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|
/*
* 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 <algorithm>
#include "Sk4fLinearGradient.h"
#include "SkColorSpace_XYZ.h"
#include "SkGradientShaderPriv.h"
#include "SkHalf.h"
#include "SkLinearGradient.h"
#include "SkMallocPixelRef.h"
#include "SkRadialGradient.h"
#include "SkSweepGradient.h"
#include "SkTwoPointConicalGradient.h"
#include "../../jumper/SkJumper.h"
enum GradientSerializationFlags {
// Bits 29:31 used for various boolean flags
kHasPosition_GSF = 0x80000000,
kHasLocalMatrix_GSF = 0x40000000,
kHasColorSpace_GSF = 0x20000000,
// Bits 12:28 unused
// Bits 8:11 for fTileMode
kTileModeShift_GSF = 8,
kTileModeMask_GSF = 0xF,
// Bits 0:7 for fGradFlags (note that kForce4fContext_PrivateFlag is 0x80)
kGradFlagsShift_GSF = 0,
kGradFlagsMask_GSF = 0xFF,
};
void SkGradientShaderBase::Descriptor::flatten(SkWriteBuffer& buffer) const {
uint32_t flags = 0;
if (fPos) {
flags |= kHasPosition_GSF;
}
if (fLocalMatrix) {
flags |= kHasLocalMatrix_GSF;
}
sk_sp<SkData> colorSpaceData = fColorSpace ? fColorSpace->serialize() : nullptr;
if (colorSpaceData) {
flags |= kHasColorSpace_GSF;
}
SkASSERT(static_cast<uint32_t>(fTileMode) <= kTileModeMask_GSF);
flags |= (fTileMode << kTileModeShift_GSF);
SkASSERT(fGradFlags <= kGradFlagsMask_GSF);
flags |= (fGradFlags << kGradFlagsShift_GSF);
buffer.writeUInt(flags);
buffer.writeColor4fArray(fColors, fCount);
if (colorSpaceData) {
buffer.writeDataAsByteArray(colorSpaceData.get());
}
if (fPos) {
buffer.writeScalarArray(fPos, fCount);
}
if (fLocalMatrix) {
buffer.writeMatrix(*fLocalMatrix);
}
}
bool SkGradientShaderBase::DescriptorScope::unflatten(SkReadBuffer& buffer) {
// New gradient format. Includes floating point color, color space, densely packed flags
uint32_t flags = buffer.readUInt();
fTileMode = (SkShader::TileMode)((flags >> kTileModeShift_GSF) & kTileModeMask_GSF);
fGradFlags = (flags >> kGradFlagsShift_GSF) & kGradFlagsMask_GSF;
fCount = buffer.getArrayCount();
if (fCount > kStorageCount) {
size_t allocSize = (sizeof(SkColor4f) + sizeof(SkScalar)) * fCount;
fDynamicStorage.reset(allocSize);
fColors = (SkColor4f*)fDynamicStorage.get();
fPos = (SkScalar*)(fColors + fCount);
} else {
fColors = fColorStorage;
fPos = fPosStorage;
}
if (!buffer.readColor4fArray(mutableColors(), fCount)) {
return false;
}
if (SkToBool(flags & kHasColorSpace_GSF)) {
sk_sp<SkData> data = buffer.readByteArrayAsData();
fColorSpace = SkColorSpace::Deserialize(data->data(), data->size());
} else {
fColorSpace = nullptr;
}
if (SkToBool(flags & kHasPosition_GSF)) {
if (!buffer.readScalarArray(mutablePos(), fCount)) {
return false;
}
} else {
fPos = nullptr;
}
if (SkToBool(flags & kHasLocalMatrix_GSF)) {
fLocalMatrix = &fLocalMatrixStorage;
buffer.readMatrix(&fLocalMatrixStorage);
} else {
fLocalMatrix = nullptr;
}
return buffer.isValid();
}
////////////////////////////////////////////////////////////////////////////////////////////
SkGradientShaderBase::SkGradientShaderBase(const Descriptor& desc, const SkMatrix& ptsToUnit)
: INHERITED(desc.fLocalMatrix)
, fPtsToUnit(ptsToUnit)
{
fPtsToUnit.getType(); // Precache so reads are threadsafe.
SkASSERT(desc.fCount > 1);
fGradFlags = static_cast<uint8_t>(desc.fGradFlags);
SkASSERT((unsigned)desc.fTileMode < SkShader::kTileModeCount);
SkASSERT(SkShader::kTileModeCount == SK_ARRAY_COUNT(gTileProcs));
fTileMode = desc.fTileMode;
fTileProc = gTileProcs[desc.fTileMode];
/* Note: we let the caller skip the first and/or last position.
i.e. pos[0] = 0.3, pos[1] = 0.7
In these cases, we insert dummy entries to ensure that the final data
will be bracketed by [0, 1].
i.e. our_pos[0] = 0, our_pos[1] = 0.3, our_pos[2] = 0.7, our_pos[3] = 1
Thus colorCount (the caller's value, and fColorCount (our value) may
differ by up to 2. In the above example:
colorCount = 2
fColorCount = 4
*/
fColorCount = desc.fCount;
// check if we need to add in dummy start and/or end position/colors
bool dummyFirst = false;
bool dummyLast = false;
if (desc.fPos) {
dummyFirst = desc.fPos[0] != 0;
dummyLast = desc.fPos[desc.fCount - 1] != SK_Scalar1;
fColorCount += dummyFirst + dummyLast;
}
if (fColorCount > kColorStorageCount) {
size_t size = sizeof(SkColor) + sizeof(SkColor4f) + sizeof(Rec);
if (desc.fPos) {
size += sizeof(SkScalar);
}
fOrigColors = reinterpret_cast<SkColor*>(sk_malloc_throw(size * fColorCount));
}
else {
fOrigColors = fStorage;
}
fOrigColors4f = (SkColor4f*)(fOrigColors + fColorCount);
// Now copy over the colors, adding the dummies as needed
SkColor4f* origColors = fOrigColors4f;
if (dummyFirst) {
*origColors++ = desc.fColors[0];
}
memcpy(origColors, desc.fColors, desc.fCount * sizeof(SkColor4f));
if (dummyLast) {
origColors += desc.fCount;
*origColors = desc.fColors[desc.fCount - 1];
}
// Convert our SkColor4f colors to SkColor as well. Note that this is incorrect if the
// source colors are not in sRGB gamut. We would need to do a gamut transformation, but
// SkColorSpaceXform can't do that (yet). GrColorSpaceXform can, but we may not have GPU
// support compiled in here. For the common case (sRGB colors), this does the right thing.
for (int i = 0; i < fColorCount; ++i) {
fOrigColors[i] = fOrigColors4f[i].toSkColor();
}
if (!desc.fColorSpace) {
// This happens if we were constructed from SkColors, so our colors are really sRGB
fColorSpace = SkColorSpace::MakeSRGBLinear();
} else {
// The color space refers to the float colors, so it must be linear gamma
SkASSERT(desc.fColorSpace->gammaIsLinear());
fColorSpace = desc.fColorSpace;
}
if (desc.fPos && fColorCount) {
fOrigPos = (SkScalar*)(fOrigColors4f + fColorCount);
fRecs = (Rec*)(fOrigPos + fColorCount);
} else {
fOrigPos = nullptr;
fRecs = (Rec*)(fOrigColors4f + fColorCount);
}
if (fColorCount > 2) {
Rec* recs = fRecs;
recs->fPos = 0;
// recs->fScale = 0; // unused;
recs += 1;
if (desc.fPos) {
SkScalar* origPosPtr = fOrigPos;
*origPosPtr++ = 0;
/* We need to convert the user's array of relative positions into
fixed-point positions and scale factors. We need these results
to be strictly monotonic (no two values equal or out of order).
