-1);
} else {
bool isRect = this->isRect();
buffer.write32(isRect ? 0 : fRunHead->fRunCount);
buffer.write(&fBounds, sizeof(fBounds));
if (!isRect) {
buffer.write32(fRunHead->getYSpanCount());
buffer.write32(fRunHead->getIntervalCount());
buffer.write(fRunHead->readonly_runs(),
fRunHead->fRunCount * sizeof(RunType));
}
}
return buffer.pos();
}
uint32_t SkRegion::readFromMemory(const void* storage) {
SkRBuffer buffer(storage);
SkRegion tmp;
int32_t count;
count = buffer.readS32();
if (count >= 0) {
buffer.read(&tmp.fBounds, sizeof(tmp.fBounds));
if (count == 0) {
tmp.fRunHead = SkRegion_gRectRunHeadPtr;
} else {
int32_t ySpanCount = buffer.readS32();
int32_t intervalCount = buffer.readS32();
tmp.allocateRuns(count, ySpanCount, intervalCount);
buffer.read(tmp.fRunHead->writable_runs(), count * sizeof(RunType));
}
}
this->swap(tmp);
return buffer.pos();
}
///////////////////////////////////////////////////////////////////////////////
const SkRegion& SkRegion::GetEmptyRegion() {
static SkRegion gEmpty;
return gEmpty;
}
///////////////////////////////////////////////////////////////////////////////
#ifdef SK_DEBUG
// Starts with first X-interval, and returns a ptr to the X-sentinel
static const SkRegion::RunType* skip_intervals_slow(const SkRegion::RunType runs[]) {
// want to track that our intevals are all disjoint, such that
// prev-right < next-left. We rely on this optimization in places such as
// contains().
//
SkRegion::RunType prevR = -SkRegion::kRunTypeSentinel;
while (runs[0] < SkRegion::kRunTypeSentinel) {
SkASSERT(prevR < runs[0]);
SkASSERT(runs[0] < runs[1]);
SkASSERT(runs[1] < SkRegion::kRunTypeSentinel);
prevR = runs[1];
runs += 2;
}
return runs;
}
static void compute_bounds(const SkRegion::RunType runs[], int count,
SkIRect* bounds, int* ySpanCountPtr,
int* intervalCountPtr) {
assert_sentinel(runs[0], false); // top
int left = SK_MaxS32;
int rite = SK_MinS32;
int bot;
int ySpanCount = 0;
int intervalCount = 0;
bounds->fTop = *runs++;
do {
bot = *runs++;
SkASSERT(SkRegion::kRunTypeSentinel > bot);
ySpanCount += 1;
runs += 1; // skip intervalCount for now
if (*runs < SkRegion::kRunTypeSentinel) {
if (left > *runs) {
left = *runs;
}
const SkRegion::RunType* prev = runs;
runs = skip_intervals_slow(runs);
int intervals = (runs - prev) >> 1;
SkASSERT(prev[-1] == intervals);
intervalCount += intervals;
if (rite < runs[-1]) {
rite = runs[-1];
}
} else {
SkASSERT(0 == runs[-1]); // no intervals
}
SkASSERT(SkRegion::kRunTypeSentinel == *runs);
runs += 1;
} while (SkRegion::kRunTypeSentinel != *runs);
bounds->fLeft = left;
bounds->fRight = rite;
bounds->fBottom = bot;
*ySpanCountPtr = ySpanCount;
*intervalCountPtr = intervalCount;
}
void SkRegion::validate() const {
if (this->isEmpty()) {
// check for explicit empty (the zero rect), so we can compare rects to know when
// two regions are equal (i.e. emptyRectA == emptyRectB)
// this is stricter than just asserting fBounds.isEmpty()
SkASSERT(fBounds.fLeft == 0 && fBounds.fTop == 0 && fBounds.fRight == 0 && fBounds.fBottom == 0);
} else {
SkASSERT(!fBounds.isEmpty());
if (!this->isRect()) {
SkASSERT(fRunHead->fRefCnt >= 1);
SkASSERT(fRunHead->fRunCount > kRectRegionRuns);
const RunType* run = fRunHead->readonly_runs();
const RunType* stop = run + fRunHead->fRunCount;
// check that our bounds match our runs
{
SkIRect bounds;
int ySpanCount, intervalCount;
compute_bounds(run, stop - run, &bounds, &ySpanCount, &intervalCount);
SkASSERT(bounds == fBounds);
SkASSERT(ySpanCount > 0);
SkASSERT(fRunHead->getYSpanCount() == ySpanCount);
// SkASSERT(intervalCount > 1);
SkASSERT(fRunHead->getIntervalCount() == intervalCount);
}
}
}
}
void SkRegion::dump() const {
if (this->isEmpty()) {
SkDebugf(" rgn: empty\n");
} else {
SkDebugf(" rgn: [%d %d %d %d]", fBounds.fLeft, fBounds.fTop, fBounds.fRight, fBounds.fBottom);
if (this->isComplex()) {
