blob: d222690f09744d6e8ce97c1446fca6dc20ec9503 [file] [log] [blame]
/*
* Copyright 2019 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/SkPoint.h"
#include "src/base/SkRandom.h"
#include "src/base/SkVx.h"
#include "tests/Test.h"
#include <numeric>
namespace skvx {
DEF_TEST(SkVx, r) {
static_assert(sizeof(float2) == 8, "");
static_assert(sizeof(float4) == 16, "");
static_assert(sizeof(float8) == 32, "");
static_assert(sizeof(byte2) == 2, "");
static_assert(sizeof(byte4) == 4, "");
static_assert(sizeof(byte8) == 8, "");
{
int4 mask = float4{1,2,3,4} < float4{1,2,4,8};
REPORTER_ASSERT(r, mask[0] == int32_t( 0));
REPORTER_ASSERT(r, mask[1] == int32_t( 0));
REPORTER_ASSERT(r, mask[2] == int32_t(-1));
REPORTER_ASSERT(r, mask[3] == int32_t(-1));
REPORTER_ASSERT(r, any(mask));
REPORTER_ASSERT(r, !all(mask));
}
{
long4 mask = double4{1,2,3,4} < double4{1,2,4,8};
REPORTER_ASSERT(r, mask[0] == int64_t( 0));
REPORTER_ASSERT(r, mask[1] == int64_t( 0));
REPORTER_ASSERT(r, mask[2] == int64_t(-1));
REPORTER_ASSERT(r, mask[3] == int64_t(-1));
REPORTER_ASSERT(r, any(mask));
REPORTER_ASSERT(r, !all(mask));
}
{
// Tests that any/all work with non-zero values, not just full bit lanes.
REPORTER_ASSERT(r, all(int4{1,2,3,4}));
REPORTER_ASSERT(r, !all(int4{1,2,3}));
REPORTER_ASSERT(r, any(int4{1,2}));
REPORTER_ASSERT(r, !any(int4{}));
}
REPORTER_ASSERT(r, min(float4{1,2,3,4}) == 1);
REPORTER_ASSERT(r, max(float4{1,2,3,4}) == 4);
REPORTER_ASSERT(r, all(int4{1,2,3,4,5} == int4{1,2,3,4}));
REPORTER_ASSERT(r, all(int4{1,2,3,4} == int4{1,2,3,4}));
REPORTER_ASSERT(r, all(int4{1,2,3} == int4{1,2,3,0}));
REPORTER_ASSERT(r, all(int4{1,2} == int4{1,2,0,0}));
REPORTER_ASSERT(r, all(int4{1} == int4{1,0,0,0}));
REPORTER_ASSERT(r, all(int4(1) == int4{1,1,1,1}));
REPORTER_ASSERT(r, all(int4{} == int4{0,0,0,0}));
REPORTER_ASSERT(r, all(int4() == int4{0,0,0,0}));
REPORTER_ASSERT(r, all(int4{1,2,2,1} == min(int4{1,2,3,4}, int4{4,3,2,1})));
REPORTER_ASSERT(r, all(int4{4,3,3,4} == max(int4{1,2,3,4}, int4{4,3,2,1})));
REPORTER_ASSERT(r, all(if_then_else(float4{1,2,3,2} <= float4{2,2,2,2}, float4(42), float4(47))
== float4{42,42,47,42}));
REPORTER_ASSERT(r, all(floor(float4{-1.5f,1.5f,1.0f,-1.0f}) == float4{-2.0f,1.0f,1.0f,-1.0f}));
REPORTER_ASSERT(r, all( ceil(float4{-1.5f,1.5f,1.0f,-1.0f}) == float4{-1.0f,2.0f,1.0f,-1.0f}));
REPORTER_ASSERT(r, all(trunc(float4{-1.5f,1.5f,1.0f,-1.0f}) == float4{-1.0f,1.0f,1.0f,-1.0f}));
REPORTER_ASSERT(r, all(round(float4{-1.5f,1.5f,1.0f,-1.0f}) == float4{-2.0f,2.0f,1.0f,-1.0f}));
REPORTER_ASSERT(r, all(abs(float4{-2,-1,0,1}) == float4{2,1,0,1}));
// TODO(mtklein): these tests could be made less loose.
