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skia2/gm/beziereffects.cpp
commit-bot@chromium.org e0e7cfe44b Change old PRG to be SkLCGRandom; change new one to SkRandom 
The goal here is to get people to start using the new random number
generator, while leaving the old one in place so we don't have to 
rebaseline GMs.

R=reed@google.com, bsalomon@google.com

Author: jvanverth@google.com

Review URL: https://chromiumcodereview.appspot.com/23576015

git-svn-id: http://skia.googlecode.com/svn/trunk@11169 2bbb7eff-a529-9590-31e7-b0007b416f81
2013-09-09 20:09:12 +00:00

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/*
* Copyright 2013 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
// This test only works with the GPU backend.
#include "gm.h"
#if SK_SUPPORT_GPU
#include "GrContext.h"
#include "GrPathUtils.h"
#include "GrTest.h"
#include "SkColorPriv.h"
#include "SkDevice.h"
#include "SkGeometry.h"
#include "effects/GrBezierEffect.h"
// Position & KLM line eq values. These are the vertex attributes for Bezier curves. The last value
// of the Vec4f is ignored.
extern const GrVertexAttrib kAttribs[] = {
{kVec2f_GrVertexAttribType, 0, kPosition_GrVertexAttribBinding},
{kVec4f_GrVertexAttribType, sizeof(GrPoint), kEffect_GrVertexAttribBinding}
};
static inline SkScalar eval_line(const SkPoint& p, const SkScalar lineEq[3], SkScalar sign) {
return sign * (lineEq[0] * p.fX + lineEq[1] * p.fY + lineEq[2]);
}
namespace skiagm {
/**
* This GM directly exercises effects that draw Bezier curves in the GPU backend.
*/
class BezierCubicEffects : public GM {
public:
BezierCubicEffects() {
this->setBGColor(0xFFFFFFFF);
}
protected:
virtual SkString onShortName() SK_OVERRIDE {
return SkString("bezier_cubic_effects");
}
virtual SkISize onISize() SK_OVERRIDE {
return make_isize(800, 800);
}
virtual uint32_t onGetFlags() const SK_OVERRIDE {
// This is a GPU-specific GM.
return kGPUOnly_Flag;
}
virtual void onDraw(SkCanvas* canvas) SK_OVERRIDE {
SkBaseDevice* device = canvas->getTopDevice();
GrRenderTarget* rt = device->accessRenderTarget();
if (NULL == rt) {
return;
}
GrContext* context = rt->getContext();
if (NULL == context) {
return;
}
struct Vertex {
SkPoint fPosition;
float fKLM[4]; // The last value is ignored. The effect expects a vec4f.
};
static const int kNumCubics = 15;
SkRandom rand;
// Mult by 3 for each edge effect type
int numCols = SkScalarCeilToInt(SkScalarSqrt(SkIntToScalar(kNumCubics*3)));
int numRows = SkScalarCeilToInt(SkIntToScalar(kNumCubics*3) / numCols);
SkScalar w = SkIntToScalar(rt->width()) / numCols;
SkScalar h = SkIntToScalar(rt->height()) / numRows;
int row = 0;
int col = 0;
for (int i = 0; i < kNumCubics; ++i) {
SkPoint baseControlPts[] = {
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)}
};
for(int edgeType = kFillAA_GrBezierEdgeType; edgeType < 3; ++edgeType) {
SkScalar x = SkScalarMul(col, w);
SkScalar y = SkScalarMul(row, h);
SkPoint controlPts[] = {
{x + baseControlPts[0].fX, y + baseControlPts[0].fY},
{x + baseControlPts[1].fX, y + baseControlPts[1].fY},
