tests/Sk4xTest.cpp - skia - Git at Google

 #include "Test.h"
 #include "Sk4x.h"

 #define ASSERT_EQ(a, b) REPORTER_ASSERT(r, a.equal(b).allTrue())
 #define ASSERT_NE(a, b) REPORTER_ASSERT(r, a.notEqual(b).allTrue())

 DEF_TEST(Sk4x_Construction, r) {
     Sk4f uninitialized;
     Sk4f zero(0,0,0,0);
     Sk4f foo(1,2,3,4),
          bar(foo),
          baz = bar;
     ASSERT_EQ(foo, bar);
     ASSERT_EQ(bar, baz);
     ASSERT_EQ(baz, foo);
 }

 struct AlignedFloats {
     Sk4f forces16ByteAlignment;   // On 64-bit machines, the stack starts 128-bit aligned,
     float fs[5];                  // but not necessarily so on 32-bit.  Adding an Sk4f forces it.
 };

 DEF_TEST(Sk4x_LoadStore, r) {
     AlignedFloats aligned;
     // fs will be 16-byte aligned, fs+1 not.
     float* fs = aligned.fs;
     for (int i = 0; i < 5; i++) {  // set to 5,6,7,8,9
         fs[i] = float(i+5);
     }

     Sk4f foo = Sk4f::Load(fs);
     Sk4f bar = Sk4f::LoadAligned(fs);
     ASSERT_EQ(foo, bar);

     foo = Sk4f::Load(fs+1);
     ASSERT_NE(foo, bar);

     foo.storeAligned(fs);
     bar.store(fs+1);
     REPORTER_ASSERT(r, fs[0] == 6 &&
                        fs[1] == 5 &&
                        fs[2] == 6 &&
                        fs[3] == 7 &&
                        fs[4] == 8);
 }

 DEF_TEST(Sk4x_Conversions, r) {
     // Assuming IEEE floats.
     Sk4f zerof(0,0,0,0);
     Sk4i zeroi(0,0,0,0);
     ASSERT_EQ(zeroi, zerof.cast<Sk4i>());
     ASSERT_EQ(zeroi, zerof.reinterpret<Sk4i>());
     ASSERT_EQ(zerof, zeroi.cast<Sk4f>());
     ASSERT_EQ(zerof, zeroi.reinterpret<Sk4f>());

     Sk4f twof(2,2,2,2);
     Sk4i twoi(2,2,2,2);
     ASSERT_EQ(twoi, twof.cast<Sk4i>());
     ASSERT_NE(twoi, twof.reinterpret<Sk4i>());
     ASSERT_EQ(twof, twoi.cast<Sk4f>());
     ASSERT_NE(twof, twoi.reinterpret<Sk4f>());
 }

 DEF_TEST(Sk4x_Bits, r) {
     ASSERT_EQ(Sk4i(0,0,0,0).bitNot(), Sk4i(-1,-1,-1,-1));

     Sk4i a(2,3,4,5),
          b(1,3,5,7);
     ASSERT_EQ(Sk4i(0,3,4,5), a & b);
     ASSERT_EQ(Sk4i(3,3,5,7), a | b);
 }

 DEF_TEST(Sk4x_Arith, r) {
     ASSERT_EQ(Sk4f(4,6,8,10),    Sk4f(1,2,3,4) + Sk4f(3,4,5,6));
     ASSERT_EQ(Sk4f(-2,-2,-2,-2), Sk4f(1,2,3,4) - Sk4f(3,4,5,6));
     ASSERT_EQ(Sk4f(3,8,15,24),   Sk4f(1,2,3,4) * Sk4f(3,4,5,6));

     float third = 1.0f/3.0f;
     ASSERT_EQ(Sk4f(1*third, 0.5f, 0.6f, 2*third), Sk4f(1,2,3,4) / Sk4f(3,4,5,6));
     ASSERT_EQ(Sk4i(4,6,8,10),    Sk4i(1,2,3,4) + Sk4i(3,4,5,6));
     ASSERT_EQ(Sk4i(-2,-2,-2,-2), Sk4i(1,2,3,4) - Sk4i(3,4,5,6));
     ASSERT_EQ(Sk4i(3,8,15,24),   Sk4i(1,2,3,4) * Sk4i(3,4,5,6));
 }