Hence this complex loop that just jams a zero for the scale
value if it sees a segment out of order, and it assures that
we start at 0 and end at 1.0
*/
SkScalar prev = 0;
int startIndex = dummyFirst ? 0 : 1;
int count = desc.fCount + dummyLast;
for (int i = startIndex; i < count; i++) {
// force the last value to be 1.0
SkScalar curr;
if (i == desc.fCount) { // we're really at the dummyLast
curr = 1;
} else {
curr = SkScalarPin(desc.fPos[i], 0, 1);
}
*origPosPtr++ = curr;
recs->fPos = SkScalarToFixed(curr);
SkFixed diff = SkScalarToFixed(curr - prev);
if (diff > 0) {
recs->fScale = (1 << 24) / diff;
} else {
recs->fScale = 0; // ignore this segment
}
// get ready for the next value
prev = curr;
recs += 1;
}
} else { // assume even distribution
fOrigPos = nullptr;
SkFixed dp = SK_Fixed1 / (desc.fCount - 1);
SkFixed p = dp;
SkFixed scale = (desc.fCount - 1) << 8; // (1 << 24) / dp
for (int i = 1; i < desc.fCount - 1; i++) {
recs->fPos = p;
recs->fScale = scale;
recs += 1;
p += dp;
}
recs->fPos = SK_Fixed1;
recs->fScale = scale;
}
} else if (desc.fPos) {
SkASSERT(2 == fColorCount);
fOrigPos[0] = SkScalarPin(desc.fPos[0], 0, 1);
fOrigPos[1] = SkScalarPin(desc.fPos[1], fOrigPos[0], 1);
if (0 == fOrigPos[0] && 1 == fOrigPos[1]) {
fOrigPos = nullptr;
}
}
this->initCommon();
}
SkGradientShaderBase::~SkGradientShaderBase() {
if (fOrigColors != fStorage) {
sk_free(fOrigColors);
}
}
void SkGradientShaderBase::initCommon() {
unsigned colorAlpha = 0xFF;
for (int i = 0; i < fColorCount; i++) {
colorAlpha &= SkColorGetA(fOrigColors[i]);
}
fColorsAreOpaque = colorAlpha == 0xFF;
}
void SkGradientShaderBase::flatten(SkWriteBuffer& buffer) const {
Descriptor desc;
desc.fColors = fOrigColors4f;
desc.fColorSpace = fColorSpace;
desc.fPos = fOrigPos;
desc.fCount = fColorCount;
desc.fTileMode = fTileMode;
desc.fGradFlags = fGradFlags;
const SkMatrix& m = this->getLocalMatrix();
desc.fLocalMatrix = m.isIdentity() ? nullptr : &m;
desc.flatten(buffer);
}
void SkGradientShaderBase::FlipGradientColors(SkColor* colorDst, Rec* recDst,
SkColor* colorSrc, Rec* recSrc,
int count) {
SkAutoSTArray<8, SkColor> colorsTemp(count);
for (int i = 0; i < count; ++i) {
int offset = count - i - 1;
colorsTemp[i] = colorSrc[offset];
}
if (count > 2) {
SkAutoSTArray<8, Rec> recsTemp(count);
for (int i = 0; i < count; ++i) {
int offset = count - i - 1;
recsTemp[i].fPos = SK_Fixed1 - recSrc[offset].fPos;
recsTemp[i].fScale = recSrc[offset].fScale;
}
memcpy(recDst, recsTemp.get(), count * sizeof(Rec));
}
memcpy(colorDst, colorsTemp.get(), count * sizeof(SkColor));
}
static void add_stop_color(SkJumper_GradientCtx* ctx, size_t stop, SkPM4f Fs, SkPM4f Bs) {
(ctx->fs[0])[stop] = Fs.r();
(ctx->fs[1])[stop] = Fs.g();
(ctx->fs[2])[stop] = Fs.b();
(ctx->fs[3])[stop] = Fs.a();
(ctx->bs[0])[stop] = Bs.r();
(ctx->bs[1])[stop] = Bs.g();
(ctx->bs[2])[stop] = Bs.b();
(ctx->bs[3])[stop] = Bs.a();
}
static void add_const_color(SkJumper_GradientCtx* ctx, size_t stop, SkPM4f color) {
add_stop_color(ctx, stop, SkPM4f::FromPremulRGBA(0,0,0,0), color);
}
// Calculate a factor F and a bias B so that color = F*t + B when t is in range of
// the stop. Assume that the distance between stops is 1/gapCount.
static void init_stop_evenly(
SkJumper_GradientCtx* ctx, float gapCount, size_t stop, SkPM4f c_l, SkPM4f c_r) {
// Clankium's GCC 4.9 targeting ARMv7 is barfing when we use Sk4f math here, so go scalar...
SkPM4f Fs = {{
(c_r.r() - c_l.r()) * gapCount,
(c_r.g() - c_l.g()) * gapCount,
(c_r.b() - c_l.b()) * gapCount,
(c_r.a() - c_l.a()) * gapCount,
}};
SkPM4f Bs = {{
c_l.r() - Fs.r()*(stop/gapCount),
c_l.g() - Fs.g()*(stop/gapCount),
c_l.b() - Fs.b()*(stop/gapCount),
c_l.a() - Fs.a()*(stop/gapCount),
}};
add_stop_color(ctx, stop, Fs, Bs);
}
// For each stop we calculate a bias B and a scale factor F, such that
// for any t between stops n and n+1, the color we want is B[n] + F[n]*t.
static void init_stop_pos(
SkJumper_GradientCtx* ctx, size_t stop, float t_l, float t_r, SkPM4f c_l, SkPM4f c_r) {
// See note about Clankium's old compiler in init_stop_evenly().
SkPM4f Fs = {{
(c_r.r() - c_l.r()) / (t_r - t_l),
(c_r.g() - c_l.g()) / (t_r - t_l),
(c_r.b() - c_l.b()) / (t_r - t_l),
(c_r.a() - c_l.a()) / (t_r - t_l),
}};
SkPM4f Bs = {{
c_l.r() - Fs.r()*t_l,
c_l.g() - Fs.g()*t_l,
c_l.b() - Fs.b()*t_l,
c_l.a() - Fs.a()*t_l,
}};
ctx->ts[stop] = t_l;
add_stop_color(ctx, stop, Fs, Bs);
}
bool SkGradientShaderBase::onAppendStages(const StageRec& rec) const {
SkRasterPipeline* p = rec.fPipeline;
SkArenaAlloc* alloc = rec.fAlloc;
SkColorSpace* dstCS = rec.fDstCS;
SkMatrix matrix;
if (!this->computeTotalInverse(rec.fCTM, rec.fLocalM, &matrix)) {
return false;
}
matrix.postConcat(fPtsToUnit);
SkRasterPipeline_<256> postPipeline;
p->append(SkRasterPipeline::seed_shader);
p->append_matrix(alloc, matrix);
this->appendGradientStages(alloc, p, &postPipeline);
switch(fTileMode) {
case kMirror_TileMode: p->append(SkRasterPipeline::mirror_x_1); break;
case kRepeat_TileMode: p->append(SkRasterPipeline::repeat_x_1); break;
case kClamp_TileMode:
if (!fOrigPos) {
// We clamp only when the stops are evenly spaced.
// If not, there may be hard stops, and clamping ruins hard stops at 0 and/or 1.
// In that case, we must make sure we're using the general "gradient" stage,
// which is the only stage that will correctly handle unclamped t.
p->append(SkRasterPipeline::clamp_x_1);
}
}
const bool premulGrad = fGradFlags & SkGradientShader::kInterpolateColorsInPremul_Flag;
auto prepareColor = [premulGrad, dstCS, this](int i) {
SkColor4f c = this->getXformedColor(i, dstCS);
return premulGrad ? c.premul()
: SkPM4f::From4f(Sk4f::Load(&c));
};
// The two-stop case with stops at 0 and 1.
if (fColorCount == 2 && fOrigPos == nullptr) {
const SkPM4f c_l = prepareColor(0),
c_r = prepareColor(1);
// See F and B below.
auto* f_and_b = alloc->makeArrayDefault<SkPM4f>(2);
f_and_b[0] = SkPM4f::From4f(c_r.to4f() - c_l.to4f());
f_and_b[1] = c_l;
p->append(SkRasterPipeline::evenly_spaced_2_stop_gradient, f_and_b);
} else {
auto* ctx = alloc->make<SkJumper_GradientCtx>();
// Note: In order to handle clamps in search, the search assumes a stop conceptully placed
// at -inf. Therefore, the max number of stops is fColorCount+1.
for (int i = 0; i < 4; i++) {
// Allocate at least at for the AVX2 gather from a YMM register.
ctx->fs[i] = alloc->makeArray<float>(std::max(fColorCount+1, 8));
ctx->bs[i] = alloc->makeArray<float>(std::max(fColorCount+1, 8));
}
if (fOrigPos == nullptr) {
// Handle evenly distributed stops.
size_t stopCount = fColorCount;
float gapCount = stopCount - 1;
SkPM4f c_l = prepareColor(0);
for (size_t i = 0; i < stopCount - 1; i++) {
SkPM4f c_r = prepareColor(i + 1);
init_stop_evenly(ctx, gapCount, i, c_l, c_r);
c_l = c_r;
}
add_const_color(ctx, stopCount - 1, c_l);
ctx->stopCount = stopCount;
p->append(SkRasterPipeline::evenly_spaced_gradient, ctx);
} else {
// Handle arbitrary stops.
ctx->ts = alloc->makeArray<float>(fColorCount+1);
// Remove the dummy stops inserted by SkGradientShaderBase::SkGradientShaderBase
// because they are naturally handled by the search method.
int firstStop;
int lastStop;
if (fColorCount > 2) {
firstStop = fOrigColors4f[0] != fOrigColors4f[1] ? 0 : 1;
lastStop = fOrigColors4f[fColorCount - 2] != fOrigColors4f[fColorCount - 1]
? fColorCount - 1 : fColorCount - 2;
} else {
firstStop = 0;
lastStop = 1;
}
size_t stopCount = 0;
float t_l = fOrigPos[firstStop];
SkPM4f c_l = prepareColor(firstStop);
add_const_color(ctx, stopCount++, c_l);
// N.B. lastStop is the index of the last stop, not one after.
for (int i = firstStop; i < lastStop; i++) {
float t_r = fOrigPos[i + 1];
SkPM4f c_r = prepareColor(i + 1);
if (t_l < t_r) {
init_stop_pos(ctx, stopCount, t_l, t_r, c_l, c_r);
stopCount += 1;
}
t_l = t_r;
c_l = c_r;
}
ctx->ts[stopCount] = t_l;
add_const_color(ctx, stopCount++, c_l);
ctx->stopCount = stopCount;
p->append(SkRasterPipeline::gradient, ctx);
}
}
if (!premulGrad && !this->colorsAreOpaque()) {
p->append(SkRasterPipeline::premul);
}
p->extend(postPipeline);
return true;
}
bool SkGradientShaderBase::isOpaque() const {
return fColorsAreOpaque;
}
static unsigned rounded_divide(unsigned numer, unsigned denom) {
return (numer + (denom >> 1)) / denom;
}
bool SkGradientShaderBase::onAsLuminanceColor(SkColor* lum) const {
// we just compute an average color.
