blob: 0908e3d4237e1e978eaa9e391ad6efdd62de3e78 [file] [log] [blame]
/*
* Copyright 2011 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "include/core/SkMatrix.h"
#include "include/core/SkPoint.h"
#include "include/core/SkScalar.h"
#include "include/core/SkSpan.h"
#include "include/core/SkTypes.h"
#include "include/utils/SkRandom.h"
#include "src/core/SkGeometry.h"
#include "src/core/SkPointPriv.h"
#include "tests/Test.h"
#include <array>
#include <cmath>
#include <cstdlib>
#include <limits>
#include <string>
static bool nearly_equal(const SkPoint& a, const SkPoint& b) {
return SkScalarNearlyEqual(a.fX, b.fX) && SkScalarNearlyEqual(a.fY, b.fY);
}
static void testChopCubic(skiatest::Reporter* reporter) {
/*
Inspired by this test, which used to assert that the tValues had dups
<path stroke="#202020" d="M0,0 C0,0 1,1 2190,5130 C2190,5070 2220,5010 2205,4980" />
*/
const SkPoint src[] = {
{ SkIntToScalar(2190), SkIntToScalar(5130) },
{ SkIntToScalar(2190), SkIntToScalar(5070) },
{ SkIntToScalar(2220), SkIntToScalar(5010) },
{ SkIntToScalar(2205), SkIntToScalar(4980) },
};
SkPoint dst[13];
SkScalar tValues[3];
// make sure we don't assert internally
int count = SkChopCubicAtMaxCurvature(src, dst, tValues);
if ((false)) { // avoid bit rot, suppress warning
REPORTER_ASSERT(reporter, count);
}
// Make sure src and dst can be the same pointer.
{
SkPoint pts[7];
for (int i = 0; i < 7; ++i) {
pts[i].set(i, i);
}
SkChopCubicAt(pts, pts, .5f);
for (int i = 0; i < 7; ++i) {
REPORTER_ASSERT(reporter, pts[i].fX == pts[i].fY);
REPORTER_ASSERT(reporter, pts[i].fX == i * .5f);
}
}
static const float chopTs[] = {
0, 3/83.f, 3/79.f, 3/73.f, 3/71.f, 3/67.f, 3/61.f, 3/59.f, 3/53.f, 3/47.f, 3/43.f, 3/41.f,
3/37.f, 3/31.f, 3/29.f, 3/23.f, 3/19.f, 3/17.f, 3/13.f, 3/11.f, 3/7.f, 3/5.f, 1,
};
float ones[] = {1,1,1,1,1};
// Ensure an odd number of T values so we exercise the single chop code at the end of
// SkChopCubicAt form multiple T.
static_assert(std::size(chopTs) % 2 == 1);
static_assert(std::size(ones) % 2 == 1);
SkRandom rand;
for (int iterIdx = 0; iterIdx < 5; ++iterIdx) {
SkPoint pts[4] = {{rand.nextF(), rand.nextF()}, {rand.nextF(), rand.nextF()},
{rand.nextF(), rand.nextF()}, {rand.nextF(), rand.nextF()}};
SkPoint allChops[4 + std::size(chopTs)*3];
SkChopCubicAt(pts, allChops, chopTs, std::size(chopTs));
int i = 3;
for (float chopT : chopTs) {
// Ensure we chop at approximately the correct points when we chop an entire list.
SkPoint expectedPt;
SkEvalCubicAt(pts, chopT, &expectedPt, nullptr, nullptr);
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(allChops[i].x(), expectedPt.x()));
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(allChops[i].y(), expectedPt.y()));
if (chopT == 0) {
REPORTER_ASSERT(reporter, allChops[i] == pts[0]);
}
if (chopT == 1) {
REPORTER_ASSERT(reporter, allChops[i] == pts[3]);
}
i += 3;
// Ensure the middle is exactly degenerate when we chop at two equal points.
SkPoint localChops[10];
SkChopCubicAt(pts, localChops, chopT, chopT);
REPORTER_ASSERT(reporter, localChops[3] == localChops[4]);
REPORTER_ASSERT(reporter, localChops[3] == localChops[5]);
REPORTER_ASSERT(reporter, localChops[3] == localChops[6]);
if (chopT == 0) {
// Also ensure the first curve is exactly p0 when we chop at T=0.
REPORTER_ASSERT(reporter, localChops[0] == pts[0]);
REPORTER_ASSERT(reporter, localChops[1] == pts[0]);
REPORTER_ASSERT(reporter, localChops[2] == pts[0]);
REPORTER_ASSERT(reporter, localChops[3] == pts[0]);
}
if (chopT == 1) {
// Also ensure the last curve is exactly p3 when we chop at T=1.
REPORTER_ASSERT(reporter, localChops[6] == pts[3]);
REPORTER_ASSERT(reporter, localChops[7] == pts[3]);
REPORTER_ASSERT(reporter, localChops[8] == pts[3]);
REPORTER_ASSERT(reporter, localChops[9] == pts[3]);
}
}
// Now test what happens when SkChopCubicAt does 0/0 and gets NaN values.