REPORTER_ASSERT(r, all( sqrt(float4{2,3,4,5}) < float4{2,2,3,3}));
REPORTER_ASSERT(r, all( sqrt(float2{2,3}) < float2{2,2}));
REPORTER_ASSERT(r, all(cast<int>(float4{-1.5f,0.5f,1.0f,1.5f}) == int4{-1,0,1,1}));
float buf[] = {1,2,3,4,5,6};
REPORTER_ASSERT(r, all(float4::Load(buf) == float4{1,2,3,4}));
float4{2,3,4,5}.store(buf);
REPORTER_ASSERT(r, buf[0] == 2
&& buf[1] == 3
&& buf[2] == 4
&& buf[3] == 5
&& buf[4] == 5
&& buf[5] == 6);
REPORTER_ASSERT(r, all(float4::Load(buf+0) == float4{2,3,4,5}));
REPORTER_ASSERT(r, all(float4::Load(buf+2) == float4{4,5,5,6}));
REPORTER_ASSERT(r, all(shuffle<2,1,0,3> (float4{1,2,3,4}) == float4{3,2,1,4}));
REPORTER_ASSERT(r, all(shuffle<2,1> (float4{1,2,3,4}) == float2{3,2}));
REPORTER_ASSERT(r, all(shuffle<3,3,3,3> (float4{1,2,3,4}) == float4{4,4,4,4}));
REPORTER_ASSERT(r, all(shuffle<2,1,2,1,2,1,2,1>(float4{1,2,3,4})
== float8{3,2,3,2,3,2,3,2}));
// Test that mixed types can be used where they make sense. Mostly about ergonomics.
REPORTER_ASSERT(r, all(float4{1,2,3,4} < 5));
REPORTER_ASSERT(r, all( byte4{1,2,3,4} < 5));
REPORTER_ASSERT(r, all( int4{1,2,3,4} < 5.0f));
float4 five = 5;
REPORTER_ASSERT(r, all(five == 5.0f));
REPORTER_ASSERT(r, all(five == 5));
REPORTER_ASSERT(r, all(max(2, min(float4{1,2,3,4}, 3)) == float4{2,2,3,3}));
for (int x = 0; x < 256; x++)
for (int y = 0; y < 256; y++) {
uint8_t want = (uint8_t)( 255*(x/255.0 * y/255.0) + 0.5 );
{
uint8_t got = div255(Vec<8, uint16_t>(x) * Vec<8, uint16_t>(y) )[0];
REPORTER_ASSERT(r, got == want);
}
{
uint8_t got = approx_scale(Vec<8,uint8_t>(x), Vec<8,uint8_t>(y))[0];
REPORTER_ASSERT(r, got == want-1 ||
got == want ||
got == want+1);
if (x == 0 || y == 0 || x == 255 || y == 255) {
REPORTER_ASSERT(r, got == want);
}
}
}
for (int x = 0; x < 256; x++)
for (int y = 0; y < 256; y++) {
uint16_t xy = x*y;
// Make sure to cover implementation cases N=8, N<8, and N>8.
REPORTER_ASSERT(r, all(mull(byte2 (x), byte2 (y)) == xy));
REPORTER_ASSERT(r, all(mull(byte4 (x), byte4 (y)) == xy));
REPORTER_ASSERT(r, all(mull(byte8 (x), byte8 (y)) == xy));
REPORTER_ASSERT(r, all(mull(byte16(x), byte16(y)) == xy));
}
{
// Intentionally not testing -0, as we don't care if it's 0x0000 or 0x8000.