// possibly we could weight this based on the proportional width for each color
// assuming they are not evenly distributed in the fPos array.
int r = 0;
int g = 0;
int b = 0;
const int n = fColorCount;
for (int i = 0; i < n; ++i) {
SkColor c = fOrigColors[i];
r += SkColorGetR(c);
g += SkColorGetG(c);
b += SkColorGetB(c);
}
*lum = SkColorSetRGB(rounded_divide(r, n), rounded_divide(g, n), rounded_divide(b, n));
return true;
}
SkGradientShaderBase::GradientShaderBaseContext::GradientShaderBaseContext(
const SkGradientShaderBase& shader, const ContextRec& rec)
: INHERITED(shader, rec)
#ifdef SK_SUPPORT_LEGACY_GRADIENT_DITHERING
, fDither(true)
#else
, fDither(rec.fPaint->isDither())
#endif
, fCache(shader.refCache(getPaintAlpha(), fDither))
{
const SkMatrix& inverse = this->getTotalInverse();
fDstToIndex.setConcat(shader.fPtsToUnit, inverse);
SkASSERT(!fDstToIndex.hasPerspective());
fDstToIndexProc = fDstToIndex.getMapXYProc();
// now convert our colors in to PMColors
unsigned paintAlpha = this->getPaintAlpha();
fFlags = this->INHERITED::getFlags();
if (shader.fColorsAreOpaque && paintAlpha == 0xFF) {
fFlags |= kOpaqueAlpha_Flag;
}
}
bool SkGradientShaderBase::GradientShaderBaseContext::isValid() const {
return fDstToIndex.isFinite();
}
SkGradientShaderBase::GradientShaderCache::GradientShaderCache(
U8CPU alpha, bool dither, const SkGradientShaderBase& shader)
: fCacheAlpha(alpha)
, fCacheDither(dither)
, fShader(shader)
{
// Only initialize the cache in getCache32.
fCache32 = nullptr;
}
SkGradientShaderBase::GradientShaderCache::~GradientShaderCache() {}
/*
* r,g,b used to be SkFixed, but on gcc (4.2.1 mac and 4.6.3 goobuntu) in
* release builds, we saw a compiler error where the 0xFF parameter in
* SkPackARGB32() was being totally ignored whenever it was called with
* a non-zero add (e.g. 0x8000).
*
* We found two work-arounds:
* 1. change r,g,b to unsigned (or just one of them)
* 2. change SkPackARGB32 to + its (a << SK_A32_SHIFT) value instead
* of using |
*
* We chose #1 just because it was more localized.
* See http://code.google.com/p/skia/issues/detail?id=1113
*
* The type SkUFixed encapsulate this need for unsigned, but logically Fixed.
*/
typedef uint32_t SkUFixed;
void SkGradientShaderBase::GradientShaderCache::Build32bitCache(
SkPMColor cache[], SkColor c0, SkColor c1,
int count, U8CPU paintAlpha, uint32_t gradFlags, bool dither) {
SkASSERT(count > 1);
// need to apply paintAlpha to our two endpoints
uint32_t a0 = SkMulDiv255Round(SkColorGetA(c0), paintAlpha);
uint32_t a1 = SkMulDiv255Round(SkColorGetA(c1), paintAlpha);
const bool interpInPremul = SkToBool(gradFlags &
SkGradientShader::kInterpolateColorsInPremul_Flag);
uint32_t r0 = SkColorGetR(c0);
uint32_t g0 = SkColorGetG(c0);
uint32_t b0 = SkColorGetB(c0);
uint32_t r1 = SkColorGetR(c1);
uint32_t g1 = SkColorGetG(c1);
uint32_t b1 = SkColorGetB(c1);
if (interpInPremul) {
r0 = SkMulDiv255Round(r0, a0);
g0 = SkMulDiv255Round(g0, a0);
b0 = SkMulDiv255Round(b0, a0);
r1 = SkMulDiv255Round(r1, a1);
g1 = SkMulDiv255Round(g1, a1);
b1 = SkMulDiv255Round(b1, a1);
}
SkFixed da = SkIntToFixed(a1 - a0) / (count - 1);
SkFixed dr = SkIntToFixed(r1 - r0) / (count - 1);
SkFixed dg = SkIntToFixed(g1 - g0) / (count - 1);
SkFixed db = SkIntToFixed(b1 - b0) / (count - 1);
/* We pre-add 1/8 to avoid having to add this to our [0] value each time
in the loop. Without this, the bias for each would be
0x2000 0xA000 0xE000 0x6000
With this trick, we can add 0 for the first (no-op) and just adjust the
others.
*/
const SkUFixed bias0 = dither ? 0x2000 : 0x8000;
const SkUFixed bias1 = dither ? 0x8000 : 0;
const SkUFixed bias2 = dither ? 0xC000 : 0;
const SkUFixed bias3 = dither ? 0x4000 : 0;
SkUFixed a = SkIntToFixed(a0) + bias0;
SkUFixed r = SkIntToFixed(r0) + bias0;
SkUFixed g = SkIntToFixed(g0) + bias0;
SkUFixed b = SkIntToFixed(b0) + bias0;
/*
* Our dither-cell (spatially) is
* 0 2
* 3 1
* Where
* [0] -> [-1/8 ... 1/8 ) values near 0
* [1] -> [ 1/8 ... 3/8 ) values near 1/4
* [2] -> [ 3/8 ... 5/8 ) values near 1/2
* [3] -> [ 5/8 ... 7/8 ) values near 3/4
*/
if (0xFF == a0 && 0 == da) {
do {
cache[kCache32Count*0] = SkPackARGB32(0xFF, (r + 0 ) >> 16,
(g + 0 ) >> 16,
(b + 0 ) >> 16);
cache[kCache32Count*1] = SkPackARGB32(0xFF, (r + bias1) >> 16,
(g + bias1) >> 16,
(b + bias1) >> 16);
cache[kCache32Count*2] = SkPackARGB32(0xFF, (r + bias2) >> 16,
(g + bias2) >> 16,
(b + bias2) >> 16);
cache[kCache32Count*3] = SkPackARGB32(0xFF, (r + bias3) >> 16,
(g + bias3) >> 16,
(b + bias3) >> 16);
cache += 1;
r += dr;
g += dg;
b += db;
} while (--count != 0);
} else if (interpInPremul) {
do {
cache[kCache32Count*0] = SkPackARGB32((a + 0 ) >> 16,
(r + 0 ) >> 16,
(g + 0 ) >> 16,
(b + 0 ) >> 16);
cache[kCache32Count*1] = SkPackARGB32((a + bias1) >> 16,
(r + bias1) >> 16,
(g + bias1) >> 16,
(b + bias1) >> 16);
cache[kCache32Count*2] = SkPackARGB32((a + bias2) >> 16,
(r + bias2) >> 16,
(g + bias2) >> 16,
(b + bias2) >> 16);
cache[kCache32Count*3] = SkPackARGB32((a + bias3) >> 16,
(r + bias3) >> 16,
(g + bias3) >> 16,
(b + bias3) >> 16);
cache += 1;
a += da;
r += dr;
g += dg;
b += db;
} while (--count != 0);
} else { // interpolate in unpreml space
do {
cache[kCache32Count*0] = SkPremultiplyARGBInline((a + 0 ) >> 16,
(r + 0 ) >> 16,
(g + 0 ) >> 16,
(b + 0 ) >> 16);
cache[kCache32Count*1] = SkPremultiplyARGBInline((a + bias1) >> 16,
(r + bias1) >> 16,
(g + bias1) >> 16,
(b + bias1) >> 16);
cache[kCache32Count*2] = SkPremultiplyARGBInline((a + bias2) >> 16,
(r + bias2) >> 16,
(g + bias2) >> 16,
(b + bias2) >> 16);
cache[kCache32Count*3] = SkPremultiplyARGBInline((a + bias3) >> 16,
(r + bias3) >> 16,
(g + bias3) >> 16,
(b + bias3) >> 16);
cache += 1;
a += da;
r += dr;
g += dg;
b += db;
} while (--count != 0);
}
}
static inline int SkFixedToFFFF(SkFixed x) {
SkASSERT((unsigned)x <= SK_Fixed1);
return x - (x >> 16);
}
const SkPMColor* SkGradientShaderBase::GradientShaderCache::getCache32() {