SkPoint oneChops[4 + std::size(ones)*3];
SkChopCubicAt(pts, oneChops, ones, std::size(ones));
REPORTER_ASSERT(reporter, oneChops[0] == pts[0]);
REPORTER_ASSERT(reporter, oneChops[1] == pts[1]);
REPORTER_ASSERT(reporter, oneChops[2] == pts[2]);
for (size_t index = 3; index < std::size(oneChops); ++index) {
REPORTER_ASSERT(reporter, oneChops[index] == pts[3]);
}
}
}
static void check_pairs(skiatest::Reporter* reporter, int index, SkScalar t, const char name[],
SkScalar x0, SkScalar y0, SkScalar x1, SkScalar y1) {
bool eq = SkScalarNearlyEqual(x0, x1) && SkScalarNearlyEqual(y0, y1);
if (!eq) {
SkDebugf("%s [%d %g] p0 [%10.8f %10.8f] p1 [%10.8f %10.8f]\n",
name, index, t, x0, y0, x1, y1);
REPORTER_ASSERT(reporter, eq);
}
}
static void test_evalquadat(skiatest::Reporter* reporter) {
SkRandom rand;
for (int i = 0; i < 1000; ++i) {
SkPoint pts[3];
for (int j = 0; j < 3; ++j) {
pts[j].set(rand.nextSScalar1() * 100, rand.nextSScalar1() * 100);
}
const SkScalar dt = SK_Scalar1 / 128;
SkScalar t = dt;
for (int j = 1; j < 128; ++j) {
SkPoint r0;
SkEvalQuadAt(pts, t, &r0);
SkPoint r1 = SkEvalQuadAt(pts, t);
check_pairs(reporter, i, t, "quad-pos", r0.fX, r0.fY, r1.fX, r1.fY);
SkVector v0;
SkEvalQuadAt(pts, t, nullptr, &v0);
SkVector v1 = SkEvalQuadTangentAt(pts, t);
check_pairs(reporter, i, t, "quad-tan", v0.fX, v0.fY, v1.fX, v1.fY);
t += dt;
}
}
}
static void test_conic_eval_pos(skiatest::Reporter* reporter, const SkConic& conic, SkScalar t) {
SkPoint p0, p1;
conic.evalAt(t, &p0, nullptr);
p1 = conic.evalAt(t);
check_pairs(reporter, 0, t, "conic-pos", p0.fX, p0.fY, p1.fX, p1.fY);
}
static void test_conic_eval_tan(skiatest::Reporter* reporter, const SkConic& conic, SkScalar t) {
SkVector v0, v1;
conic.evalAt(t, nullptr, &v0);
v1 = conic.evalTangentAt(t);
check_pairs(reporter, 0, t, "conic-tan", v0.fX, v0.fY, v1.fX, v1.fY);
}
static void test_conic(skiatest::Reporter* reporter) {
SkRandom rand;
for (int i = 0; i < 1000; ++i) {
SkPoint pts[3];
for (int j = 0; j < 3; ++j) {
pts[j].set(rand.nextSScalar1() * 100, rand.nextSScalar1() * 100);
}
for (int k = 0; k < 10; ++k) {
SkScalar w = rand.nextUScalar1() * 2;
SkConic conic(pts, w);
const SkScalar dt = SK_Scalar1 / 128;
SkScalar t = dt;
for (int j = 1; j < 128; ++j) {
test_conic_eval_pos(reporter, conic, t);
test_conic_eval_tan(reporter, conic, t);
t += dt;
}
}
}
}
static void test_quad_tangents(skiatest::Reporter* reporter) {
SkPoint pts[] = {
{10, 20}, {10, 20}, {20, 30},
{10, 20}, {15, 25}, {20, 30},
{10, 20}, {20, 30}, {20, 30},
};
int count = (int) std::size(pts) / 3;
for (int index = 0; index < count; ++index) {
SkConic conic(&pts[index * 3], 0.707f);
SkVector start = SkEvalQuadTangentAt(&pts[index * 3], 0);
SkVector mid = SkEvalQuadTangentAt(&pts[index * 3], .5f);
SkVector end = SkEvalQuadTangentAt(&pts[index * 3], 1);
REPORTER_ASSERT(reporter, start.fX && start.fY);
REPORTER_ASSERT(reporter, mid.fX && mid.fY);
REPORTER_ASSERT(reporter, end.fX && end.fY);
REPORTER_ASSERT(reporter, SkScalarNearlyZero(start.cross(mid)));
REPORTER_ASSERT(reporter, SkScalarNearlyZero(mid.cross(end)));
}
}
static void test_conic_tangents(skiatest::Reporter* reporter) {
SkPoint pts[] = {
{ 10, 20}, {10, 20}, {20, 30},
{ 10, 20}, {15, 25}, {20, 30},
{ 10, 20}, {20, 30}, {20, 30}
};
int count = (int) std::size(pts) / 3;
for (int index = 0; index < count; ++index) {
SkConic conic(&pts[index * 3], 0.707f);
SkVector start = conic.evalTangentAt(0);
SkVector mid = conic.evalTangentAt(.5f);
SkVector end = conic.evalTangentAt(1);
REPORTER_ASSERT(reporter, start.fX && start.fY);
REPORTER_ASSERT(reporter, mid.fX && mid.fY);
REPORTER_ASSERT(reporter, end.fX && end.fY);
REPORTER_ASSERT(reporter, SkScalarNearlyZero(start.cross(mid)));
REPORTER_ASSERT(reporter, SkScalarNearlyZero(mid.cross(end)));
}
}
static void test_this_conic_to_quad(skiatest::Reporter* r, const SkPoint pts[3], SkScalar w) {
SkAutoConicToQuads quadder;
const SkPoint* qpts = quadder.computeQuads(pts, w, 0.25);
const int qcount = quadder.countQuads();
const int pcount = qcount * 2 + 1;
REPORTER_ASSERT(r, SkPointPriv::AreFinite(qpts, pcount));
}
/**
* We need to ensure that when a conic is approximated by quads, that we always return finite
* values in the quads.