const RunType* runs = fRunHead->readonly_runs();
for (int i = 0; i < fRunHead->fRunCount; i++)
SkDebugf(" %d", runs[i]);
}
SkDebugf("\n");
}
}
#endif
///////////////////////////////////////////////////////////////////////////////
SkRegion::Iterator::Iterator(const SkRegion& rgn) {
this->reset(rgn);
}
bool SkRegion::Iterator::rewind() {
if (fRgn) {
this->reset(*fRgn);
return true;
}
return false;
}
void SkRegion::Iterator::reset(const SkRegion& rgn) {
fRgn = &rgn;
if (rgn.isEmpty()) {
fDone = true;
} else {
fDone = false;
if (rgn.isRect()) {
fRect = rgn.fBounds;
fRuns = NULL;
} else {
fRuns = rgn.fRunHead->readonly_runs();
fRect.set(fRuns[3], fRuns[0], fRuns[4], fRuns[1]);
fRuns += 5;
// Now fRuns points to the 2nd interval (or x-sentinel)
}
}
}
void SkRegion::Iterator::next() {
if (fDone) {
return;
}
if (fRuns == NULL) { // rect case
fDone = true;
return;
}
const RunType* runs = fRuns;
if (runs[0] < kRunTypeSentinel) { // valid X value
fRect.fLeft = runs[0];
fRect.fRight = runs[1];
runs += 2;
} else { // we're at the end of a line
runs += 1;
if (runs[0] < kRunTypeSentinel) { // valid Y value
int intervals = runs[1];
if (0 == intervals) { // empty line
fRect.fTop = runs[0];
runs += 3;
} else {
fRect.fTop = fRect.fBottom;
}
fRect.fBottom = runs[0];
assert_sentinel(runs[2], false);
assert_sentinel(runs[3], false);
fRect.fLeft = runs[2];
fRect.fRight = runs[3];
runs += 4;
} else { // end of rgn
fDone = true;
}
}
fRuns = runs;
}
SkRegion::Cliperator::Cliperator(const SkRegion& rgn, const SkIRect& clip)
: fIter(rgn), fClip(clip), fDone(true) {
const SkIRect& r = fIter.rect();
while (!fIter.done()) {
if (r.fTop >= clip.fBottom) {
break;
}
if (fRect.intersect(clip, r)) {
fDone = false;
break;
}
fIter.next();
}
}
void SkRegion::Cliperator::next() {
if (fDone) {
return;
}
const SkIRect& r = fIter.rect();
fDone = true;
fIter.next();
while (!fIter.done()) {
if (r.fTop >= fClip.fBottom) {
break;
}
if (fRect.intersect(fClip, r)) {
fDone = false;
break;
}
fIter.next();
}
}
///////////////////////////////////////////////////////////////////////////////
SkRegion::Spanerator::Spanerator(const SkRegion& rgn, int y, int left,
int right) {
SkDEBUGCODE(rgn.validate();)
const SkIRect& r = rgn.getBounds();
fDone = true;
if (!rgn.isEmpty() && y >= r.fTop && y < r.fBottom &&
right > r.fLeft && left < r.fRight) {
if (rgn.isRect()) {
if (left < r.fLeft) {
left = r.fLeft;
}
if (right > r.fRight) {
right = r.fRight;
}
fLeft = left;
fRight = right;
fRuns = NULL; // means we're a rect, not a rgn
fDone = false;
} else {
const SkRegion::RunType* runs = rgn.fRunHead->findScanline(y);
runs += 2; // skip Bottom and IntervalCount
for (;;) {
// runs[0..1] is to the right of the span, so we're done
if (runs[0] >= right) {
break;
}
// runs[0..1] is to the left of the span, so continue
if (runs[1] <= left) {
runs += 2;
continue;
}
// runs[0..1] intersects the span
fRuns = runs;
fLeft = left;
fRight = right;
fDone = false;
break;
}
}
}
}
bool SkRegion::Spanerator::next(int* left, int* right) {
if (fDone) {
return false;
}
if (fRuns == NULL) { // we're a rect
fDone = true; // ok, now we're done
if (left) {
*left = fLeft;
}
if (right) {
*right = fRight;
}
return true; // this interval is legal
}
const SkRegion::RunType* runs = fRuns;
if (runs[0] >= fRight) {
fDone = true;
return false;
}
SkASSERT(runs[1] > fLeft);
if (left) {
*left = SkMax32(fLeft, runs[0]);
}
if (right) {
*right = SkMin32(fRight, runs[1]);
}
fRuns = runs + 2;
return true;
}
///////////////////////////////////////////////////////////////////////////////
#ifdef SK_DEBUG
bool SkRegion::debugSetRuns(const RunType runs[], int count) {
// we need to make a copy, since the real method may modify the array, and
// so it cannot be const.
SkAutoTArray<RunType> storage(count);
memcpy(storage.get(), runs, count * sizeof(RunType));
return this->setRuns(storage.get(), count);
}
#endif