fCache32InitOnce(SkGradientShaderBase::GradientShaderCache::initCache32, this);
SkASSERT(fCache32);
return fCache32;
}
void SkGradientShaderBase::GradientShaderCache::initCache32(GradientShaderCache* cache) {
const int kNumberOfDitherRows = 4;
const SkImageInfo info = SkImageInfo::MakeN32Premul(kCache32Count, kNumberOfDitherRows);
SkASSERT(nullptr == cache->fCache32PixelRef);
cache->fCache32PixelRef = SkMallocPixelRef::MakeAllocate(info, 0);
cache->fCache32 = (SkPMColor*)cache->fCache32PixelRef->pixels();
if (cache->fShader.fColorCount == 2) {
Build32bitCache(cache->fCache32, cache->fShader.fOrigColors[0],
cache->fShader.fOrigColors[1], kCache32Count, cache->fCacheAlpha,
cache->fShader.fGradFlags, cache->fCacheDither);
} else {
Rec* rec = cache->fShader.fRecs;
int prevIndex = 0;
for (int i = 1; i < cache->fShader.fColorCount; i++) {
int nextIndex = SkFixedToFFFF(rec[i].fPos) >> kCache32Shift;
SkASSERT(nextIndex < kCache32Count);
if (nextIndex > prevIndex)
Build32bitCache(cache->fCache32 + prevIndex, cache->fShader.fOrigColors[i-1],
cache->fShader.fOrigColors[i], nextIndex - prevIndex + 1,
cache->fCacheAlpha, cache->fShader.fGradFlags, cache->fCacheDither);
prevIndex = nextIndex;
}
}
}
void SkGradientShaderBase::initLinearBitmap(SkBitmap* bitmap) const {
const bool interpInPremul = SkToBool(fGradFlags &
SkGradientShader::kInterpolateColorsInPremul_Flag);
SkHalf* pixelsF16 = reinterpret_cast<SkHalf*>(bitmap->getPixels());
uint32_t* pixelsS32 = reinterpret_cast<uint32_t*>(bitmap->getPixels());
typedef std::function<void(const Sk4f&, int)> pixelWriteFn_t;
pixelWriteFn_t writeF16Pixel = [&](const Sk4f& x, int index) {
Sk4h c = SkFloatToHalf_finite_ftz(x);
pixelsF16[4*index+0] = c[0];
pixelsF16[4*index+1] = c[1];
pixelsF16[4*index+2] = c[2];
pixelsF16[4*index+3] = c[3];
};
pixelWriteFn_t writeS32Pixel = [&](const Sk4f& c, int index) {
pixelsS32[index] = Sk4f_toS32(c);
};
pixelWriteFn_t writeSizedPixel =
(kRGBA_F16_SkColorType == bitmap->colorType()) ? writeF16Pixel : writeS32Pixel;
pixelWriteFn_t writeUnpremulPixel = [&](const Sk4f& c, int index) {
writeSizedPixel(c * Sk4f(c[3], c[3], c[3], 1.0f), index);
};
pixelWriteFn_t writePixel = interpInPremul ? writeSizedPixel : writeUnpremulPixel;
int prevIndex = 0;
for (int i = 1; i < fColorCount; i++) {
int nextIndex = (fColorCount == 2) ? (kCache32Count - 1)
: SkFixedToFFFF(fRecs[i].fPos) >> kCache32Shift;
SkASSERT(nextIndex < kCache32Count);
if (nextIndex > prevIndex) {
Sk4f c0 = Sk4f::Load(fOrigColors4f[i - 1].vec());
Sk4f c1 = Sk4f::Load(fOrigColors4f[i].vec());
if (interpInPremul) {
c0 = c0 * Sk4f(c0[3], c0[3], c0[3], 1.0f);
c1 = c1 * Sk4f(c1[3], c1[3], c1[3], 1.0f);
}
Sk4f step = Sk4f(1.0f / static_cast<float>(nextIndex - prevIndex));
Sk4f delta = (c1 - c0) * step;
for (int curIndex = prevIndex; curIndex <= nextIndex; ++curIndex) {
writePixel(c0, curIndex);
c0 += delta;
}
}
prevIndex = nextIndex;
}
SkASSERT(prevIndex == kCache32Count - 1);
}
/*
* The gradient holds a cache for the most recent value of alpha. Successive
* callers with the same alpha value will share the same cache.
*/
sk_sp<SkGradientShaderBase::GradientShaderCache> SkGradientShaderBase::refCache(U8CPU alpha,
bool dither) const {
SkAutoMutexAcquire ama(fCacheMutex);
if (!fCache || fCache->getAlpha() != alpha || fCache->getDither() != dither) {
fCache.reset(new GradientShaderCache(alpha, dither, *this));
}
// Increment the ref counter inside the mutex to ensure the returned pointer is still valid.
// Otherwise, the pointer may have been overwritten on a different thread before the object's
// ref count was incremented.
return fCache;
}
SkColor4f SkGradientShaderBase::getXformedColor(size_t i, SkColorSpace* dstCS) const {
return dstCS ? to_colorspace(fOrigColors4f[i], fColorSpace.get(), dstCS)
: SkColor4f_from_SkColor(fOrigColors[i], nullptr);
}
SK_DECLARE_STATIC_MUTEX(gGradientCacheMutex);
/*
* Because our caller might rebuild the same (logically the same) gradient
* over and over, we'd like to return exactly the same "bitmap" if possible,
* allowing the client to utilize a cache of our bitmap (e.g. with a GPU).
* To do that, we maintain a private cache of built-bitmaps, based on our
* colors and positions. Note: we don't try to flatten the fMapper, so if one
* is present, we skip the cache for now.
*/
void SkGradientShaderBase::getGradientTableBitmap(SkBitmap* bitmap,
GradientBitmapType bitmapType) const {
// our caller assumes no external alpha, so we ensure that our cache is built with 0xFF
sk_sp<GradientShaderCache> cache(this->refCache(0xFF, true));
// build our key: [numColors + colors[] + {positions[]} + flags + colorType ]
int count = 1 + fColorCount + 1 + 1;
if (fColorCount > 2) {
count += fColorCount - 1; // fRecs[].fPos
}
SkAutoSTMalloc<16, int32_t> storage(count);
int32_t* buffer = storage.get();
*buffer++ = fColorCount;
memcpy(buffer, fOrigColors, fColorCount * sizeof(SkColor));
buffer += fColorCount;
if (fColorCount > 2) {
for (int i = 1; i < fColorCount; i++) {
*buffer++ = fRecs[i].fPos;
}
}
*buffer++ = fGradFlags;
*buffer++ = static_cast<int32_t>(bitmapType);
SkASSERT(buffer - storage.get() == count);
///////////////////////////////////
static SkGradientBitmapCache* gCache;
// each cache cost 1K or 2K of RAM, since each bitmap will be 1x256 at either 32bpp or 64bpp
static const int MAX_NUM_CACHED_GRADIENT_BITMAPS = 32;
SkAutoMutexAcquire ama(gGradientCacheMutex);
if (nullptr == gCache) {
gCache = new SkGradientBitmapCache(MAX_NUM_CACHED_GRADIENT_BITMAPS);
}
size_t size = count * sizeof(int32_t);
if (!gCache->find(storage.get(), size, bitmap)) {
if (GradientBitmapType::kLegacy == bitmapType) {
// force our cache32pixelref to be built
(void)cache->getCache32();
bitmap->setInfo(SkImageInfo::MakeN32Premul(kCache32Count, 1));
bitmap->setPixelRef(sk_ref_sp(cache->getCache32PixelRef()), 0, 0);
} else {
// For these cases we use the bitmap cache, but not the GradientShaderCache. So just
// allocate and populate the bitmap's data directly.