 DEF_TEST(Sk4x_ExplicitPromotion, r) {
     ASSERT_EQ(Sk4f(2,4,6,8), Sk4f(1,2,3,4) * Sk4f(2.0f));
 }

 DEF_TEST(Sk4x_Sqrt, r) {
     Sk4f squares(4, 16, 25, 121),
            roots(2,  4,  5,  11);
     // .sqrt() should be pretty precise.
     Sk4f error = roots.subtract(squares.sqrt());
     REPORTER_ASSERT(r, error.greaterThanEqual(Sk4f(0.0f)).allTrue());
     REPORTER_ASSERT(r, error.lessThan(Sk4f(0.000001f)).allTrue());

     // .rsqrt() isn't so precise (for SSE), but should be pretty close.
     error = roots.subtract(squares.multiply(squares.rsqrt()));
     REPORTER_ASSERT(r, error.greaterThanEqual(Sk4f(0.0f)).allTrue());
     REPORTER_ASSERT(r, error.lessThan(Sk4f(0.01f)).allTrue());
 }

 DEF_TEST(Sk4x_Comparison, r) {
     ASSERT_EQ(Sk4f(1,2,3,4), Sk4f(1,2,3,4));
     ASSERT_NE(Sk4f(4,3,2,1), Sk4f(1,2,3,4));

     ASSERT_EQ(Sk4i(-1,-1,0,-1), Sk4f(1,2,5,4) == Sk4f(1,2,3,4));

     ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4f(1,2,3,4) <  Sk4f(2,3,4,5));
     ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4f(1,2,3,4) <= Sk4f(2,3,4,5));
     ASSERT_EQ(Sk4i(0,0,0,0),     Sk4f(1,2,3,4) >  Sk4f(2,3,4,5));
     ASSERT_EQ(Sk4i(0,0,0,0),     Sk4f(1,2,3,4) >= Sk4f(2,3,4,5));

     ASSERT_EQ(Sk4i(1,2,3,4), Sk4i(1,2,3,4));
     ASSERT_NE(Sk4i(4,3,2,1), Sk4i(1,2,3,4));

     ASSERT_EQ(Sk4i(-1,-1,0,-1), Sk4i(1,2,5,4) == Sk4i(1,2,3,4));

     ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4i(1,2,3,4) <  Sk4i(2,3,4,5));
     ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4i(1,2,3,4) <= Sk4i(2,3,4,5));
     ASSERT_EQ(Sk4i(0,0,0,0),     Sk4i(1,2,3,4) >  Sk4i(2,3,4,5));
     ASSERT_EQ(Sk4i(0,0,0,0),     Sk4i(1,2,3,4) >= Sk4i(2,3,4,5));
 }

 DEF_TEST(Sk4x_MinMax, r) {
     ASSERT_EQ(Sk4f(1,2,2,1), Sk4f::Min(Sk4f(1,2,3,4), Sk4f(4,3,2,1)));
     ASSERT_EQ(Sk4f(4,3,3,4), Sk4f::Max(Sk4f(1,2,3,4), Sk4f(4,3,2,1)));
     ASSERT_EQ(Sk4i(1,2,2,1), Sk4i::Min(Sk4i(1,2,3,4), Sk4i(4,3,2,1)));
     ASSERT_EQ(Sk4i(4,3,3,4), Sk4i::Max(Sk4i(1,2,3,4), Sk4i(4,3,2,1)));
 }

 DEF_TEST(Sk4x_Swizzle, r) {
     ASSERT_EQ(Sk4f(3,4,1,2), Sk4f(1,2,3,4).zwxy());
     ASSERT_EQ(Sk4f(1,2,5,6), Sk4f::XYAB(Sk4f(1,2,3,4), Sk4f(5,6,7,8)));
     ASSERT_EQ(Sk4f(3,4,7,8), Sk4f::ZWCD(Sk4f(1,2,3,4), Sk4f(5,6,7,8)));
     ASSERT_EQ(Sk4i(3,4,1,2), Sk4i(1,2,3,4).zwxy());
     ASSERT_EQ(Sk4i(1,2,5,6), Sk4i::XYAB(Sk4i(1,2,3,4), Sk4i(5,6,7,8)));
     ASSERT_EQ(Sk4i(3,4,7,8), Sk4i::ZWCD(Sk4i(1,2,3,4), Sk4i(5,6,7,8)));
 }
	#include "Test.h"
	#include "Sk4x.h"