*
* Inspired by crbug_627414
*/
static void test_conic_to_quads(skiatest::Reporter* reporter) {
const SkPoint triples[] = {
{ 0, 0 }, { 1, 0 }, { 1, 1 },
{ 0, 0 }, { 3.58732e-43f, 2.72084f }, { 3.00392f, 3.00392f },
{ 0, 0 }, { 100000, 0 }, { 100000, 100000 },
{ 0, 0 }, { 1e30f, 0 }, { 1e30f, 1e30f },
};
const int N = sizeof(triples) / sizeof(SkPoint);
for (int i = 0; i < N; i += 3) {
const SkPoint* pts = &triples[i];
SkScalar w = 1e30f;
do {
w *= 2;
test_this_conic_to_quad(reporter, pts, w);
} while (SkScalarIsFinite(w));
test_this_conic_to_quad(reporter, pts, SK_ScalarNaN);
}
}
static void test_cubic_tangents(skiatest::Reporter* reporter) {
SkPoint pts[] = {
{ 10, 20}, {10, 20}, {20, 30}, {30, 40},
{ 10, 20}, {15, 25}, {20, 30}, {30, 40},
{ 10, 20}, {20, 30}, {30, 40}, {30, 40},
};
int count = (int) std::size(pts) / 4;
for (int index = 0; index < count; ++index) {
SkConic conic(&pts[index * 3], 0.707f);
SkVector start, mid, end;
SkEvalCubicAt(&pts[index * 4], 0, nullptr, &start, nullptr);
SkEvalCubicAt(&pts[index * 4], .5f, nullptr, &mid, nullptr);
SkEvalCubicAt(&pts[index * 4], 1, nullptr, &end, nullptr);
REPORTER_ASSERT(reporter, start.fX && start.fY);
REPORTER_ASSERT(reporter, mid.fX && mid.fY);
REPORTER_ASSERT(reporter, end.fX && end.fY);
REPORTER_ASSERT(reporter, SkScalarNearlyZero(start.cross(mid)));
REPORTER_ASSERT(reporter, SkScalarNearlyZero(mid.cross(end)));
}
}
static void check_cubic_type(skiatest::Reporter* reporter,
const std::array<SkPoint, 4>& bezierPoints, SkCubicType expectedType,
bool undefined = false) {
// Classify the cubic even if the results will be undefined: check for crashes and asserts.
SkCubicType actualType = SkClassifyCubic(bezierPoints.data());
if (!undefined) {
REPORTER_ASSERT(reporter, actualType == expectedType);
}
}
static void check_cubic_around_rect(skiatest::Reporter* reporter,
float x1, float y1, float x2, float y2,
bool undefined = false) {
static constexpr SkCubicType expectations[24] = {
SkCubicType::kLoop,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLocalCusp,
SkCubicType::kLocalCusp,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLoop,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLoop,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLoop,
SkCubicType::kLocalCusp,
SkCubicType::kLocalCusp,
SkCubicType::kLocalCusp,
SkCubicType::kLocalCusp,
SkCubicType::kLoop,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLoop,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLoop,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLocalCusp,
SkCubicType::kLocalCusp,
SkCubicType::kCuspAtInfinity,
SkCubicType::kLoop,
};
SkPoint points[] = {{x1, y1}, {x2, y1}, {x2, y2}, {x1, y2}};
std::array<SkPoint, 4> bezier;
for (int i=0; i < 4; ++i) {
bezier[0] = points[i];
for (int j=0; j < 3; ++j) {
int jidx = (j < i) ? j : j+1;
bezier[1] = points[jidx];
for (int k=0, kidx=0; k < 2; ++k, ++kidx) {
for (int n = 0; n < 2; ++n) {
kidx = (kidx == i || kidx == jidx) ? kidx+1 : kidx;
}
bezier[2] = points[kidx];
for (int l = 0; l < 4; ++l) {
if (l != i && l != jidx && l != kidx) {
bezier[3] = points[l];
break;
}
}
check_cubic_type(reporter, bezier, expectations[i*6 + j*2 + k], undefined);
}
}
}
for (int i=0; i < 4; ++i) {
bezier[0] = points[i];
for (int j=0; j < 3; ++j) {
int jidx = (j < i) ? j : j+1;
bezier[1] = points[jidx];
bezier[2] = points[jidx];
for (int k=0, kidx=0; k < 2; ++k, ++kidx) {
for (int n = 0; n < 2; ++n) {
kidx = (kidx == i || kidx == jidx) ? kidx+1 : kidx;
}
bezier[3] = points[kidx];
check_cubic_type(reporter, bezier, SkCubicType::kSerpentine, undefined);
}
}
}
}
static std::array<SkPoint, 4> kSerpentines[] = {
{{{149.325f, 107.705f}, {149.325f, 103.783f}, {151.638f, 100.127f}, {156.263f, 96.736f}}},
{{{225.694f, 223.15f}, {209.831f, 224.837f}, {195.994f, 230.237f}, {184.181f, 239.35f}}},
{{{4.873f, 5.581f}, {5.083f, 5.2783f}, {5.182f, 4.8593f}, {5.177f, 4.3242f}}},
{{{285.625f, 499.687f}, {411.625f, 808.188f}, {1064.62f, 135.688f}, {1042.63f, 585.187f}}}
};
static std::array<SkPoint, 4> kLoops[] = {
{{{635.625f, 614.687f}, {171.625f, 236.188f}, {1064.62f, 135.688f}, {516.625f, 570.187f}}},
{{{653.050f, 725.049f}, {663.000f, 176.000f}, {1189.000f, 508.000f}, {288.050f, 564.950f}}},
{{{631.050f, 478.049f}, {730.000f, 302.000f}, {870.000f, 350.000f}, {905.050f, 528.950f}}},
{{{631.050f, 478.0499f}, {221.000f, 230.000f}, {1265.000f, 451.000f}, {905.050f, 528.950f}}}
};
static std::array<SkPoint, 4> kLinearCubics[] = {
{{{0, 0}, {0, 1}, {0, 2}, {0, 3}}}, // 0-degree flat line.