{x + baseControlPts[2].fX, y + baseControlPts[2].fY},
{x + baseControlPts[3].fX, y + baseControlPts[3].fY}
};
SkPoint chopped[10];
SkScalar klmEqs[9];
SkScalar klmSigns[3];
int cnt = GrPathUtils::chopCubicAtLoopIntersection(controlPts,
chopped,
klmEqs,
klmSigns);
SkPaint ctrlPtPaint;
ctrlPtPaint.setColor(rand.nextU() | 0xFF000000);
for (int i = 0; i < 4; ++i) {
canvas->drawCircle(controlPts[i].fX, controlPts[i].fY, 6.f, ctrlPtPaint);
}
SkPaint polyPaint;
polyPaint.setColor(0xffA0A0A0);
polyPaint.setStrokeWidth(0);
polyPaint.setStyle(SkPaint::kStroke_Style);
canvas->drawPoints(SkCanvas::kPolygon_PointMode, 4, controlPts, polyPaint);
SkPaint choppedPtPaint;
choppedPtPaint.setColor(~ctrlPtPaint.getColor() | 0xFF000000);
for (int c = 0; c < cnt; ++c) {
SkPoint* pts = chopped + 3 * c;
for (int i = 0; i < 4; ++i) {
canvas->drawCircle(pts[i].fX, pts[i].fY, 3.f, choppedPtPaint);
}
SkRect bounds;
bounds.set(pts, 4);
SkPaint boundsPaint;
boundsPaint.setColor(0xff808080);
boundsPaint.setStrokeWidth(0);
boundsPaint.setStyle(SkPaint::kStroke_Style);
canvas->drawRect(bounds, boundsPaint);
Vertex verts[4];
verts[0].fPosition.setRectFan(bounds.fLeft, bounds.fTop,
bounds.fRight, bounds.fBottom,
sizeof(Vertex));
for (int v = 0; v < 4; ++v) {
verts[v].fKLM[0] = eval_line(verts[v].fPosition, klmEqs + 0, klmSigns[c]);
verts[v].fKLM[1] = eval_line(verts[v].fPosition, klmEqs + 3, klmSigns[c]);
verts[v].fKLM[2] = eval_line(verts[v].fPosition, klmEqs + 6, 1.f);
}
GrTestTarget tt;
context->getTestTarget(&tt);
if (NULL == tt.target()) {
continue;
}
GrDrawState* drawState = tt.target()->drawState();
drawState->setVertexAttribs<kAttribs>(2);
SkAutoTUnref<GrEffectRef> effect(GrCubicEffect::Create(
GrBezierEdgeType(edgeType), *tt.target()->caps()));
if (!effect) {
continue;
}
drawState->addCoverageEffect(effect, 1);
drawState->setRenderTarget(rt);
drawState->setColor(0xff000000);
tt.target()->setVertexSourceToArray(verts, 4);
tt.target()->setIndexSourceToBuffer(context->getQuadIndexBuffer());
tt.target()->drawIndexed(kTriangleFan_GrPrimitiveType, 0, 0, 4, 6);
}
++col;
if (numCols == col) {
col = 0;
++row;
}
}
}
}
private:
typedef GM INHERITED;
};
//////////////////////////////////////////////////////////////////////////////
/**
* This GM directly exercises effects that draw Bezier curves in the GPU backend.
*/
class BezierConicEffects : public GM {
public:
BezierConicEffects() {
this->setBGColor(0xFFFFFFFF);
}
protected:
virtual SkString onShortName() SK_OVERRIDE {
return SkString("bezier_conic_effects");
}
virtual SkISize onISize() SK_OVERRIDE {
return make_isize(800, 800);
}
virtual uint32_t onGetFlags() const SK_OVERRIDE {
// This is a GPU-specific GM.
return kGPUOnly_Flag;
}
virtual void onDraw(SkCanvas* canvas) SK_OVERRIDE {
SkBaseDevice* device = canvas->getTopDevice();
GrRenderTarget* rt = device->accessRenderTarget();
if (NULL == rt) {
return;
}
GrContext* context = rt->getContext();
if (NULL == context) {
return;
}
struct Vertex {
SkPoint fPosition;
float fKLM[4]; // The last value is ignored. The effect expects a vec4f.