SkImageInfo info;
switch (bitmapType) {
case GradientBitmapType::kSRGB:
info = SkImageInfo::Make(kCache32Count, 1, kRGBA_8888_SkColorType,
kPremul_SkAlphaType,
SkColorSpace::MakeSRGB());
break;
case GradientBitmapType::kHalfFloat:
info = SkImageInfo::Make(
kCache32Count, 1, kRGBA_F16_SkColorType, kPremul_SkAlphaType,
SkColorSpace::MakeSRGBLinear());
break;
default:
SK_ABORT("Unexpected bitmap type");
return;
}
bitmap->allocPixels(info);
this->initLinearBitmap(bitmap);
}
gCache->add(storage.get(), size, *bitmap);
}
}
void SkGradientShaderBase::commonAsAGradient(GradientInfo* info, bool flipGrad) const {
if (info) {
if (info->fColorCount >= fColorCount) {
SkColor* colorLoc;
Rec* recLoc;
SkAutoSTArray<8, SkColor> colorStorage;
SkAutoSTArray<8, Rec> recStorage;
if (flipGrad && (info->fColors || info->fColorOffsets)) {
colorStorage.reset(fColorCount);
recStorage.reset(fColorCount);
colorLoc = colorStorage.get();
recLoc = recStorage.get();
FlipGradientColors(colorLoc, recLoc, fOrigColors, fRecs, fColorCount);
} else {
colorLoc = fOrigColors;
recLoc = fRecs;
}
if (info->fColors) {
memcpy(info->fColors, colorLoc, fColorCount * sizeof(SkColor));
}
if (info->fColorOffsets) {
if (fColorCount == 2) {
info->fColorOffsets[0] = 0;
info->fColorOffsets[1] = SK_Scalar1;
} else if (fColorCount > 2) {
for (int i = 0; i < fColorCount; ++i) {
info->fColorOffsets[i] = SkFixedToScalar(recLoc[i].fPos);
}
}
}
}
info->fColorCount = fColorCount;
info->fTileMode = fTileMode;
info->fGradientFlags = fGradFlags;
}
}
#ifndef SK_IGNORE_TO_STRING
void SkGradientShaderBase::toString(SkString* str) const {
str->appendf("%d colors: ", fColorCount);
for (int i = 0; i < fColorCount; ++i) {
str->appendHex(fOrigColors[i], 8);
if (i < fColorCount-1) {
str->append(", ");
}
}
if (fColorCount > 2) {
str->append(" points: (");
for (int i = 0; i < fColorCount; ++i) {
str->appendScalar(SkFixedToScalar(fRecs[i].fPos));
if (i < fColorCount-1) {
str->append(", ");
}
}
str->append(")");
}
static const char* gTileModeName[SkShader::kTileModeCount] = {
"clamp", "repeat", "mirror"
};
str->append(" ");
str->append(gTileModeName[fTileMode]);
this->INHERITED::toString(str);
}
#endif
///////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////
// Return true if these parameters are valid/legal/safe to construct a gradient
//
static bool valid_grad(const SkColor4f colors[], const SkScalar pos[], int count,
unsigned tileMode) {
return nullptr != colors && count >= 1 && tileMode < (unsigned)SkShader::kTileModeCount;
}
static void desc_init(SkGradientShaderBase::Descriptor* desc,
const SkColor4f colors[], sk_sp<SkColorSpace> colorSpace,
const SkScalar pos[], int colorCount,
SkShader::TileMode mode, uint32_t flags, const SkMatrix* localMatrix) {
SkASSERT(colorCount > 1);
desc->fColors = colors;
desc->fColorSpace = std::move(colorSpace);
desc->fPos = pos;
desc->fCount = colorCount;
desc->fTileMode = mode;
desc->fGradFlags = flags;
desc->fLocalMatrix = localMatrix;
}
// assumes colors is SkColor4f* and pos is SkScalar*
#define EXPAND_1_COLOR(count) \
SkColor4f tmp[2]; \
do { \
if (1 == count) { \
tmp[0] = tmp[1] = colors[0]; \
colors = tmp; \
pos = nullptr; \
count = 2; \
} \
} while (0)
struct ColorStopOptimizer {
ColorStopOptimizer(const SkColor4f* colors, const SkScalar* pos,
int count, SkShader::TileMode mode)
: fColors(colors)
, fPos(pos)
, fCount(count) {
if (!pos || count != 3) {
return;
}
if (SkScalarNearlyEqual(pos[0], 0.0f) &&
SkScalarNearlyEqual(pos[1], 0.0f) &&
SkScalarNearlyEqual(pos[2], 1.0f)) {
if (SkShader::kRepeat_TileMode == mode ||
SkShader::kMirror_TileMode == mode ||
colors[0] == colors[1]) {
// Ignore the leftmost color/pos.
fColors += 1;
fPos += 1;
fCount = 2;
}
} else if (SkScalarNearlyEqual(pos[0], 0.0f) &&
SkScalarNearlyEqual(pos[1], 1.0f) &&
SkScalarNearlyEqual(pos[2], 1.0f)) {
if (SkShader::kRepeat_TileMode == mode ||
SkShader::kMirror_TileMode == mode ||
colors[1] == colors[2]) {
// Ignore the rightmost color/pos.
fCount = 2;
}
}
}
const SkColor4f* fColors;
const SkScalar* fPos;
int fCount;
};
struct ColorConverter {
ColorConverter(const SkColor* colors, int count) {
for (int i = 0; i < count; ++i) {
fColors4f.push_back(SkColor4f::FromColor(colors[i]));
}
}
SkSTArray<2, SkColor4f, true> fColors4f;
};
sk_sp<SkShader> SkGradientShader::MakeLinear(const SkPoint pts[2],
const SkColor colors[],
const SkScalar pos[], int colorCount,
SkShader::TileMode mode,
uint32_t flags,
const SkMatrix* localMatrix) {
ColorConverter converter(colors, colorCount);
return MakeLinear(pts, converter.fColors4f.begin(), nullptr, pos, colorCount, mode, flags,
localMatrix);
}
sk_sp<SkShader> SkGradientShader::MakeLinear(const SkPoint pts[2],
const SkColor4f colors[],
sk_sp<SkColorSpace> colorSpace,
const SkScalar pos[], int colorCount,
SkShader::TileMode mode,
uint32_t flags,
const SkMatrix* localMatrix) {
if (!pts || !SkScalarIsFinite((pts[1] - pts[0]).length())) {
return nullptr;
}
if (!valid_grad(colors, pos, colorCount, mode)) {
return nullptr;
}
if (1 == colorCount) {
return SkShader::MakeColorShader(colors[0], std::move(colorSpace));
}
if (localMatrix && !localMatrix->invert(nullptr)) {
return nullptr;
}
ColorStopOptimizer opt(colors, pos, colorCount, mode);
SkGradientShaderBase::Descriptor desc;
desc_init(&desc, opt.fColors, std::move(colorSpace), opt.fPos, opt.fCount, mode, flags,
localMatrix);
return sk_make_sp<SkLinearGradient>(pts, desc);
}
sk_sp<SkShader> SkGradientShader::MakeRadial(const SkPoint& center, SkScalar radius,
const SkColor colors[],
const SkScalar pos[], int colorCount,
SkShader::TileMode mode,
uint32_t flags,
const SkMatrix* localMatrix) {
ColorConverter converter(colors, colorCount);
return MakeRadial(center, radius, converter.fColors4f.begin(), nullptr, pos, colorCount, mode,
flags, localMatrix);
}
sk_sp<SkShader> SkGradientShader::MakeRadial(const SkPoint& center, SkScalar radius,
const SkColor4f colors[],
sk_sp<SkColorSpace> colorSpace,
const SkScalar pos[], int colorCount,
SkShader::TileMode mode,
uint32_t flags,
const SkMatrix* localMatrix) {
if (radius <= 0) {
return nullptr;
}
if (!valid_grad(colors, pos, colorCount, mode)) {
return nullptr;
}
if (1 == colorCount) {
return SkShader::MakeColorShader(colors[0], std::move(colorSpace));
}
if (localMatrix && !localMatrix->invert(nullptr)) {
return nullptr;
}
ColorStopOptimizer opt(colors, pos, colorCount, mode);
SkGradientShaderBase::Descriptor desc;
desc_init(&desc, opt.fColors, std::move(colorSpace), opt.fPos, opt.fCount, mode, flags,
localMatrix);
return sk_make_sp<SkRadialGradient>(center, radius, desc);
}
sk_sp<SkShader> SkGradientShader::MakeTwoPointConical(const SkPoint& start,
SkScalar startRadius,
const SkPoint& end,
SkScalar endRadius,
const SkColor colors[],
const SkScalar pos[],
int colorCount,
SkShader::TileMode mode,
uint32_t flags,
const SkMatrix* localMatrix) {
ColorConverter converter(colors, colorCount);
return MakeTwoPointConical(start, startRadius, end, endRadius, converter.fColors4f.begin(),
nullptr, pos, colorCount, mode, flags, localMatrix);
}
sk_sp<SkShader> SkGradientShader::MakeTwoPointConical(const SkPoint& start,
SkScalar startRadius,
const SkPoint& end,
SkScalar endRadius,
const SkColor4f colors[],
sk_sp<SkColorSpace> colorSpace,
const SkScalar pos[],
int colorCount,
SkShader::TileMode mode,
uint32_t flags,
const SkMatrix* localMatrix) {
if (startRadius < 0 || endRadius < 0) {
return nullptr;
}
if (SkScalarNearlyZero((start - end).length()) && SkScalarNearlyZero(startRadius)) {
// We can treat this gradient as radial, which is faster.
return MakeRadial(start, endRadius, colors, std::move(colorSpace), pos, colorCount,
mode, flags, localMatrix);
}
if (!valid_grad(colors, pos, colorCount, mode)) {
return nullptr;
}
if (startRadius == endRadius) {
if (start == end || startRadius == 0) {
return SkShader::MakeEmptyShader();
}
}
if (localMatrix && !localMatrix->invert(nullptr)) {
return nullptr;
}
EXPAND_1_COLOR(colorCount);
ColorStopOptimizer opt(colors, pos, colorCount, mode);
bool flipGradient = startRadius > endRadius;
SkGradientShaderBase::Descriptor desc;
if (!flipGradient) {
desc_init(&desc, opt.fColors, std::move(colorSpace), opt.fPos, opt.fCount, mode, flags,
localMatrix);
return SkTwoPointConicalGradient::Create(start, startRadius, end, endRadius, flipGradient,
desc);
} else {
SkAutoSTArray<8, SkColor4f> colorsNew(opt.fCount);
SkAutoSTArray<8, SkScalar> posNew(opt.fCount);
for (int i = 0; i < opt.fCount; ++i) {
colorsNew[i] = opt.fColors[opt.fCount - i - 1];
}
if (pos) {
for (int i = 0; i < opt.fCount; ++i) {
posNew[i] = 1 - opt.fPos[opt.fCount - i - 1];
}
desc_init(&desc, colorsNew.get(), std::move(colorSpace), posNew.get(), opt.fCount, mode,
flags, localMatrix);
} else {
desc_init(&desc, colorsNew.get(), std::move(colorSpace), nullptr, opt.fCount, mode,
flags, localMatrix);
}
return SkTwoPointConicalGradient::Create(end, endRadius, start, startRadius, flipGradient,
desc);
}
}
sk_sp<SkShader> SkGradientShader::MakeSweep(SkScalar cx, SkScalar cy,
const SkColor colors[],
const SkScalar pos[],
int colorCount,
SkShader::TileMode mode,
SkScalar startAngle,
SkScalar endAngle,
uint32_t flags,
const SkMatrix* localMatrix) {
ColorConverter converter(colors, colorCount);
return MakeSweep(cx, cy, converter.fColors4f.begin(), nullptr, pos, colorCount,
mode, startAngle, endAngle, flags, localMatrix);
}
sk_sp<SkShader> SkGradientShader::MakeSweep(SkScalar cx, SkScalar cy,
const SkColor4f colors[],
sk_sp<SkColorSpace> colorSpace,
const SkScalar pos[],
int colorCount,
SkShader::TileMode mode,
SkScalar startAngle,
SkScalar endAngle,
uint32_t flags,
const SkMatrix* localMatrix) {
if (!valid_grad(colors, pos, colorCount, mode)) {
return nullptr;
}
if (1 == colorCount) {
return SkShader::MakeColorShader(colors[0], std::move(colorSpace));
}
if (startAngle >= endAngle) {
return nullptr;
}
if (localMatrix && !localMatrix->invert(nullptr)) {
return nullptr;
}
if (startAngle <= 0 && endAngle >= 360) {
// If the t-range includes [0,1], then we can always use clamping (presumably faster).