{{{0, 0}, {1, 0}, {1, 0}, {0, 0}}}, // 180-degree flat line
{{{0, 1}, {0, 0}, {0, 2}, {0, 3}}}, // 180-degree flat line
{{{0, 1}, {0, 0}, {0, 3}, {0, 2}}}, // 360-degree flat line
{{{0, 0}, {2, 0}, {1, 0}, {64, 0}}}, // 360-degree flat line
{{{1, 0}, {0, 0}, {3, 0}, {-64, 0}}} // 360-degree flat line
};
static void test_classify_cubic(skiatest::Reporter* reporter) {
for (const auto& serp : kSerpentines) {
check_cubic_type(reporter, serp, SkCubicType::kSerpentine);
}
for (const auto& loop : kLoops) {
check_cubic_type(reporter, loop, SkCubicType::kLoop);
}
for (const auto& loop : kLinearCubics) {
check_cubic_type(reporter, loop, SkCubicType::kLineOrPoint);
}
check_cubic_around_rect(reporter, 0, 0, 1, 1);
check_cubic_around_rect(reporter,
-std::numeric_limits<float>::max(),
-std::numeric_limits<float>::max(),
+std::numeric_limits<float>::max(),
+std::numeric_limits<float>::max());
check_cubic_around_rect(reporter, 1, 1,
+std::numeric_limits<float>::min(),
+std::numeric_limits<float>::max());
check_cubic_around_rect(reporter,
-std::numeric_limits<float>::min(),
-std::numeric_limits<float>::min(),
+std::numeric_limits<float>::min(),
+std::numeric_limits<float>::min());
check_cubic_around_rect(reporter, +1, -std::numeric_limits<float>::min(), -1, -1);
check_cubic_around_rect(reporter,
-std::numeric_limits<float>::infinity(),
-std::numeric_limits<float>::infinity(),
+std::numeric_limits<float>::infinity(),
+std::numeric_limits<float>::infinity(),
true);
check_cubic_around_rect(reporter, 0, 0, 1, +std::numeric_limits<float>::infinity(), true);
check_cubic_around_rect(reporter,
-std::numeric_limits<float>::quiet_NaN(),
-std::numeric_limits<float>::quiet_NaN(),
+std::numeric_limits<float>::quiet_NaN(),
+std::numeric_limits<float>::quiet_NaN(),
true);
check_cubic_around_rect(reporter, 0, 0, 1, +std::numeric_limits<float>::quiet_NaN(), true);
}
static std::array<SkPoint, 4> kCusps[] = {
{{{0, 0}, {1, 1}, {1, 0}, {0, 1}}},
{{{0, 0}, {1, 1}, {0, 1}, {1, 0}}},
{{{0, 1}, {1, 0}, {0, 0}, {1, 1}}},
{{{0, 1}, {1, 0}, {1, 1}, {0, 0}}},
};
static void test_cubic_cusps(skiatest::Reporter* reporter) {
std::array<SkPoint, 4> noCusps[] = {
{{{0, 0}, {1, 1}, {2, 2}, {3, 3}}},
{{{0, 0}, {1, 0}, {1, 1}, {0, 1}}},
{{{0, 0}, {1, 0}, {2, 1}, {2, 2}}},
{{{0, 0}, {1, 0}, {1, 1}, {2, 1}}},
};
for (auto noCusp : noCusps) {
REPORTER_ASSERT(reporter, SkFindCubicCusp(noCusp.data()) < 0);
}
for (auto cusp : kCusps) {
REPORTER_ASSERT(reporter, SkFindCubicCusp(cusp.data()) > 0);
}
}
static SkMatrix kSkewMatrices[] = {
SkMatrix::MakeAll(1,0,0, 0,1,0, 0,0,1),
SkMatrix::MakeAll(1,-1,0, 1,1,0, 0,0,1),
SkMatrix::MakeAll(.889f,.553f,0, -.443f,.123f,0, 0,0,1),
};
static void test_chop_quad_at_midtangent(skiatest::Reporter* reporter, const SkPoint pts[3]) {
constexpr float kTolerance = 1e-3f;
for (const SkMatrix& m : kSkewMatrices) {
SkPoint mapped[3];
m.mapPoints(mapped, pts, 3);
float fullRotation = SkMeasureQuadRotation(pts);
SkPoint chopped[5];
SkChopQuadAtMidTangent(pts, chopped);
float leftRotation = SkMeasureQuadRotation(chopped);
float rightRotation = SkMeasureQuadRotation(chopped+2);
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(leftRotation, fullRotation/2, kTolerance));
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(rightRotation, fullRotation/2, kTolerance));
}
}
static void test_chop_cubic_at_midtangent(skiatest::Reporter* reporter, const SkPoint pts[4],
SkCubicType cubicType) {
constexpr float kTolerance = 1e-3f;
int n = std::size(kSkewMatrices);
if (cubicType == SkCubicType::kLocalCusp || cubicType == SkCubicType::kLineOrPoint) {
// FP precision isn't always enough to get the exact correct T value of the mid-tangent on
// cusps and lines. Only test the identity matrix and the matrix with all 1's.
n = 2;
}
for (int i = 0; i < n; ++i) {
SkPoint mapped[4];
kSkewMatrices[i].mapPoints(mapped, pts, 4);
float fullRotation = SkMeasureNonInflectCubicRotation(mapped);
SkPoint chopped[7];
SkChopCubicAtMidTangent(mapped, chopped);
float leftRotation = SkMeasureNonInflectCubicRotation(chopped);
float rightRotation = SkMeasureNonInflectCubicRotation(chopped+3);
if (cubicType == SkCubicType::kLineOrPoint &&
(SkScalarNearlyEqual(fullRotation, 2*SK_ScalarPI, kTolerance) ||
SkScalarNearlyEqual(fullRotation, 0, kTolerance))) {
// 0- and 360-degree flat lines don't have single points of midtangent.
// (tangent == midtangent at every point on these curves except the cusp points.)
// Instead verify the promise from SkChopCubicAtMidTangent that neither side will rotate
// more than 180 degrees.