float8 fs = {+0.0f,+0.5f,+1.0f,+2.0f,
-4.0f,-0.5f,-1.0f,-2.0f};
Vec<8,uint16_t> hs = {0x0000,0x3800,0x3c00,0x4000,
0xc400,0xb800,0xbc00,0xc000};
REPORTER_ASSERT(r, all( to_half(fs) == hs));
REPORTER_ASSERT(r, all(from_half(hs) == fs));
}
}
DEF_TEST(SkVx_xy, r) {
float2 f = float2(1,2);
REPORTER_ASSERT(r, all(f == float2{1,2}));
REPORTER_ASSERT(r, f.x() == 1);
REPORTER_ASSERT(r, f.y() == 2);
f.y() = 9;
REPORTER_ASSERT(r, all(f == float2{1,9}));
f.x() = 0;
REPORTER_ASSERT(r, all(f == float2(0,9)));
f[0] = 8;
REPORTER_ASSERT(r, f.x() == 8);
f[1] = 6;
REPORTER_ASSERT(r, f.y() == 6);
REPORTER_ASSERT(r, all(f == float2(8,6)));
f = f.yx();
REPORTER_ASSERT(r, all(f == float2(6,8)));
REPORTER_ASSERT(r, bit_pun<SkPoint>(f) == SkPoint::Make(6,8));
SkPoint p;
f.store(&p);
REPORTER_ASSERT(r, p == SkPoint::Make(6,8));
f.yx().store(&p);
REPORTER_ASSERT(r, p == SkPoint::Make(8,6));
REPORTER_ASSERT(r, all(f.xyxy() == float4(6,8,6,8)));
REPORTER_ASSERT(r, all(f.xyxy() == float4(f,f)));
REPORTER_ASSERT(r, all(join(f,f) == f.xyxy()));
REPORTER_ASSERT(r, all(join(f.yx(),f) == float4(f.y(),f.x(),f)));
REPORTER_ASSERT(r, all(join(f.yx(),f) == float4(f.yx(),f.x(),f.y())));
REPORTER_ASSERT(r, all(join(f,f.yx()) == float4(f.x(),f.y(),f.yx())));
REPORTER_ASSERT(r, all(join(f.yx(),f.yx()) == float4(f.yx(),f.yx())));
}
DEF_TEST(SkVx_xyzw, r) {
float4 f = float4{1,2,3,4};
REPORTER_ASSERT(r, all(f == float4(1,2,3,4)));
REPORTER_ASSERT(r, all(f == float4(1,2,float2(3,4))));
REPORTER_ASSERT(r, all(f == float4(float2(1,2),3,4)));
REPORTER_ASSERT(r, all(f == float4(float2(1,2),float2(3,4))));
f.xy() = float2(9,8);
REPORTER_ASSERT(r, all(f == float4(9,8,3,4)));
f.zw().x() = 7;
f.zw().y() = 6;
REPORTER_ASSERT(r, all(f == float4(9,8,7,6)));
f.x() = 5;
f.y() = 4;
f.z() = 3;
f.w() = 2;
REPORTER_ASSERT(r, all(f == float4(5,4,3,2)));
f[0] = 0;
REPORTER_ASSERT(r, f.x() == 0);
f[1] = 1;
REPORTER_ASSERT(r, f.y() == 1);
f[2] = 2;
REPORTER_ASSERT(r, f.z() == 2);
f[3] = 3;
REPORTER_ASSERT(r, f.w() == 3);
REPORTER_ASSERT(r, all(f.xy() == float2(0,1)));
REPORTER_ASSERT(r, all(f.zw() == float2{2,3}));
REPORTER_ASSERT(r, all(f == float4(0,1,2,3)));
REPORTER_ASSERT(r, all(f.yxwz().lo == shuffle<1,0>(f)));
REPORTER_ASSERT(r, all(f.yxwz().hi == shuffle<3,2>(f)));
REPORTER_ASSERT(r, all(f.zwxy().lo.lo == f.z()));
REPORTER_ASSERT(r, all(f.zwxy().lo.hi == f.w()));
REPORTER_ASSERT(r, all(f.zwxy().hi.lo == f.x()));
REPORTER_ASSERT(r, all(f.zwxy().hi.hi == f.y()));
REPORTER_ASSERT(r, f.yxwz().lo.lo.val == f.y());
REPORTER_ASSERT(r, f.yxwz().lo.hi.val == f.x());
REPORTER_ASSERT(r, f.yxwz().hi.lo.val == f.w());