mode = SkShader::kClamp_TileMode;
}
ColorStopOptimizer opt(colors, pos, colorCount, mode);
SkGradientShaderBase::Descriptor desc;
desc_init(&desc, opt.fColors, std::move(colorSpace), opt.fPos, opt.fCount, mode, flags,
localMatrix);
const SkScalar t0 = startAngle / 360,
t1 = endAngle / 360;
return sk_make_sp<SkSweepGradient>(SkPoint::Make(cx, cy), t0, t1, desc);
}
SK_DEFINE_FLATTENABLE_REGISTRAR_GROUP_START(SkGradientShader)
SK_DEFINE_FLATTENABLE_REGISTRAR_ENTRY(SkLinearGradient)
SK_DEFINE_FLATTENABLE_REGISTRAR_ENTRY(SkRadialGradient)
SK_DEFINE_FLATTENABLE_REGISTRAR_ENTRY(SkSweepGradient)
SK_DEFINE_FLATTENABLE_REGISTRAR_ENTRY(SkTwoPointConicalGradient)
SK_DEFINE_FLATTENABLE_REGISTRAR_GROUP_END
///////////////////////////////////////////////////////////////////////////////
#if SK_SUPPORT_GPU
#include "GrContext.h"
#include "GrShaderCaps.h"
#include "GrTextureStripAtlas.h"
#include "gl/GrGLContext.h"
#include "glsl/GrGLSLColorSpaceXformHelper.h"
#include "glsl/GrGLSLFragmentShaderBuilder.h"
#include "glsl/GrGLSLProgramDataManager.h"
#include "glsl/GrGLSLUniformHandler.h"
#include "SkGr.h"
static inline int color_type_to_color_count(GrGradientEffect::ColorType colorType) {
switch (colorType) {
case GrGradientEffect::kSingleHardStop_ColorType:
return 4;
case GrGradientEffect::kHardStopLeftEdged_ColorType:
case GrGradientEffect::kHardStopRightEdged_ColorType:
return 3;
case GrGradientEffect::kTwo_ColorType:
return 2;
case GrGradientEffect::kThree_ColorType:
return 3;
case GrGradientEffect::kTexture_ColorType:
return 0;
}
SkDEBUGFAIL("Unhandled ColorType in color_type_to_color_count()");
return -1;
}
GrGradientEffect::ColorType GrGradientEffect::determineColorType(
const SkGradientShaderBase& shader) {
if (shader.fOrigPos) {
if (4 == shader.fColorCount) {
if (SkScalarNearlyEqual(shader.fOrigPos[0], 0.0f) &&
SkScalarNearlyEqual(shader.fOrigPos[1], shader.fOrigPos[2]) &&
SkScalarNearlyEqual(shader.fOrigPos[3], 1.0f)) {
return kSingleHardStop_ColorType;
}
} else if (3 == shader.fColorCount) {
if (SkScalarNearlyEqual(shader.fOrigPos[0], 0.0f) &&
SkScalarNearlyEqual(shader.fOrigPos[1], 0.0f) &&
SkScalarNearlyEqual(shader.fOrigPos[2], 1.0f)) {
return kHardStopLeftEdged_ColorType;
} else if (SkScalarNearlyEqual(shader.fOrigPos[0], 0.0f) &&
SkScalarNearlyEqual(shader.fOrigPos[1], 1.0f) &&
SkScalarNearlyEqual(shader.fOrigPos[2], 1.0f)) {
return kHardStopRightEdged_ColorType;
}
}
}
if (2 == shader.fColorCount) {
return kTwo_ColorType;
} else if (3 == shader.fColorCount) {
return kThree_ColorType;
}
return kTexture_ColorType;
}
void GrGradientEffect::GLSLProcessor::emitUniforms(GrGLSLUniformHandler* uniformHandler,
const GrGradientEffect& ge) {
if (int colorCount = color_type_to_color_count(ge.getColorType())) {
fColorsUni = uniformHandler->addUniformArray(kFragment_GrShaderFlag,
kHalf4_GrSLType,
"Colors",
colorCount);
if (kSingleHardStop_ColorType == ge.fColorType || kThree_ColorType == ge.fColorType) {
fExtraStopT = uniformHandler->addUniform(kFragment_GrShaderFlag, kHighFloat4_GrSLType,
kHigh_GrSLPrecision, "ExtraStopT");
}
} else {
fFSYUni = uniformHandler->addUniform(kFragment_GrShaderFlag, kHalf_GrSLType,
"GradientYCoordFS");
}
}
static inline void set_after_interp_color_uni_array(
const GrGLSLProgramDataManager& pdman,
const GrGLSLProgramDataManager::UniformHandle uni,
const SkTDArray<SkColor4f>& colors,
const GrColorSpaceXform* colorSpaceXform) {
int count = colors.count();
if (colorSpaceXform) {
constexpr int kSmallCount = 10;
SkAutoSTArray<4 * kSmallCount, float> vals(4 * count);
for (int i = 0; i < count; i++) {
colorSpaceXform->srcToDst().mapScalars(colors[i].vec(), &vals[4 * i]);
}
pdman.set4fv(uni, count, vals.get());
} else {
pdman.set4fv(uni, count, (float*)&colors[0]);
}
}
static inline void set_before_interp_color_uni_array(
const GrGLSLProgramDataManager& pdman,
const GrGLSLProgramDataManager::UniformHandle uni,
const SkTDArray<SkColor4f>& colors,
const GrColorSpaceXform* colorSpaceXform) {
int count = colors.count();
constexpr int kSmallCount = 10;
SkAutoSTArray<4 * kSmallCount, float> vals(4 * count);
for (int i = 0; i < count; i++) {
float a = colors[i].fA;
vals[4 * i + 0] = colors[i].fR * a;
vals[4 * i + 1] = colors[i].fG * a;
vals[4 * i + 2] = colors[i].fB * a;
vals[4 * i + 3] = a;
}
if (colorSpaceXform) {
for (int i = 0; i < count; i++) {
colorSpaceXform->srcToDst().mapScalars(&vals[4 * i]);
}
}
pdman.set4fv(uni, count, vals.get());
}
static inline void set_after_interp_color_uni_array(const GrGLSLProgramDataManager& pdman,
const GrGLSLProgramDataManager::UniformHandle uni,
const SkTDArray<SkColor>& colors) {
int count = colors.count();
constexpr int kSmallCount = 10;
SkAutoSTArray<4*kSmallCount, float> vals(4*count);
for (int i = 0; i < colors.count(); i++) {
// RGBA
vals[4*i + 0] = SkColorGetR(colors[i]) / 255.f;
vals[4*i + 1] = SkColorGetG(colors[i]) / 255.f;
vals[4*i + 2] = SkColorGetB(colors[i]) / 255.f;
vals[4*i + 3] = SkColorGetA(colors[i]) / 255.f;
}
pdman.set4fv(uni, colors.count(), vals.get());
}
static inline void set_before_interp_color_uni_array(const GrGLSLProgramDataManager& pdman,
const GrGLSLProgramDataManager::UniformHandle uni,
const SkTDArray<SkColor>& colors) {
int count = colors.count();
constexpr int kSmallCount = 10;
SkAutoSTArray<4*kSmallCount, float> vals(4*count);
for (int i = 0; i < count; i++) {
float a = SkColorGetA(colors[i]) / 255.f;
float aDiv255 = a / 255.f;
// RGBA
vals[4*i + 0] = SkColorGetR(colors[i]) * aDiv255;
vals[4*i + 1] = SkColorGetG(colors[i]) * aDiv255;
vals[4*i + 2] = SkColorGetB(colors[i]) * aDiv255;
vals[4*i + 3] = a;
}
pdman.set4fv(uni, count, vals.get());
}
void GrGradientEffect::GLSLProcessor::onSetData(const GrGLSLProgramDataManager& pdman,
const GrFragmentProcessor& processor) {
const GrGradientEffect& e = processor.cast<GrGradientEffect>();
switch (e.getColorType()) {
case GrGradientEffect::kSingleHardStop_ColorType:
case GrGradientEffect::kThree_ColorType:
// ( t, 1/t, 1/(1-t), t/(1-t) )
// This lets us compute relative t on either side of the stop with at most a single FMA
pdman.set4f(fExtraStopT, e.fPositions[1],