REPORTER_ASSERT(reporter, std::abs(leftRotation) - kTolerance <= SK_ScalarPI);
REPORTER_ASSERT(reporter, std::abs(rightRotation) - kTolerance <= SK_ScalarPI);
continue;
}
float expectedChoppedRotation = fullRotation/2;
if (cubicType == SkCubicType::kLocalCusp ||
(cubicType == SkCubicType::kLineOrPoint &&
SkScalarNearlyEqual(fullRotation, SK_ScalarPI, kTolerance))) {
// If we chop a cubic at a cusp, we lose 180 degrees of rotation.
expectedChoppedRotation = (fullRotation - SK_ScalarPI)/2;
}
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(leftRotation, expectedChoppedRotation,
kTolerance));
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(rightRotation, expectedChoppedRotation,
kTolerance));
}
}
static std::array<SkPoint, 3> kQuads[] = {
{{{10, 20}, {15, 35}, {30, 40}}},
{{{176.324f, 392.705f}, {719.325f, 205.782f}, {297.263f, 347.735f}}},
{{{652.050f, 602.049f}, {481.000f, 533.000f}, {288.050f, 564.950f}}},
{{{460.625f, 557.187f}, {707.121f, 209.688f}, {779.628f, 577.687f}}},
{{{359.050f, 578.049f}, {759.000f, 274.000f}, {288.050f, 564.950f}}}
};
SkPoint lerp(const SkPoint& a, const SkPoint& b, float t) {
return a * (1 - t) + b * t;
}
static void test_measure_rotation(skiatest::Reporter* reporter) {
static SkPoint kFlatCubic[4] = {{0, 0}, {0, 1}, {0, 2}, {0, 3}};
REPORTER_ASSERT(reporter, SkScalarNearlyZero(SkMeasureNonInflectCubicRotation(kFlatCubic)));
static SkPoint kFlatCubic180_1[4] = {{0, 0}, {1, 0}, {3, 0}, {2, 0}};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(kFlatCubic180_1),
SK_ScalarPI));
static SkPoint kFlatCubic180_2[4] = {{0, 1}, {0, 0}, {0, 2}, {0, 3}};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(kFlatCubic180_2),
SK_ScalarPI));
static SkPoint kFlatCubic360[4] = {{0, 1}, {0, 0}, {0, 3}, {0, 2}};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(kFlatCubic360),
2*SK_ScalarPI));
static SkPoint kSquare180[4] = {{0, 0}, {0, 1}, {1, 1}, {1, 0}};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(kSquare180),
SK_ScalarPI));
auto checkQuadRotation = [=](const SkPoint pts[3], float expectedRotation) {
float r = SkMeasureQuadRotation(pts);
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(r, expectedRotation));
SkPoint cubic1[4] = {pts[0], pts[0], pts[1], pts[2]};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(cubic1),
expectedRotation));
SkPoint cubic2[4] = {pts[0], pts[1], pts[1], pts[2]};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(cubic2),
expectedRotation));
SkPoint cubic3[4] = {pts[0], pts[1], pts[2], pts[2]};
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(SkMeasureNonInflectCubicRotation(cubic3),
expectedRotation));
};
static SkPoint kFlatQuad[4] = {{0, 0}, {0, 1}, {0, 2}};
checkQuadRotation(kFlatQuad, 0);
static SkPoint kFlatQuad180_1[4] = {{1, 0}, {0, 0}, {2, 0}};
checkQuadRotation(kFlatQuad180_1, SK_ScalarPI);
static SkPoint kFlatQuad180_2[4] = {{0, 0}, {0, 2}, {0, 1}};
checkQuadRotation(kFlatQuad180_2, SK_ScalarPI);
static SkPoint kTri120[3] = {{0, 0}, {.5f, std::sqrt(3.f)/2}, {1, 0}};
checkQuadRotation(kTri120, 2*SK_ScalarPI/3);
}
static void test_chop_at_midtangent(skiatest::Reporter* reporter) {
SkPoint chops[10];
for (const auto& serp : kSerpentines) {
REPORTER_ASSERT(reporter, SkClassifyCubic(serp.data()) == SkCubicType::kSerpentine);
int n = SkChopCubicAtInflections(serp.data(), chops);
for (int i = 0; i < n; ++i) {
test_chop_cubic_at_midtangent(reporter, chops + i*3, SkCubicType::kSerpentine);
}
}
for (const auto& loop : kLoops) {
REPORTER_ASSERT(reporter, SkClassifyCubic(loop.data()) == SkCubicType::kLoop);
test_chop_cubic_at_midtangent(reporter, loop.data(), SkCubicType::kLoop);
}
for (const auto& line : kLinearCubics) {
REPORTER_ASSERT(reporter, SkClassifyCubic(line.data()) == SkCubicType::kLineOrPoint);
test_chop_cubic_at_midtangent(reporter, line.data(), SkCubicType::kLineOrPoint);
}
for (const auto& cusp : kCusps) {
REPORTER_ASSERT(reporter, SkClassifyCubic(cusp.data()) == SkCubicType::kLocalCusp);
test_chop_cubic_at_midtangent(reporter, cusp.data(), SkCubicType::kLocalCusp);
}
for (const auto& quad : kQuads) {
test_chop_quad_at_midtangent(reporter, quad.data());
SkPoint asCubic[4] = {
quad[0], lerp(quad[0], quad[1], 2/3.f), lerp(quad[1], quad[2], 1/3.f), quad[2]};
test_chop_cubic_at_midtangent(reporter, asCubic, SkCubicType::kQuadratic);
}
static const SkPoint kExactQuad[4] = {{0,0}, {6,2}, {10,2}, {12,0}};
REPORTER_ASSERT(reporter, SkClassifyCubic(kExactQuad) == SkCubicType::kQuadratic);
test_chop_cubic_at_midtangent(reporter, kExactQuad, SkCubicType::kQuadratic);
static const SkPoint kExactCuspAtInf[4] = {{0,0}, {1,0}, {0,1}, {1,1}};
REPORTER_ASSERT(reporter, SkClassifyCubic(kExactCuspAtInf) == SkCubicType::kCuspAtInfinity);
int n = SkChopCubicAtInflections(kExactCuspAtInf, chops);
for (int i = 0; i < n; ++i) {
test_chop_cubic_at_midtangent(reporter, chops + i*3, SkCubicType::kCuspAtInfinity);
}
}
DEF_TEST(Geometry, reporter) {
SkPoint pts[5];
pts[0].set(0, 0);
pts[1].set(100, 50);
pts[2].set(0, 100);
int count = SkChopQuadAtMaxCurvature(pts, pts); // Ensure src and dst can be the same pointer.