REPORTER_ASSERT(r, f.yxwz().hi.hi.val == f.z());
REPORTER_ASSERT(r, all(naive_if_then_else(int2(0,~0),
shuffle<3,2>(float4(0,1,2,3)),
float4(4,5,6,7).xy()) == float2(4,2)));
REPORTER_ASSERT(r, all(if_then_else(int2(0,~0),
shuffle<3,2>(float4(0,1,2,3)),
float4(4,5,6,7).xy()) == float2(4,2)));
REPORTER_ASSERT(r, all(naive_if_then_else(int2(0,~0).xyxy(),
float4(0,1,2,3).zwxy(),
float4(4,5,6,7)) == float4(4,3,6,1)));
REPORTER_ASSERT(r, all(if_then_else(int2(0,~0).xyxy(),
float4(0,1,2,3).zwxy(),
float4(4,5,6,7)) == float4(4,3,6,1)));
REPORTER_ASSERT(r, all(pin(float4(0,1,2,3).yxwz(),
float2(1).xyxy(),
float2(2).xyxy()) == float4(1,1,2,2)));
}
DEF_TEST(SkVx_cross_dot, r) {
REPORTER_ASSERT(r, cross(int2{0,1}, int2{0,1}) == 0);
REPORTER_ASSERT(r, cross(int2{1,0}, int2{1,0}) == 0);
REPORTER_ASSERT(r, cross(int2{1,1}, int2{1,1}) == 0);
REPORTER_ASSERT(r, cross(int2{1,1}, int2{1,-1}) == -2);
REPORTER_ASSERT(r, cross(int2{1,1}, int2{-1,1}) == 2);
REPORTER_ASSERT(r, dot(int2{0,1}, int2{1,0}) == 0);
REPORTER_ASSERT(r, dot(int2{1,0}, int2{0,1}) == 0);
REPORTER_ASSERT(r, dot(int2{1,1}, int2{1,-1}) == 0);
REPORTER_ASSERT(r, dot(int2{1,1}, int2{1,1}) == 2);
REPORTER_ASSERT(r, dot(int2{1,1}, int2{-1,-1}) == -2);
SkRandom rand;
for (int i = 0; i < 100; ++i) {
float a=rand.nextRangeF(-1,1), b=rand.nextRangeF(-1,1), c=rand.nextRangeF(-1,1),
d=rand.nextRangeF(-1,1);
constexpr static float kTolerance = 1.f / (1 << 20);
REPORTER_ASSERT(r, SkScalarNearlyEqual(
cross(float2{a,b}, float2{c,d}), SkPoint::CrossProduct({a,b}, {c,d}), kTolerance));
REPORTER_ASSERT(r, SkScalarNearlyEqual(
dot(float2{a,b}, float2{c,d}), SkPoint::DotProduct({a,b}, {c,d}), kTolerance));
}
auto assertDoublesEqual = [&](double left, double right) {
REPORTER_ASSERT(r, SkScalarNearlyEqual(left, right), "%f != %f", left, right);
};
assertDoublesEqual(cross(double2{1.2, 3.4}, double2{3.4, -1.2}), -13.000000);
assertDoublesEqual(cross(double2{12.34, 5.6}, double2{7.8, -9.0}), -154.740000);
assertDoublesEqual(cross(double2{12.34, 5.6}, double2{7.8, 9.012345678}), 67.532346);
}
template<int N, typename T> void check_strided_loads(skiatest::Reporter* r) {
using Vec = Vec<N,T>;
T values[N*4];
std::iota(values, values + N*4, 0);
Vec a, b, c, d;
strided_load2(values, a, b);
for (int i = 0; i < N; ++i) {
REPORTER_ASSERT(r, a[i] == values[i*2]);
REPORTER_ASSERT(r, b[i] == values[i*2 + 1]);
}
strided_load4(values, a, b, c, d);
for (int i = 0; i < N; ++i) {
REPORTER_ASSERT(r, a[i] == values[i*4]);
REPORTER_ASSERT(r, b[i] == values[i*4 + 1]);
REPORTER_ASSERT(r, c[i] == values[i*4 + 2]);
REPORTER_ASSERT(r, d[i] == values[i*4 + 3]);
