зеркало из https://github.com/mozilla/moz-skia.git
259 строки
8.4 KiB
C++
259 строки
8.4 KiB
C++
#include "Test.h"
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#include "SkColor.h"
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#define ASSERT(x) REPORTER_ASSERT(r, x)
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static uint8_t double_to_u8(double d) {
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SkASSERT(d >= 0);
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SkASSERT(d < 256);
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return uint8_t(d);
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}
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// All algorithms we're testing have this interface.
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// We want a single channel blend, src over dst, assuming src is premultiplied by srcAlpha.
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typedef uint8_t(*Blend)(uint8_t dst, uint8_t src, uint8_t srcAlpha);
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// This is our golden algorithm.
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static uint8_t blend_double_round(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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SkASSERT(src <= srcAlpha);
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return double_to_u8(0.5 + src + dst * (255.0 - srcAlpha) / 255.0);
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}
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static uint8_t abs_diff(uint8_t a, uint8_t b) {
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const int diff = a - b;
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return diff > 0 ? diff : -diff;
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}
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static void test(skiatest::Reporter* r, int maxDiff, Blend algorithm,
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uint8_t dst, uint8_t src, uint8_t alpha) {
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const uint8_t golden = blend_double_round(dst, src, alpha);
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const uint8_t blend = algorithm(dst, src, alpha);
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if (abs_diff(blend, golden) > maxDiff) {
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SkDebugf("dst %02x, src %02x, alpha %02x, |%02x - %02x| > %d\n",
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dst, src, alpha, blend, golden, maxDiff);
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ASSERT(abs_diff(blend, golden) <= maxDiff);
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}
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}
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// Exhaustively compare an algorithm against our golden, for a given alpha.
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static void test_alpha(skiatest::Reporter* r, uint8_t alpha, int maxDiff, Blend algorithm) {
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SkASSERT(maxDiff >= 0);
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for (unsigned src = 0; src <= alpha; src++) {
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for (unsigned dst = 0; dst < 256; dst++) {
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test(r, maxDiff, algorithm, dst, src, alpha);
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}
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}
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}
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// Exhaustively compare an algorithm against our golden, for a given dst.
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static void test_dst(skiatest::Reporter* r, uint8_t dst, int maxDiff, Blend algorithm) {
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SkASSERT(maxDiff >= 0);
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for (unsigned alpha = 0; alpha < 256; alpha++) {
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for (unsigned src = 0; src <= alpha; src++) {
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test(r, maxDiff, algorithm, dst, src, alpha);
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}
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}
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}
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static uint8_t blend_double_trunc(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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return double_to_u8(src + dst * (255.0 - srcAlpha) / 255.0);
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}
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static uint8_t blend_float_trunc(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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return double_to_u8(src + dst * (255.0f - srcAlpha) / 255.0f);
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}
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static uint8_t blend_float_round(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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return double_to_u8(0.5f + src + dst * (255.0f - srcAlpha) / 255.0f);
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}
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static uint8_t blend_255_trunc(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint16_t invAlpha = 255 - srcAlpha;
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const uint16_t product = dst * invAlpha;
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return src + (product >> 8);
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}
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static uint8_t blend_255_round(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint16_t invAlpha = 255 - srcAlpha;
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const uint16_t product = dst * invAlpha + 128;
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return src + (product >> 8);
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}
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static uint8_t blend_256_trunc(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint16_t invAlpha = 256 - (srcAlpha + (srcAlpha >> 7));
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const uint16_t product = dst * invAlpha;
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return src + (product >> 8);
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}
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static uint8_t blend_256_round(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint16_t invAlpha = 256 - (srcAlpha + (srcAlpha >> 7));
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const uint16_t product = dst * invAlpha + 128;
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return src + (product >> 8);
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}
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static uint8_t blend_256_round_alt(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint8_t invAlpha8 = 255 - srcAlpha;
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const uint16_t invAlpha = invAlpha8 + (invAlpha8 >> 7);
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const uint16_t product = dst * invAlpha + 128;
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return src + (product >> 8);
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}
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static uint8_t blend_256_plus1_trunc(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint16_t invAlpha = 256 - (srcAlpha + 1);
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const uint16_t product = dst * invAlpha;
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return src + (product >> 8);
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}
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static uint8_t blend_256_plus1_round(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint16_t invAlpha = 256 - (srcAlpha + 1);
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const uint16_t product = dst * invAlpha + 128;
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return src + (product >> 8);
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}
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static uint8_t blend_perfect(uint8_t dst, uint8_t src, uint8_t srcAlpha) {
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const uint8_t invAlpha = 255 - srcAlpha;
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const uint16_t product = dst * invAlpha + 128;
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return src + ((product + (product >> 8)) >> 8);
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}
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// We want 0 diff whenever src is fully transparent.
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DEF_TEST(Blend_alpha_0x00, r) {
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const uint8_t alpha = 0x00;
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// GOOD
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test_alpha(r, alpha, 0, blend_256_round);
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test_alpha(r, alpha, 0, blend_256_round_alt);
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test_alpha(r, alpha, 0, blend_256_trunc);
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test_alpha(r, alpha, 0, blend_double_trunc);
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test_alpha(r, alpha, 0, blend_float_round);
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test_alpha(r, alpha, 0, blend_float_trunc);
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test_alpha(r, alpha, 0, blend_perfect);
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// BAD
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test_alpha(r, alpha, 1, blend_255_round);
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test_alpha(r, alpha, 1, blend_255_trunc);
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test_alpha(r, alpha, 1, blend_256_plus1_round);
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test_alpha(r, alpha, 1, blend_256_plus1_trunc);
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}
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// We want 0 diff whenever dst is 0.