REPORTER_ASSERT(reporter, count == 1 || count == 2);
// This previously crashed because the computed t of max curvature is NaN and SkChopQuadAt
// asserts that the passed t is in 0..1. Passes by not asserting.
pts[0].set(15.1213f, 7.77647f);
pts[1].set(6.2168e+19f, 1.51338e+20f);
pts[2].set(1.4579e+19f, 1.55558e+21f);
count = SkChopQuadAtMaxCurvature(pts, pts);
pts[0].set(0, 0);
pts[1].set(3, 0);
pts[2].set(3, 3);
SkConvertQuadToCubic(pts, pts);
const SkPoint cubic[] = {
{ 0, 0, }, { 2, 0, }, { 3, 1, }, { 3, 3 },
};
for (int i = 0; i < 4; ++i) {
REPORTER_ASSERT(reporter, nearly_equal(cubic[i], pts[i]));
}
testChopCubic(reporter);
test_evalquadat(reporter);
test_conic(reporter);
test_cubic_tangents(reporter);
test_quad_tangents(reporter);
test_conic_tangents(reporter);
test_conic_to_quads(reporter);
test_classify_cubic(reporter);
test_cubic_cusps(reporter);
test_measure_rotation(reporter);
test_chop_at_midtangent(reporter);
}
static void testChopMonoCubicAtY(skiatest::Reporter* reporter, std::string name,
SkSpan<const SkPoint> curveInputs, SkScalar yToChopAt,
SkSpan<const SkPoint> expectedOutputs) {
skiatest::ReporterContext subtest(reporter, name);
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(expectedOutputs[3].y(), yToChopAt),
"Invalid test case. 4th point's Y should be %f", yToChopAt);
SkPoint outputs[7];
// Make sure it actually chopped
REPORTER_ASSERT(reporter, SkChopMonoCubicAtY(curveInputs.begin(), yToChopAt, outputs));
for (int i = 0; i < 7; ++i) {
REPORTER_ASSERT(reporter, nearly_equal(expectedOutputs[i], outputs[i]),
"(%f, %f) != (%f, %f) at index %d",
expectedOutputs[i].x(), expectedOutputs[i].y(),
outputs[i].x(), outputs[i].y(), i);
}
}
DEF_TEST(GeometryChopMonoCubicAtY_Successful, reporter) {
// These cubics are all arbitrary, picked using Desmos for something that looked "nice".
testChopMonoCubicAtY(reporter, "straight, positive slope @ 2.5",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
2.5f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 1.065055f, 1.065055f },
{ 2.500000f, 2.500000f },
{ 5.461981f, 5.461981f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtY(reporter, "straight, positive slope @ 5.0",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
5.0f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 2.500000f, 2.500000f },
{ 5.000000f, 5.000000f },
{ 7.500000f, 7.500000f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtY(reporter, "straight, positive slope @ 9.0",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
9.0f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 6.467375f, 6.467375f },
{ 9.000000f, 9.000000f },
{ 9.616623f, 9.616623f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtY(reporter, "straight, positive slope @ 10.0",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
10.0f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 10.000000f, 10.000000f },
{ 10.000000f, 10.000000f },
{ 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtY(reporter, "curve, positive slope @ 2.0",
{{ 1, 1 }, { 5, 2 }, { 7, 4 }, { 8, 7 }},
2.0f,
{{ 1.000000f, 1.000000f }, { 2.055050f, 1.263763f }, { 2.970959f, 1.597096f },
{ 3.766077f, 2.000000f },
{ 5.985480f, 3.124621f }, { 7.263762f, 4.791288f }, { 8.000000f, 7.000000f }}
);
testChopMonoCubicAtY(reporter, "curve, positive slope @ 5.0",
{{ 1, 1 }, { 5, 2 }, { 7, 4 }, { 8, 7 }},
5.0f,
{{ 1.000000f, 1.000000f }, { 4.033223f, 1.758306f }, { 5.916391f, 3.091639f },
{ 7.085550f, 5.000000f },
{ 7.458195f, 5.608251f }, { 7.758306f, 6.274917f }, { 8.000000f, 7.000000f }}
);
testChopMonoCubicAtY(reporter, "curve, negative slope @ 5.0",
{{ 2, 7 }, { 3, 2 }, { 6, 3 }, { 11, 2 }},
5.0f,
{{ 2.000000f, 7.000000f }, { 2.162856f, 6.185719f }, { 2.378757f, 5.530570f },
{ 2.647702f, 5.000000f },
{ 4.030182f, 2.272668f }, { 6.814281f, 2.837144f }, { 11.000000f, 2.000000f }}
);
testChopMonoCubicAtY(reporter, "curve, negative slope @ 3.0",
{{ 2, 7 }, { 3, 2 }, { 6, 3 }, { 11, 2 }},
3.0f,
{{ 2.000000f, 7.000000f }, { 2.500000f, 4.500000f }, { 3.500000f, 3.500000f },
{ 5.000000f, 3.000000f },
{ 6.500000f, 2.500000f }, { 8.500000f, 2.500000f }, { 11.000000f, 2.000000f }}
);
testChopMonoCubicAtY(reporter, "curve, negative slope @ 2.5",
{{ 2, 7 }, { 3, 2 }, { 6, 3 }, { 11, 2 }},
2.5f,
{{ 2.000000f, 7.000000f }, { 2.750000f, 3.250000f }, { 4.625000f, 2.875000f },
{ 7.625000f, 2.500000f },
{ 8.625000f, 2.375000f }, { 9.750000f, 2.250000f }, { 11.000000f, 2.000000f }}
);
// This is the same curve as above, just the 4 points given in the opposite order.