}
}
template<typename T> void check_strided_loads(skiatest::Reporter* r) {
check_strided_loads<1,T>(r);
check_strided_loads<2,T>(r);
check_strided_loads<4,T>(r);
check_strided_loads<8,T>(r);
check_strided_loads<16,T>(r);
check_strided_loads<32,T>(r);
}
DEF_TEST(SkVx_strided_loads, r) {
check_strided_loads<uint32_t>(r);
check_strided_loads<uint16_t>(r);
check_strided_loads<uint8_t>(r);
check_strided_loads<int32_t>(r);
check_strided_loads<int16_t>(r);
check_strided_loads<int8_t>(r);
check_strided_loads<float>(r);
}
DEF_TEST(SkVx_ScaledDividerU32, r) {
static constexpr uint32_t kMax = std::numeric_limits<uint32_t>::max();
auto errorBounds = [&](uint32_t actual, uint32_t expected) {
uint32_t lowerLimit = expected == 0 ? 0 : expected - 1,
upperLimit = expected == kMax ? kMax : expected + 1;
return lowerLimit <= actual && actual <= upperLimit;
};
auto test = [&](uint32_t denom) {
// half == 1 so, the max to check is kMax-1
ScaledDividerU32 d(denom);
uint32_t maxCheck = static_cast<uint32_t>(
std::floor((double)(kMax - d.half()) / denom + 0.5));
REPORTER_ASSERT(r, errorBounds(d.divide((kMax))[0], maxCheck));
for (uint32_t i = 0; i < kMax - d.half(); i += 65535) {
uint32_t expected = static_cast<uint32_t>(std::floor((double)i / denom + 0.5));
auto actual = d.divide(i + d.half());
if (!errorBounds(actual[0], expected)) {
SkDebugf("i: %u expected: %u actual: %u\n", i, expected, actual[0]);
}
// Make sure all the lanes are the same.
for (int e = 1; e < 4; e++) {
SkASSERT(actual[0] == actual[e]);
}
}
};
test(2);
test(3);
test(5);
test(7);
test(27);
test(65'535);
test(15'485'863);
test(512'927'377);
}
DEF_TEST(SkVx_saturated_add, r) {
for (int a = 0; a < (1<<8); a++) {
for (int b = 0; b < (1<<8); b++) {
int exact = a+b;
if (exact > 255) { exact = 255; }
if (exact < 0) { exact = 0; }
REPORTER_ASSERT(r, saturated_add(skvx::byte16(a), skvx::byte16(b))[0] == exact);
}
}
}
DEF_TEST(SkVx_length, r) {
auto assertFloatsEqual = [&](float left, float right) {
REPORTER_ASSERT(r, SkScalarNearlyEqual(left, right), "%f != %f", left, right);
};
auto assertDoublesEqual = [&](double left, double right) {
REPORTER_ASSERT(r, SkScalarNearlyEqual(left, right), "%f != %f", left, right);
};
assertFloatsEqual(length(float2{0, 1}), 1.000000f);
assertFloatsEqual(length(float2{2, 0}), 2.000000f);
assertFloatsEqual(length(float2{3, 4}), 5.000000f);
assertFloatsEqual(length(float2{1, 1}), 1.414214f);
assertFloatsEqual(length(float2{2.5f, 2.5f}), 3.535534f);
assertFloatsEqual(length(float4{1, 2, 3, 4}), 5.477226f);
assertDoublesEqual(length(double2{2.5, 2.5}), 3.535534);