};
static const int kNumConics = 10;
SkRandom rand;
// Mult by 3 for each edge effect type
int numCols = SkScalarCeilToInt(SkScalarSqrt(SkIntToScalar(kNumConics*3)));
int numRows = SkScalarCeilToInt(SkIntToScalar(kNumConics*3) / numCols);
SkScalar w = SkIntToScalar(rt->width()) / numCols;
SkScalar h = SkIntToScalar(rt->height()) / numRows;
int row = 0;
int col = 0;
for (int i = 0; i < kNumConics; ++i) {
SkPoint baseControlPts[] = {
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)}
};
SkScalar weight = rand.nextRangeF(0.f, 2.f);
for(int edgeType = kFillAA_GrBezierEdgeType; edgeType < 3; ++edgeType) {
SkScalar x = SkScalarMul(col, w);
SkScalar y = SkScalarMul(row, h);
SkPoint controlPts[] = {
{x + baseControlPts[0].fX, y + baseControlPts[0].fY},
{x + baseControlPts[1].fX, y + baseControlPts[1].fY},
{x + baseControlPts[2].fX, y + baseControlPts[2].fY}
};
SkConic dst[4];
SkScalar klmEqs[9];
int cnt = chop_conic(controlPts, dst, weight);
GrPathUtils::getConicKLM(controlPts, weight, klmEqs);
SkPaint ctrlPtPaint;
ctrlPtPaint.setColor(rand.nextU() | 0xFF000000);
for (int i = 0; i < 3; ++i) {
canvas->drawCircle(controlPts[i].fX, controlPts[i].fY, 6.f, ctrlPtPaint);
}
SkPaint polyPaint;
polyPaint.setColor(0xffA0A0A0);
polyPaint.setStrokeWidth(0);
polyPaint.setStyle(SkPaint::kStroke_Style);
canvas->drawPoints(SkCanvas::kPolygon_PointMode, 3, controlPts, polyPaint);
SkPaint choppedPtPaint;
choppedPtPaint.setColor(~ctrlPtPaint.getColor() | 0xFF000000);
for (int c = 0; c < cnt; ++c) {
SkPoint* pts = dst[c].fPts;
for (int i = 0; i < 3; ++i) {
canvas->drawCircle(pts[i].fX, pts[i].fY, 3.f, choppedPtPaint);
}
SkRect bounds;
//SkPoint bPts[] = {{0.f, 0.f}, {800.f, 800.f}};
//bounds.set(bPts, 2);
bounds.set(pts, 3);
SkPaint boundsPaint;
boundsPaint.setColor(0xff808080);
boundsPaint.setStrokeWidth(0);
boundsPaint.setStyle(SkPaint::kStroke_Style);
canvas->drawRect(bounds, boundsPaint);
Vertex verts[4];
verts[0].fPosition.setRectFan(bounds.fLeft, bounds.fTop,
bounds.fRight, bounds.fBottom,
sizeof(Vertex));
for (int v = 0; v < 4; ++v) {
verts[v].fKLM[0] = eval_line(verts[v].fPosition, klmEqs + 0, 1.f);
verts[v].fKLM[1] = eval_line(verts[v].fPosition, klmEqs + 3, 1.f);
verts[v].fKLM[2] = eval_line(verts[v].fPosition, klmEqs + 6, 1.f);
}
GrTestTarget tt;
context->getTestTarget(&tt);
if (NULL == tt.target()) {
continue;
}
GrDrawState* drawState = tt.target()->drawState();
drawState->setVertexAttribs<kAttribs>(2);
SkAutoTUnref<GrEffectRef> effect(GrConicEffect::Create(
GrBezierEdgeType(edgeType), *tt.target()->caps()));
if (!effect) {
continue;
}
drawState->addCoverageEffect(effect, 1);
drawState->setRenderTarget(rt);
drawState->setColor(0xff000000);
tt.target()->setVertexSourceToArray(verts, 4);
tt.target()->setIndexSourceToBuffer(context->getQuadIndexBuffer());
tt.target()->drawIndexed(kTriangleFan_GrPrimitiveType, 0, 0, 4, 6);
}
++col;
if (numCols == col) {
col = 0;
++row;
}
}
}
}
private:
// Uses the max curvature function for quads to estimate
// where to chop the conic. If the max curvature is not
// found along the curve segment it will return 1 and
// dst[0] is the original conic. If it returns 2 the dst[0]
// and dst[1] are the two new conics.
int split_conic(const SkPoint src[3], SkConic dst[2], const SkScalar weight) {
SkScalar t = SkFindQuadMaxCurvature(src);
if (t == 0) {
if (dst) {
dst[0].set(src, weight);
}
return 1;
} else {
if (dst) {
SkConic conic;
conic.set(src, weight);
conic.chopAt(t, dst);
}
return 2;
}
}
// Calls split_conic on the entire conic and then once more on each subsection.
// Most cases will result in either 1 conic (chop point is not within t range)
// or 3 points (split once and then one subsection is split again).
int chop_conic(const SkPoint src[3], SkConic dst[4], const SkScalar weight) {
SkConic dstTemp[2];
int conicCnt = split_conic(src, dstTemp, weight);
if (2 == conicCnt) {
int conicCnt2 = split_conic(dstTemp[0].fPts, dst, dstTemp[0].fW);
conicCnt = conicCnt2 + split_conic(dstTemp[1].fPts, &dst[conicCnt2], dstTemp[1].fW);
} else {
dst[0] = dstTemp[0];
}
return conicCnt;
}
typedef GM INHERITED;
};
//////////////////////////////////////////////////////////////////////////////
/**
* This GM directly exercises effects that draw Bezier quad curves in the GPU backend.