	#define ASSERT_EQ(a, b) REPORTER_ASSERT(r, a.equal(b).allTrue())
	#define ASSERT_NE(a, b) REPORTER_ASSERT(r, a.notEqual(b).allTrue())

	DEF_TEST(Sk4x_Construction, r) {
	Sk4f uninitialized;
	Sk4f zero(0,0,0,0);
	Sk4f foo(1,2,3,4),
	bar(foo),
	baz = bar;
	ASSERT_EQ(foo, bar);
	ASSERT_EQ(bar, baz);
	ASSERT_EQ(baz, foo);
	}

	struct AlignedFloats {
	Sk4f forces16ByteAlignment; // On 64-bit machines, the stack starts 128-bit aligned,
	float fs[5]; // but not necessarily so on 32-bit. Adding an Sk4f forces it.
	};

	DEF_TEST(Sk4x_LoadStore, r) {
	AlignedFloats aligned;
	// fs will be 16-byte aligned, fs+1 not.
	float* fs = aligned.fs;
	for (int i = 0; i < 5; i++) { // set to 5,6,7,8,9
	fs[i] = float(i+5);
	}

	Sk4f foo = Sk4f::Load(fs);
	Sk4f bar = Sk4f::LoadAligned(fs);
	ASSERT_EQ(foo, bar);

	foo = Sk4f::Load(fs+1);
	ASSERT_NE(foo, bar);

	foo.storeAligned(fs);
	bar.store(fs+1);
	REPORTER_ASSERT(r, fs[0] == 6 &&
	fs[1] == 5 &&
	fs[2] == 6 &&
	fs[3] == 7 &&
	fs[4] == 8);
	}

	DEF_TEST(Sk4x_Conversions, r) {
	// Assuming IEEE floats.
	Sk4f zerof(0,0,0,0);
	Sk4i zeroi(0,0,0,0);
	ASSERT_EQ(zeroi, zerof.cast<Sk4i>());
	ASSERT_EQ(zeroi, zerof.reinterpret<Sk4i>());
	ASSERT_EQ(zerof, zeroi.cast<Sk4f>());
	ASSERT_EQ(zerof, zeroi.reinterpret<Sk4f>());

	Sk4f twof(2,2,2,2);
	Sk4i twoi(2,2,2,2);
	ASSERT_EQ(twoi, twof.cast<Sk4i>());
	ASSERT_NE(twoi, twof.reinterpret<Sk4i>());
	ASSERT_EQ(twof, twoi.cast<Sk4f>());
	ASSERT_NE(twof, twoi.reinterpret<Sk4f>());
	}

	DEF_TEST(Sk4x_Bits, r) {
	ASSERT_EQ(Sk4i(0,0,0,0).bitNot(), Sk4i(-1,-1,-1,-1));

	Sk4i a(2,3,4,5),
	b(1,3,5,7);
	ASSERT_EQ(Sk4i(0,3,4,5), a & b);
	ASSERT_EQ(Sk4i(3,3,5,7), a \| b);
	}

	DEF_TEST(Sk4x_Arith, r) {
	ASSERT_EQ(Sk4f(4,6,8,10), Sk4f(1,2,3,4) + Sk4f(3,4,5,6));
	ASSERT_EQ(Sk4f(-2,-2,-2,-2), Sk4f(1,2,3,4) - Sk4f(3,4,5,6));
	ASSERT_EQ(Sk4f(3,8,15,24), Sk4f(1,2,3,4) * Sk4f(3,4,5,6));

	float third = 1.0f/3.0f;
	ASSERT_EQ(Sk4f(1third, 0.5f, 0.6f, 2third), Sk4f(1,2,3,4) / Sk4f(3,4,5,6));
	ASSERT_EQ(Sk4i(4,6,8,10), Sk4i(1,2,3,4) + Sk4i(3,4,5,6));
	ASSERT_EQ(Sk4i(-2,-2,-2,-2), Sk4i(1,2,3,4) - Sk4i(3,4,5,6));
	ASSERT_EQ(Sk4i(3,8,15,24), Sk4i(1,2,3,4) * Sk4i(3,4,5,6));
	}