1.0f / e.fPositions[1],
1.0f / (1.0f - e.fPositions[1]),
e.fPositions[1] / (1.0f - e.fPositions[1]));
// fall through
case GrGradientEffect::kHardStopLeftEdged_ColorType:
case GrGradientEffect::kHardStopRightEdged_ColorType:
case GrGradientEffect::kTwo_ColorType: {
if (e.fColors4f.count() > 0) {
// Gamma-correct / color-space aware
if (GrGradientEffect::kBeforeInterp_PremulType == e.getPremulType()) {
set_before_interp_color_uni_array(pdman, fColorsUni, e.fColors4f,
e.fColorSpaceXform.get());
} else {
set_after_interp_color_uni_array(pdman, fColorsUni, e.fColors4f,
e.fColorSpaceXform.get());
}
} else {
// Legacy mode. Would be nice if we had converted the 8-bit colors to float earlier
if (GrGradientEffect::kBeforeInterp_PremulType == e.getPremulType()) {
set_before_interp_color_uni_array(pdman, fColorsUni, e.fColors);
} else {
set_after_interp_color_uni_array(pdman, fColorsUni, e.fColors);
}
}
break;
}
case GrGradientEffect::kTexture_ColorType: {
SkScalar yCoord = e.getYCoord();
if (yCoord != fCachedYCoord) {
pdman.set1f(fFSYUni, yCoord);
fCachedYCoord = yCoord;
}
if (SkToBool(e.fColorSpaceXform)) {
fColorSpaceHelper.setData(pdman, e.fColorSpaceXform.get());
}
break;
}
}
}
uint32_t GrGradientEffect::GLSLProcessor::GenBaseGradientKey(const GrProcessor& processor) {
const GrGradientEffect& e = processor.cast<GrGradientEffect>();
uint32_t key = 0;
if (GrGradientEffect::kBeforeInterp_PremulType == e.getPremulType()) {
key |= kPremulBeforeInterpKey;
}
if (GrGradientEffect::kTwo_ColorType == e.getColorType()) {
key |= kTwoColorKey;
} else if (GrGradientEffect::kThree_ColorType == e.getColorType()) {
key |= kThreeColorKey;
} else if (GrGradientEffect::kSingleHardStop_ColorType == e.getColorType()) {
key |= kHardStopCenteredKey;
} else if (GrGradientEffect::kHardStopLeftEdged_ColorType == e.getColorType()) {
key |= kHardStopZeroZeroOneKey;
} else if (GrGradientEffect::kHardStopRightEdged_ColorType == e.getColorType()) {
key |= kHardStopZeroOneOneKey;
}
switch (e.fWrapMode) {
case GrSamplerState::WrapMode::kClamp:
key |= kClampTileMode;
break;
case GrSamplerState::WrapMode::kRepeat:
key |= kRepeatTileMode;
break;
case GrSamplerState::WrapMode::kMirrorRepeat:
key |= kMirrorTileMode;
break;
}
key |= GrColorSpaceXform::XformKey(e.fColorSpaceXform.get()) << kReservedBits;
return key;
}
void GrGradientEffect::GLSLProcessor::emitAnalyticalColor(GrGLSLFPFragmentBuilder* fragBuilder,
GrGLSLUniformHandler* uniformHandler,
const GrShaderCaps* shaderCaps,
const GrGradientEffect& ge,
const char* t,
const char* outputColor,
const char* inputColor) {
// First, apply tiling rules.
switch (ge.fWrapMode) {
case GrSamplerState::WrapMode::kClamp:
fragBuilder->codeAppendf("half clamp_t = clamp(%s, 0.0, 1.0);", t);
break;
case GrSamplerState::WrapMode::kRepeat:
fragBuilder->codeAppendf("half clamp_t = fract(%s);", t);
break;
case GrSamplerState::WrapMode::kMirrorRepeat:
fragBuilder->codeAppendf("half t_1 = %s - 1.0;", t);
fragBuilder->codeAppendf("half clamp_t = abs(t_1 - 2.0 * floor(t_1 * 0.5) - 1.0);");
break;
}
// Calculate the color.
const char* colors = uniformHandler->getUniformCStr(fColorsUni);
switch (ge.getColorType()) {
case kSingleHardStop_ColorType: {
// (t, 1/t, 1/(1-t), t/(1-t))
const char* stopT = uniformHandler->getUniformCStr(fExtraStopT);
fragBuilder->codeAppend ("half4 start, end;");
fragBuilder->codeAppend ("half relative_t;");
fragBuilder->codeAppendf("if (clamp_t < %s.x) {", stopT);
fragBuilder->codeAppendf(" start = %s[0];", colors);
fragBuilder->codeAppendf(" end = %s[1];", colors);
fragBuilder->codeAppendf(" relative_t = clamp_t * %s.y;", stopT);
fragBuilder->codeAppend ("} else {");
fragBuilder->codeAppendf(" start = %s[2];", colors);
fragBuilder->codeAppendf(" end = %s[3];", colors);
// Want: (t-s)/(1-s), but arrange it as: t/(1-s) - s/(1-s), for FMA form
fragBuilder->codeAppendf(" relative_t = (clamp_t * %s.z) - %s.w;", stopT, stopT);
fragBuilder->codeAppend ("}");
fragBuilder->codeAppend ("half4 colorTemp = mix(start, end, relative_t);");
break;
}
case kHardStopLeftEdged_ColorType: {
fragBuilder->codeAppendf("half4 colorTemp = mix(%s[1], %s[2], clamp_t);", colors,
colors);
if (GrSamplerState::WrapMode::kClamp == ge.fWrapMode) {
fragBuilder->codeAppendf("if (%s < 0.0) {", t);
fragBuilder->codeAppendf(" colorTemp = %s[0];", colors);
fragBuilder->codeAppendf("}");
}
break;
}
case kHardStopRightEdged_ColorType: {
fragBuilder->codeAppendf("half4 colorTemp = mix(%s[0], %s[1], clamp_t);", colors,
colors);
if (GrSamplerState::WrapMode::kClamp == ge.fWrapMode) {
fragBuilder->codeAppendf("if (%s > 1.0) {", t);
fragBuilder->codeAppendf(" colorTemp = %s[2];", colors);
fragBuilder->codeAppendf("}");
}
break;
}
case kTwo_ColorType: {
fragBuilder->codeAppendf("half4 colorTemp = mix(%s[0], %s[1], clamp_t);",
colors, colors);
break;
}
case kThree_ColorType: {
// (t, 1/t, 1/(1-t), t/(1-t))
const char* stopT = uniformHandler->getUniformCStr(fExtraStopT);
fragBuilder->codeAppend("half4 start, end;");
fragBuilder->codeAppend("half relative_t;");
fragBuilder->codeAppendf("if (clamp_t < %s.x) {", stopT);
fragBuilder->codeAppendf(" start = %s[0];", colors);
fragBuilder->codeAppendf(" end = %s[1];", colors);
fragBuilder->codeAppendf(" relative_t = clamp_t * %s.y;", stopT);
fragBuilder->codeAppend("} else {");
fragBuilder->codeAppendf(" start = %s[1];", colors);
fragBuilder->codeAppendf(" end = %s[2];", colors);
// Want: (t-s)/(1-s), but arrange it as: t/(1-s) - s/(1-s), for FMA form
fragBuilder->codeAppendf(" relative_t = (clamp_t * %s.z) - %s.w;", stopT, stopT);
fragBuilder->codeAppend("}");
fragBuilder->codeAppend("half4 colorTemp = mix(start, end, relative_t);");
break;
}
default:
SkASSERT(false);
break;
}
// We could skip this step if both colors are known to be opaque. Two
// considerations:
// The gradient SkShader reporting opaque is more restrictive than necessary in the two
// pt case. Make sure the key reflects this optimization (and note that it can use the
// same shader as thekBeforeIterp case). This same optimization applies to the 3 color
// case below.