*/
class BezierQuadEffects : public GM {
public:
BezierQuadEffects() {
this->setBGColor(0xFFFFFFFF);
}
protected:
virtual SkString onShortName() SK_OVERRIDE {
return SkString("bezier_quad_effects");
}
virtual SkISize onISize() SK_OVERRIDE {
return make_isize(800, 800);
}
virtual uint32_t onGetFlags() const SK_OVERRIDE {
// This is a GPU-specific GM.
return kGPUOnly_Flag;
}
virtual void onDraw(SkCanvas* canvas) SK_OVERRIDE {
SkBaseDevice* device = canvas->getTopDevice();
GrRenderTarget* rt = device->accessRenderTarget();
if (NULL == rt) {
return;
}
GrContext* context = rt->getContext();
if (NULL == context) {
return;
}
struct Vertex {
SkPoint fPosition;
float fUV[4]; // The last two values are ignored. The effect expects a vec4f.
};
static const int kNumQuads = 5;
SkRandom rand;
int numCols = SkScalarCeilToInt(SkScalarSqrt(SkIntToScalar(kNumQuads*3)));
int numRows = SkScalarCeilToInt(SkIntToScalar(kNumQuads*3) / numCols);
SkScalar w = SkIntToScalar(rt->width()) / numCols;
SkScalar h = SkIntToScalar(rt->height()) / numRows;
int row = 0;
int col = 0;
for (int i = 0; i < kNumQuads; ++i) {
SkPoint baseControlPts[] = {
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)},
{rand.nextRangeF(0.f, w), rand.nextRangeF(0.f, h)}
};
for(int edgeType = kFillAA_GrBezierEdgeType; edgeType < 3; ++edgeType) {
SkScalar x = SkScalarMul(col, w);
SkScalar y = SkScalarMul(row, h);
SkPoint controlPts[] = {
{x + baseControlPts[0].fX, y + baseControlPts[0].fY},
{x + baseControlPts[1].fX, y + baseControlPts[1].fY},
{x + baseControlPts[2].fX, y + baseControlPts[2].fY}
};
SkPoint chopped[5];
int cnt = SkChopQuadAtMaxCurvature(controlPts, chopped);
SkPaint ctrlPtPaint;
ctrlPtPaint.setColor(rand.nextU() | 0xFF000000);
for (int i = 0; i < 3; ++i) {
canvas->drawCircle(controlPts[i].fX, controlPts[i].fY, 6.f, ctrlPtPaint);
}
SkPaint polyPaint;
polyPaint.setColor(0xffA0A0A0);
polyPaint.setStrokeWidth(0);
polyPaint.setStyle(SkPaint::kStroke_Style);
canvas->drawPoints(SkCanvas::kPolygon_PointMode, 3, controlPts, polyPaint);
SkPaint choppedPtPaint;
choppedPtPaint.setColor(~ctrlPtPaint.getColor() | 0xFF000000);
for (int c = 0; c < cnt; ++c) {
SkPoint* pts = chopped + 2 * c;
for (int i = 0; i < 3; ++i) {
canvas->drawCircle(pts[i].fX, pts[i].fY, 3.f, choppedPtPaint);
}
SkRect bounds;
bounds.set(pts, 3);
SkPaint boundsPaint;
boundsPaint.setColor(0xff808080);
boundsPaint.setStrokeWidth(0);
boundsPaint.setStyle(SkPaint::kStroke_Style);
canvas->drawRect(bounds, boundsPaint);
Vertex verts[4];
verts[0].fPosition.setRectFan(bounds.fLeft, bounds.fTop,
bounds.fRight, bounds.fBottom,
sizeof(Vertex));
GrPathUtils::QuadUVMatrix DevToUV(pts);
DevToUV.apply<4, sizeof(Vertex), sizeof(GrPoint)>(verts);
GrTestTarget tt;
context->getTestTarget(&tt);
if (NULL == tt.target()) {
continue;
}
GrDrawState* drawState = tt.target()->drawState();
drawState->setVertexAttribs<kAttribs>(2);
SkAutoTUnref<GrEffectRef> effect(GrQuadEffect::Create(
GrBezierEdgeType(edgeType), *tt.target()->caps()));
if (!effect) {
continue;
}
drawState->addCoverageEffect(effect, 1);
drawState->setRenderTarget(rt);
drawState->setColor(0xff000000);
tt.target()->setVertexSourceToArray(verts, 4);
tt.target()->setIndexSourceToBuffer(context->getQuadIndexBuffer());
tt.target()->drawIndexed(kTriangles_GrPrimitiveType, 0, 0, 4, 6);
}
++col;
if (numCols == col) {
col = 0;
++row;
}
}
}
}
private:
typedef GM INHERITED;
};
DEF_GM( return SkNEW(BezierCubicEffects); )
DEF_GM( return SkNEW(BezierConicEffects); )
DEF_GM( return SkNEW(BezierQuadEffects); )
}
#endif
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