// We would expect the math to result in the same chop points, with the outputs
// in the opposite order too.
testChopMonoCubicAtY(reporter, "inverted curve, negative slope @ 5.0",
{{ 11, 2 }, { 6, 3 }, { 3, 2 }, { 2, 7 }},
5.0f,
{{ 11.000000f, 2.000000f }, { 6.814281f, 2.837144f }, { 4.030182f, 2.272668f },
{ 2.647702f, 5.000000f },
{ 2.378757f, 5.530570f }, { 2.162856f, 6.185719f }, { 2.000000f, 7.000000f }}
);
testChopMonoCubicAtY(reporter, "inverted curve, negative slope @ 3.0",
{{ 11, 2 }, { 6, 3 }, { 3, 2 }, { 2, 7 }},
3.0f,
{{ 11.000000f, 2.000000f }, { 8.500000f, 2.500000f }, { 6.500000f, 2.500000f },
{ 5.000000f, 3.000000f },
{ 3.500000f, 3.500000f }, { 2.500000f, 4.500000f }, { 2.000000f, 7.000000f }}
);
testChopMonoCubicAtY(reporter, "inverted curve, negative slope @ 2.5",
{{ 11, 2 }, { 6, 3 }, { 3, 2 }, { 2, 7 }},
2.5f,
{{ 11.000000f, 2.000000f }, { 9.750000f, 2.250000f }, { 8.625000f, 2.375000f },
{ 7.625000f, 2.500000f },
{ 4.625000f, 2.875000f }, { 2.750000f, 3.250000f }, { 2.000000f, 7.000000f }}
);
testChopMonoCubicAtY(reporter, "big curve, negative slope @ 90",
{{ -2, 100 }, { 0, 0 }, { 0, 0 }, { 100, -2 }},
90.f,
{{ -2.000000f,100.000000f }, { -1.930979f, 96.548965f }, { -1.864341f, 93.217033f },
{ -1.795892f, 90.000000f },
{ 0.119096f, -0.002382f }, { 3.451032f, -0.069021f }, {100.000000f, -2.000000f }}
);
testChopMonoCubicAtY(reporter, "big curve, negative slope @ 10",
{{ -2, 100 }, { 0, 0 }, { 0, 0 }, { 100, -2 }},
10.f,
{{ -2.000000f,100.000000f }, { -0.937505f, 46.875271f }, { -0.439458f, 21.972910f },
{ 14.787060f, 10.000000f },
{ 28.222368f, -0.564447f }, { 53.124729f, -1.062495f }, {100.000000f, -2.000000f }}
);
testChopMonoCubicAtY(reporter, "big curve, negative slope @ 0",
{{ -2, 100 }, { 0, 0 }, { 0, 0 }, { 100, -2 }},
0.f,
{{ -2.000000f,100.000000f }, { -0.426983f, 21.349131f }, { -0.091157f, 4.557854f },
{ 48.633648f, 0.000000f },
{ 61.859592f, -1.237192f }, { 78.650871f, -1.573017f }, {100.000000f, -2.000000f }}
);
}
DEF_TEST(GeometryChopMonoCubicAtY_OutOfRangeReturnFalse, reporter) {
SkPoint inputs[] = {{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }};
SkPoint outputs[7];
// Too low
REPORTER_ASSERT(reporter, !SkChopMonoCubicAtY(inputs, -10, outputs));
// Too high
REPORTER_ASSERT(reporter, !SkChopMonoCubicAtY(inputs, 20, outputs));
}
static void testChopMonoCubicAtX(skiatest::Reporter* reporter, std::string name,
SkSpan<const SkPoint> curveInputs, SkScalar xToChopAt,
SkSpan<const SkPoint> expectedOutputs) {
skiatest::ReporterContext subtest(reporter, name);
REPORTER_ASSERT(reporter, SkScalarNearlyEqual(expectedOutputs[3].x(), xToChopAt),
"Invalid test case. 4th point's X should be %f", xToChopAt);
SkPoint outputs[7];
// Make sure it actually chopped
REPORTER_ASSERT(reporter, SkChopMonoCubicAtX(curveInputs.begin(), xToChopAt, outputs));
for (int i = 0; i < 7; ++i) {
REPORTER_ASSERT(reporter, nearly_equal(expectedOutputs[i], outputs[i]),
"(%f, %f) != (%f, %f) at index %d",
expectedOutputs[i].x(), expectedOutputs[i].y(),
outputs[i].x(), outputs[i].y(), i);
}
}
DEF_TEST(GeometryChopMonoCubicAtX_Successful, reporter) {
// These cubics are all arbitrary, picked using Desmos for something that looked "nice".