assertDoublesEqual(length(double4{1.5, 2.5, 3.5, 4.5}), 6.403124);
}
DEF_TEST(SkVx_normalize, r) {
auto assertFloatsEqual = [&](float left, float right) {
REPORTER_ASSERT(r, SkScalarNearlyEqual(left, right), "%f != %f", left, right);
};
auto assertDoublesEqual = [&](double left, double right) {
REPORTER_ASSERT(r, SkScalarNearlyEqual(left, right), "%f != %f", left, right);
};
skvx::float2 twoFloats = normalize(skvx::float2{1.2f, 3.4f});
assertFloatsEqual(twoFloats[0], 0.332820f);
assertFloatsEqual(twoFloats[1], 0.942990f);
skvx::double2 twoDoubles = normalize(skvx::double2{2.3, -4.5});
assertDoublesEqual(twoDoubles[0], 0.455111);
assertDoublesEqual(twoDoubles[1], -0.890435);
skvx::double4 fourDoubles = normalize(skvx::double4{1.2, 3.4, 5.6, 7.8});
assertDoublesEqual(fourDoubles[0], 0.116997);
assertDoublesEqual(fourDoubles[1], 0.331490);
assertDoublesEqual(fourDoubles[2], 0.545984);
assertDoublesEqual(fourDoubles[3], 0.760478);
}
DEF_TEST(SkVx_normalize_infinity_and_nan, r) {
skvx::float2 zeroLenVec = normalize(skvx::float2{0, 0});
REPORTER_ASSERT(r, std::isnan(zeroLenVec[0]), "%f is not nan", zeroLenVec[0]);
REPORTER_ASSERT(r, std::isnan(zeroLenVec[1]), "%f is not nan", zeroLenVec[1]);
REPORTER_ASSERT(r, !isfinite(zeroLenVec));
skvx::float2 tooBigVec = normalize(skvx::float2{std::numeric_limits<float>::max(),
std::numeric_limits<float>::max()});
REPORTER_ASSERT(r, tooBigVec[0] == 0, "%f != 0", tooBigVec[0]);
REPORTER_ASSERT(r, tooBigVec[1] == 0, "%f != 0", tooBigVec[1]);
skvx::double2 tooBigVecD = normalize(skvx::double2{std::numeric_limits<double>::max(),
std::numeric_limits<double>::max()});
REPORTER_ASSERT(r, tooBigVecD[0] == 0, "%f != 0", tooBigVecD[0]);
REPORTER_ASSERT(r, tooBigVecD[1] == 0, "%f != 0", tooBigVecD[1]);
}
DEF_TEST(SkVx_isfinite, r) {
REPORTER_ASSERT(r, isfinite(skvx::float2{0, 0}));
REPORTER_ASSERT(r, isfinite(skvx::double4{1.2, 3.4, 5.6, 7.8}));
REPORTER_ASSERT(r, isfinite(skvx::float8{8, 7, 6, 5, 4, 3, 2, 1}));
REPORTER_ASSERT(r, !isfinite(skvx::float2{0, NAN}));
REPORTER_ASSERT(r, !isfinite(skvx::float2{INFINITY, 10}));
REPORTER_ASSERT(r, !isfinite(skvx::float2{NAN, INFINITY}));
for (int i = 0; i < 4; i++) {
auto v = skvx::double4{4, 3, 2, 1};
v[i] = INFINITY;
REPORTER_ASSERT(r, !isfinite(v), "index %d INFINITY", i);
v[i] = NAN;
REPORTER_ASSERT(r, !isfinite(v), "index %d NAN", i);
}
for (int i = 0; i < 8; i++) {
auto v = skvx::float8{8, 7, 6, 5, 4, 3, 2, 1};
v[i] = INFINITY;
REPORTER_ASSERT(r, !isfinite(v), "index %d INFINITY", i);
v[i] = NAN;
REPORTER_ASSERT(r, !isfinite(v), "index %d NAN", i);
}
}
} // namespace skvx