	DEF_TEST(Sk4x_ExplicitPromotion, r) {
	ASSERT_EQ(Sk4f(2,4,6,8), Sk4f(1,2,3,4) * Sk4f(2.0f));
	}

	DEF_TEST(Sk4x_Sqrt, r) {
	Sk4f squares(4, 16, 25, 121),
	roots(2, 4, 5, 11);
	// .sqrt() should be pretty precise.
	Sk4f error = roots.subtract(squares.sqrt());
	REPORTER_ASSERT(r, error.greaterThanEqual(Sk4f(0.0f)).allTrue());
	REPORTER_ASSERT(r, error.lessThan(Sk4f(0.000001f)).allTrue());

	// .rsqrt() isn't so precise (for SSE), but should be pretty close.
	error = roots.subtract(squares.multiply(squares.rsqrt()));
	REPORTER_ASSERT(r, error.greaterThanEqual(Sk4f(0.0f)).allTrue());
	REPORTER_ASSERT(r, error.lessThan(Sk4f(0.01f)).allTrue());
	}

	DEF_TEST(Sk4x_Comparison, r) {
	ASSERT_EQ(Sk4f(1,2,3,4), Sk4f(1,2,3,4));
	ASSERT_NE(Sk4f(4,3,2,1), Sk4f(1,2,3,4));

	ASSERT_EQ(Sk4i(-1,-1,0,-1), Sk4f(1,2,5,4) == Sk4f(1,2,3,4));

	ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4f(1,2,3,4) < Sk4f(2,3,4,5));
	ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4f(1,2,3,4) <= Sk4f(2,3,4,5));
	ASSERT_EQ(Sk4i(0,0,0,0), Sk4f(1,2,3,4) > Sk4f(2,3,4,5));
	ASSERT_EQ(Sk4i(0,0,0,0), Sk4f(1,2,3,4) >= Sk4f(2,3,4,5));

	ASSERT_EQ(Sk4i(1,2,3,4), Sk4i(1,2,3,4));
	ASSERT_NE(Sk4i(4,3,2,1), Sk4i(1,2,3,4));

	ASSERT_EQ(Sk4i(-1,-1,0,-1), Sk4i(1,2,5,4) == Sk4i(1,2,3,4));

	ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4i(1,2,3,4) < Sk4i(2,3,4,5));
	ASSERT_EQ(Sk4i(-1,-1,-1,-1), Sk4i(1,2,3,4) <= Sk4i(2,3,4,5));
	ASSERT_EQ(Sk4i(0,0,0,0), Sk4i(1,2,3,4) > Sk4i(2,3,4,5));
	ASSERT_EQ(Sk4i(0,0,0,0), Sk4i(1,2,3,4) >= Sk4i(2,3,4,5));
	}

	DEF_TEST(Sk4x_MinMax, r) {
	ASSERT_EQ(Sk4f(1,2,2,1), Sk4f::Min(Sk4f(1,2,3,4), Sk4f(4,3,2,1)));
	ASSERT_EQ(Sk4f(4,3,3,4), Sk4f::Max(Sk4f(1,2,3,4), Sk4f(4,3,2,1)));
	ASSERT_EQ(Sk4i(1,2,2,1), Sk4i::Min(Sk4i(1,2,3,4), Sk4i(4,3,2,1)));
	ASSERT_EQ(Sk4i(4,3,3,4), Sk4i::Max(Sk4i(1,2,3,4), Sk4i(4,3,2,1)));
	}

	DEF_TEST(Sk4x_Swizzle, r) {
	ASSERT_EQ(Sk4f(3,4,1,2), Sk4f(1,2,3,4).zwxy());
	ASSERT_EQ(Sk4f(1,2,5,6), Sk4f::XYAB(Sk4f(1,2,3,4), Sk4f(5,6,7,8)));
	ASSERT_EQ(Sk4f(3,4,7,8), Sk4f::ZWCD(Sk4f(1,2,3,4), Sk4f(5,6,7,8)));
	ASSERT_EQ(Sk4i(3,4,1,2), Sk4i(1,2,3,4).zwxy());
	ASSERT_EQ(Sk4i(1,2,5,6), Sk4i::XYAB(Sk4i(1,2,3,4), Sk4i(5,6,7,8)));
	ASSERT_EQ(Sk4i(3,4,7,8), Sk4i::ZWCD(Sk4i(1,2,3,4), Sk4i(5,6,7,8)));
	}