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DEF_TEST(Blend_dst_0x00, r) {
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const uint8_t dst = 0x00;
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// GOOD
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test_dst(r, dst, 0, blend_255_round);
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test_dst(r, dst, 0, blend_255_trunc);
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test_dst(r, dst, 0, blend_256_plus1_round);
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test_dst(r, dst, 0, blend_256_plus1_trunc);
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test_dst(r, dst, 0, blend_256_round);
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test_dst(r, dst, 0, blend_256_round_alt);
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test_dst(r, dst, 0, blend_256_trunc);
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test_dst(r, dst, 0, blend_double_trunc);
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test_dst(r, dst, 0, blend_float_round);
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test_dst(r, dst, 0, blend_float_trunc);
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test_dst(r, dst, 0, blend_perfect);
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// BAD
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}
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// We want 0 diff whenever src is fully opaque.
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DEF_TEST(Blend_alpha_0xFF, r) {
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const uint8_t alpha = 0xFF;
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// GOOD
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test_alpha(r, alpha, 0, blend_255_round);
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test_alpha(r, alpha, 0, blend_255_trunc);
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test_alpha(r, alpha, 0, blend_256_plus1_round);
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test_alpha(r, alpha, 0, blend_256_plus1_trunc);
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test_alpha(r, alpha, 0, blend_256_round);
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test_alpha(r, alpha, 0, blend_256_round_alt);
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test_alpha(r, alpha, 0, blend_256_trunc);
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test_alpha(r, alpha, 0, blend_double_trunc);
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test_alpha(r, alpha, 0, blend_float_round);
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test_alpha(r, alpha, 0, blend_float_trunc);
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test_alpha(r, alpha, 0, blend_perfect);
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// BAD
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}
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// We want 0 diff whenever dst is 0xFF.
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DEF_TEST(Blend_dst_0xFF, r) {
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const uint8_t dst = 0xFF;
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// GOOD
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test_dst(r, dst, 0, blend_256_round);
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test_dst(r, dst, 0, blend_256_round_alt);
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test_dst(r, dst, 0, blend_double_trunc);
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test_dst(r, dst, 0, blend_float_round);
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test_dst(r, dst, 0, blend_float_trunc);
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test_dst(r, dst, 0, blend_perfect);
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// BAD
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test_dst(r, dst, 1, blend_255_round);
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test_dst(r, dst, 1, blend_255_trunc);
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test_dst(r, dst, 1, blend_256_plus1_round);
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test_dst(r, dst, 1, blend_256_plus1_trunc);
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test_dst(r, dst, 1, blend_256_trunc);
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}
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// We'd like diff <= 1 everywhere.
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DEF_TEST(Blend_alpha_Exhaustive, r) {
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for (unsigned alpha = 0; alpha < 256; alpha++) {
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// PERFECT
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test_alpha(r, alpha, 0, blend_float_round);
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test_alpha(r, alpha, 0, blend_perfect);
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// GOOD
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test_alpha(r, alpha, 1, blend_255_round);
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test_alpha(r, alpha, 1, blend_256_plus1_round);
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test_alpha(r, alpha, 1, blend_256_round);
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test_alpha(r, alpha, 1, blend_256_round_alt);
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test_alpha(r, alpha, 1, blend_256_trunc);
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test_alpha(r, alpha, 1, blend_double_trunc);
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test_alpha(r, alpha, 1, blend_float_trunc);
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// BAD
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test_alpha(r, alpha, 2, blend_255_trunc);
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test_alpha(r, alpha, 2, blend_256_plus1_trunc);
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}
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}
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// We'd like diff <= 1 everywhere.
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DEF_TEST(Blend_dst_Exhaustive, r) {
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for (unsigned dst = 0; dst < 256; dst++) {
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// PERFECT
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test_dst(r, dst, 0, blend_float_round);
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test_dst(r, dst, 0, blend_perfect);
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// GOOD
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test_dst(r, dst, 1, blend_255_round);
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test_dst(r, dst, 1, blend_256_plus1_round);
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test_dst(r, dst, 1, blend_256_round);
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test_dst(r, dst, 1, blend_256_round_alt);
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test_dst(r, dst, 1, blend_256_trunc);
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test_dst(r, dst, 1, blend_double_trunc);
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test_dst(r, dst, 1, blend_float_trunc);
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// BAD
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test_dst(r, dst, 2, blend_255_trunc);
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test_dst(r, dst, 2, blend_256_plus1_trunc);
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}
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}
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// Overall summary:
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// PERFECT
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// blend_double_round
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// blend_float_round
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// blend_perfect
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// GOOD ENOUGH
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// blend_double_trunc
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// blend_float_trunc
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// blend_256_round
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// blend_256_round_alt
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// NOT GOOD ENOUGH
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// all others
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//
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// Algorithms that make sense to use in Skia: blend_256_round, blend_256_round_alt, blend_perfect
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