if (GrGradientEffect::kAfterInterp_PremulType == ge.getPremulType()) {
fragBuilder->codeAppend("colorTemp.rgb *= colorTemp.a;");
}
if (ge.fColorSpaceXform) {
fragBuilder->codeAppend("colorTemp.rgb = clamp(colorTemp.rgb, 0, colorTemp.a);");
}
fragBuilder->codeAppendf("%s = %s * colorTemp;", outputColor, inputColor);
}
void GrGradientEffect::GLSLProcessor::emitColor(GrGLSLFPFragmentBuilder* fragBuilder,
GrGLSLUniformHandler* uniformHandler,
const GrShaderCaps* shaderCaps,
const GrGradientEffect& ge,
const char* gradientTValue,
const char* outputColor,
const char* inputColor,
const TextureSamplers& texSamplers) {
if (ge.getColorType() != kTexture_ColorType) {
this->emitAnalyticalColor(fragBuilder, uniformHandler, shaderCaps, ge, gradientTValue,
outputColor, inputColor);
return;
}
fColorSpaceHelper.emitCode(uniformHandler, ge.fColorSpaceXform.get());
const char* fsyuni = uniformHandler->getUniformCStr(fFSYUni);
fragBuilder->codeAppendf("half2 coord = half2(%s, %s);", gradientTValue, fsyuni);
fragBuilder->codeAppendf("%s = ", outputColor);
fragBuilder->appendTextureLookupAndModulate(inputColor, texSamplers[0], "coord",
kHighFloat2_GrSLType, &fColorSpaceHelper);
fragBuilder->codeAppend(";");
}
/////////////////////////////////////////////////////////////////////
inline GrFragmentProcessor::OptimizationFlags GrGradientEffect::OptFlags(bool isOpaque) {
return isOpaque
? kPreservesOpaqueInput_OptimizationFlag |
kCompatibleWithCoverageAsAlpha_OptimizationFlag
: kCompatibleWithCoverageAsAlpha_OptimizationFlag;
}
GrGradientEffect::GrGradientEffect(const CreateArgs& args, bool isOpaque)
: INHERITED(OptFlags(isOpaque)) {
const SkGradientShaderBase& shader(*args.fShader);
fIsOpaque = shader.isOpaque();
fColorType = this->determineColorType(shader);
fColorSpaceXform = std::move(args.fColorSpaceXform);
if (kTexture_ColorType != fColorType) {
SkASSERT(shader.fOrigColors && shader.fOrigColors4f);
if (args.fGammaCorrect) {
fColors4f = SkTDArray<SkColor4f>(shader.fOrigColors4f, shader.fColorCount);
} else {
fColors = SkTDArray<SkColor>(shader.fOrigColors, shader.fColorCount);
}
if (shader.fOrigPos) {
fPositions = SkTDArray<SkScalar>(shader.fOrigPos, shader.fColorCount);
} else if (kThree_ColorType == fColorType) {
const SkScalar symmetricStops[] = { 0.0f, 0.5f, 1.0f };
fPositions = SkTDArray<SkScalar>(symmetricStops, 3);
}
}
fWrapMode = args.fWrapMode;
switch (fColorType) {
// The two and three color specializations do not currently support tiling.
case kTwo_ColorType:
case kThree_ColorType:
case kHardStopLeftEdged_ColorType:
case kHardStopRightEdged_ColorType:
case kSingleHardStop_ColorType:
fRow = -1;
if (SkGradientShader::kInterpolateColorsInPremul_Flag & shader.getGradFlags()) {
fPremulType = kBeforeInterp_PremulType;
} else {
fPremulType = kAfterInterp_PremulType;
}
fCoordTransform.reset(*args.fMatrix);
break;
case kTexture_ColorType:
// doesn't matter how this is set, just be consistent because it is part of the
// effect key.
fPremulType = kBeforeInterp_PremulType;
SkGradientShaderBase::GradientBitmapType bitmapType =
SkGradientShaderBase::GradientBitmapType::kLegacy;
if (args.fGammaCorrect) {
// Try to use F16 if we can
if (args.fContext->caps()->isConfigTexturable(kRGBA_half_GrPixelConfig)) {
bitmapType = SkGradientShaderBase::GradientBitmapType::kHalfFloat;
} else if (args.fContext->caps()->isConfigTexturable(kSRGBA_8888_GrPixelConfig)) {
bitmapType = SkGradientShaderBase::GradientBitmapType::kSRGB;
} else {
// This can happen, but only if someone explicitly creates an unsupported
// (eg sRGB) surface. Just fall back to legacy behavior.
}
}
SkBitmap bitmap;
shader.getGradientTableBitmap(&bitmap, bitmapType);
SkASSERT(1 == bitmap.height() && SkIsPow2(bitmap.width()));
GrTextureStripAtlas::Desc desc;
desc.fWidth = bitmap.width();
desc.fHeight = 32;
desc.fRowHeight = bitmap.height();
desc.fContext = args.fContext;
desc.fConfig = SkImageInfo2GrPixelConfig(bitmap.info(), *args.fContext->caps());
fAtlas = GrTextureStripAtlas::GetAtlas(desc);
SkASSERT(fAtlas);
// We always filter the gradient table. Each table is one row of a texture, always
// y-clamp.
GrSamplerState samplerState(args.fWrapMode, GrSamplerState::Filter::kBilerp);
fRow = fAtlas->lockRow(bitmap);
if (-1 != fRow) {
fYCoord = fAtlas->getYOffset(fRow)+SK_ScalarHalf*fAtlas->getNormalizedTexelHeight();
// This is 1/2 places where auto-normalization is disabled
fCoordTransform.reset(*args.fMatrix, fAtlas->asTextureProxyRef().get(), false);
fTextureSampler.reset(fAtlas->asTextureProxyRef(), samplerState);
} else {
// In this instance we know the samplerState state is:
// clampY, bilerp
// and the proxy is:
// exact fit, power of two in both dimensions
// Only the x-tileMode is unknown. However, given all the other knowns we know
// that GrMakeCachedBitmapProxy is sufficient (i.e., it won't need to be
// extracted to a subset or mipmapped).
sk_sp<GrTextureProxy> proxy = GrMakeCachedBitmapProxy(
args.fContext->resourceProvider(),
bitmap);
if (!proxy) {
SkDebugf("Gradient won't draw. Could not create texture.");
return;
}
// This is 2/2 places where auto-normalization is disabled
fCoordTransform.reset(*args.fMatrix, proxy.get(), false);
fTextureSampler.reset(std::move(proxy), samplerState);
fYCoord = SK_ScalarHalf;
}
this->addTextureSampler(&fTextureSampler);
break;
}
this->addCoordTransform(&fCoordTransform);
}
GrGradientEffect::GrGradientEffect(const GrGradientEffect& that)
: INHERITED(OptFlags(that.fIsOpaque))
, fColors(that.fColors)
, fColors4f(that.fColors4f)
, fColorSpaceXform(that.fColorSpaceXform)
, fPositions(that.fPositions)
, fWrapMode(that.fWrapMode)
, fCoordTransform(that.fCoordTransform)
, fTextureSampler(that.fTextureSampler)
, fYCoord(that.fYCoord)
, fAtlas(that.fAtlas)
, fRow(that.fRow)
, fIsOpaque(that.fIsOpaque)
, fColorType(that.fColorType)
, fPremulType(that.fPremulType) {
this->addCoordTransform(&fCoordTransform);
if (kTexture_ColorType == fColorType) {
this->addTextureSampler(&fTextureSampler);
}
if (this->useAtlas()) {
fAtlas->lockRow(fRow);
}
}
GrGradientEffect::~GrGradientEffect() {
if (this->useAtlas()) {
fAtlas->unlockRow(fRow);
}
}
bool GrGradientEffect::onIsEqual(const GrFragmentProcessor& processor) const {
const GrGradientEffect& ge = processor.cast<GrGradientEffect>();
if (fWrapMode != ge.fWrapMode || fColorType != ge.getColorType()) {
return false;
}
SkASSERT(this->useAtlas() == ge.useAtlas());
if (kTexture_ColorType == fColorType) {
if (fYCoord != ge.getYCoord()) {
return false;
}
} else {
if (kSingleHardStop_ColorType == fColorType || kThree_ColorType == fColorType) {
if (!SkScalarNearlyEqual(ge.fPositions[1], fPositions[1])) {
return false;
}
}
if (this->getPremulType() != ge.getPremulType() ||
this->fColors.count() != ge.fColors.count() ||
this->fColors4f.count() != ge.fColors4f.count()) {
return false;
}
for (int i = 0; i < this->fColors.count(); i++) {
if (*this->getColors(i) != *ge.getColors(i)) {
return false;
}
}
for (int i = 0; i < this->fColors4f.count(); i++) {
if (*this->getColors4f(i) != *ge.getColors4f(i)) {
return false;
}
}
}
return GrColorSpaceXform::Equals(this->fColorSpaceXform.get(), ge.fColorSpaceXform.get());
}
#if GR_TEST_UTILS
GrGradientEffect::RandomGradientParams::RandomGradientParams(SkRandom* random) {
// Set color count to min of 2 so that we don't trigger the const color optimization and make
// a non-gradient processor.
fColorCount = random->nextRangeU(2, kMaxRandomGradientColors);
fUseColors4f = random->nextBool();
// if one color, omit stops, otherwise randomly decide whether or not to
if (fColorCount == 1 || (fColorCount >= 2 && random->nextBool())) {
fStops = nullptr;
} else {
fStops = fStopStorage;
}
// if using SkColor4f, attach a random (possibly null) color space (with linear gamma)
if (fUseColors4f) {
fColorSpace = GrTest::TestColorSpace(random);
if (fColorSpace) {
SkASSERT(SkColorSpace_Base::Type::kXYZ == as_CSB(fColorSpace)->type());
fColorSpace = static_cast<SkColorSpace_XYZ*>(fColorSpace.get())->makeLinearGamma();
}
}
SkScalar stop = 0.f;
for (int i = 0; i < fColorCount; ++i) {
if (fUseColors4f) {
fColors4f[i].fR = random->nextUScalar1();
fColors4f[i].fG = random->nextUScalar1();
fColors4f[i].fB = random->nextUScalar1();
fColors4f[i].fA = random->nextUScalar1();
} else {
fColors[i] = random->nextU();
}
if (fStops) {
fStops[i] = stop;
stop = i < fColorCount - 1 ? stop + random->nextUScalar1() * (1.f - stop) : 1.f;
}
}
fTileMode = static_cast<SkShader::TileMode>(random->nextULessThan(SkShader::kTileModeCount));
}
#endif
#endif
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