testChopMonoCubicAtX(reporter, "straight, positive slope @ 2.5",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
2.5f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 1.065055f, 1.065055f },
{ 2.500000f, 2.500000f },
{ 5.461981f, 5.461981f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtX(reporter, "straight, positive slope @ 5.0",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
5.0f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 2.500000f, 2.500000f },
{ 5.000000f, 5.000000f },
{ 7.500000f, 7.500000f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtX(reporter, "straight, positive slope @ 9.0",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
9.0f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 6.467375f, 6.467375f },
{ 9.000000f, 9.000000f },
{ 9.616623f, 9.616623f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtX(reporter, "straight, positive slope @ 10.0",
{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
10.0f,
{{ 0.000000f, 0.000000f }, { 0.000000f, 0.000000f }, { 10.000000f, 10.000000f },
{ 10.000000f, 10.000000f },
{ 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }, { 10.000000f, 10.000000f }}
);
testChopMonoCubicAtX(reporter, "curve, positive slope @ 2.0",
{{ 1, 1 }, { 5, 2 }, { 7, 4 }, { 8, 7 }},
2.0f,
{{ 1.000000f, 1.000000f }, { 1.348275f, 1.087069f }, { 1.681389f, 1.181719f },
{ 2.000000f, 1.283949f },
{ 5.340694f, 2.355856f }, { 7.087069f, 4.261207f }, { 8.000000f, 7.000000f }}
);
testChopMonoCubicAtX(reporter, "curve, positive slope @ 5.0",
{{ 1, 1 }, { 5, 2 }, { 7, 4 }, { 8, 7 }},
5.0f,
{{ 1.000000f, 1.000000f }, { 2.650396f, 1.412599f }, { 3.960316f, 1.995436f },
{ 5.000000f, 2.748511f },
{ 6.480158f, 3.820634f }, { 7.412599f, 5.237797f }, { 8.000000f, 7.000000f }}
);
testChopMonoCubicAtX(reporter, "curve, negative slope @ 5.0",
{{ 2, 7 }, { 3, 2 }, { 6, 3 }, { 11, 2 }},
5.0f,
{{ 2.000000f, 7.000000f }, { 2.500000f, 4.500000f }, { 3.500000f, 3.500000f },
{ 5.000000f, 3.000000f },
{ 6.500000f, 2.500000f }, { 8.500000f, 2.500000f }, { 11.000000f, 2.000000f }}
);
testChopMonoCubicAtX(reporter, "curve, negative slope @ 3.0",
{{ 2, 7 }, { 3, 2 }, { 6, 3 }, { 11, 2 }},
3.0f,
{{ 2.000000f, 7.000000f }, { 2.228714f, 5.856432f }, { 2.562047f, 5.026724f },
{ 3.000000f, 4.415163f },
{ 4.476901f, 2.352807f }, { 7.143568f, 2.771286f }, { 11.000000f, 2.000000f }}
);
testChopMonoCubicAtX(reporter, "curve, negative slope @ 2.5",
{{ 2, 7 }, { 3, 2 }, { 6, 3 }, { 11, 2 }},
2.5f,
{{ 2.000000f, 7.000000f }, { 2.131881f, 6.340593f }, { 2.298548f, 5.785543f },
{ 2.500000f, 5.316498f },
{ 3.826073f, 2.228977f }, { 6.659407f, 2.868119f }, { 11.000000f, 2.000000f }}
);
// This is the same curve as above, just the 4 points given in the opposite order.
// We would expect the math to result in the same chop points, with the outputs
// in the opposite order too.
testChopMonoCubicAtX(reporter, "inverted curve, negative slope @ 5.0",
{{ 11, 2 }, { 6, 3 }, { 3, 2 }, { 2, 7 }},
5.0f,
{{ 11.000000f, 2.000000f }, { 8.500000f, 2.500000f }, { 6.500000f, 2.500000f },
{ 5.000000f, 3.000000f },
{ 3.500000f, 3.500000f }, { 2.500000f, 4.500000f }, { 2.000000f, 7.000000f }}
);
testChopMonoCubicAtX(reporter, "inverted curve, negative slope @ 3.0",
{{ 11, 2 }, { 6, 3 }, { 3, 2 }, { 2, 7 }},
3.0f,
{{ 11.000000f, 2.000000f }, { 7.143568f, 2.771286f }, { 4.476901f, 2.352807f },
{ 3.000000f, 4.415163f },
{ 2.562047f, 5.026724f }, { 2.228714f, 5.856432f }, { 2.000000f, 7.000000f }}
);
testChopMonoCubicAtX(reporter, "inverted curve, negative slope @ 2.5",
{{ 11, 2 }, { 6, 3 }, { 3, 2 }, { 2, 7 }},
2.5f,
{{ 11.000000f, 2.000000f }, { 6.659407f, 2.868119f }, { 3.826073f, 2.228977f },
{ 2.500000f, 5.316498f },
{ 2.298548f, 5.785543f }, { 2.131881f, 6.340593f }, { 2.000000f, 7.000000f }}
);
testChopMonoCubicAtX(reporter, "big curve, negative slope @ 90",
{{ -2, 100 }, { 0, 0 }, { 0, 0 }, { 100, -2 }},
90.f,
{{ -2.000000f,100.000000f }, { -0.069021f, 3.451032f }, { -0.002382f, 0.119096f },
{ 90.000000f, -1.795892f },
{ 93.217033f, -1.864341f }, { 96.548965f, -1.930979f }, {100.000000f, -2.000000f }}
);
testChopMonoCubicAtX(reporter, "big curve, negative slope @ 10",
{{ -2, 100 }, { 0, 0 }, { 0, 0 }, { 100, -2 }},
10.f,
{{ -2.000000f,100.000000f }, { -1.062495f, 53.124729f }, { -0.564447f, 28.222368f },
{ 10.000000f, 14.787060f },
{ 21.972910f, -0.439458f }, { 46.875271f, -0.937505f }, {100.000000f, -2.000000f }}
);
testChopMonoCubicAtX(reporter, "big curve, negative slope @ 0",
{{ -2, 100 }, { 0, 0 }, { 0, 0 }, { 100, -2 }},
0.f,
{{ -2.000000f,100.000000f }, { -1.573017f, 78.650871f }, { -1.237192f, 61.859592f },
{ 0.000000f, 48.633648f },
{ 4.557854f, -0.091157f }, { 21.349131f, -0.426983f }, {100.000000f, -2.000000f }}
);
}
DEF_TEST(GeometryChopMonoCubicAtX_OutOfRangeReturnFalse, reporter) {
SkPoint inputs[] = {{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }};
SkPoint outputs[7];
// Too low
REPORTER_ASSERT(reporter, !SkChopMonoCubicAtX(inputs, -10, outputs));
// Too high
REPORTER_ASSERT(reporter, !SkChopMonoCubicAtX(inputs, 20, outputs));
}