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skia / skia / refs/heads/main / . / tests / SwizzlerTest.cpp
blob: b5e19a9dc9f4d15f08043a551fe96ceef269c89d [file] [log] [blame]
/*
* Copyright 2015 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "include/codec/SkCodec.h"
#include "include/core/SkAlphaType.h"
#include "include/core/SkColorType.h"
#include "include/core/SkImageInfo.h"
#include "include/core/SkSwizzle.h"
#include "src/codec/SkSampler.h"
#include "src/core/SkSwizzlePriv.h"
#include "tests/Test.h"
#include <cstdint>
#include <cstring>
#include <memory>
static void check_fill(skiatest::Reporter* r,
const SkImageInfo& imageInfo,
uint32_t startRow,
uint32_t endRow,
size_t rowBytes,
uint32_t offset) {
// Calculate the total size of the image in bytes. Use the smallest possible size.
// The offset value tells us to adjust the pointer from the memory we allocate in order
// to test on different memory alignments. If offset is nonzero, we need to increase the
// size of the memory we allocate in order to make sure that we have enough. We are
// still allocating the smallest possible size.
const size_t totalBytes = imageInfo.computeByteSize(rowBytes) + offset;
// Create fake image data where every byte has a value of 0
std::unique_ptr<uint8_t[]> storage(new uint8_t[totalBytes]);
memset(storage.get(), 0, totalBytes);
// Adjust the pointer in order to test on different memory alignments
uint8_t* imageData = storage.get() + offset;
uint8_t* imageStart = imageData + rowBytes * startRow;
const SkImageInfo fillInfo = imageInfo.makeWH(imageInfo.width(), endRow - startRow + 1);
SkSampler::Fill(fillInfo, imageStart, rowBytes, SkCodec::kNo_ZeroInitialized);
// Ensure that the pixels are filled properly
// The bots should catch any memory corruption
uint8_t* indexPtr = imageData + startRow * rowBytes;
uint8_t* grayPtr = indexPtr;
uint32_t* colorPtr = (uint32_t*) indexPtr;
uint16_t* color565Ptr = (uint16_t*) indexPtr;
for (uint32_t y = startRow; y <= endRow; y++) {
for (int32_t x = 0; x < imageInfo.width(); x++) {
switch (imageInfo.colorType()) {
case kN32_SkColorType:
REPORTER_ASSERT(r, 0 == colorPtr[x]);
break;
case kGray_8_SkColorType:
REPORTER_ASSERT(r, 0 == grayPtr[x]);
break;
case kRGB_565_SkColorType:
REPORTER_ASSERT(r, 0 == color565Ptr[x]);
break;
default:
REPORTER_ASSERT(r, false);
break;
}
}
indexPtr += rowBytes;
colorPtr = (uint32_t*) indexPtr;
}
}
// Test Fill() with different combinations of dimensions, alignment, and padding
DEF_TEST(SwizzlerFill, r) {
// Test on an invalid width and representative widths
const uint32_t widths[] = { 0, 10, 50 };
// In order to call Fill(), there must be at least one row to fill
// Test on the smallest possible height and representative heights
const uint32_t heights[] = { 1, 5, 10 };
// Test on interesting possibilities for row padding
const uint32_t paddings[] = { 0, 4 };
// Iterate over test dimensions
for (uint32_t width : widths) {
for (uint32_t height : heights) {
// Create image info objects
const SkImageInfo colorInfo = SkImageInfo::MakeN32(width, height, kUnknown_SkAlphaType);
const SkImageInfo grayInfo = colorInfo.makeColorType(kGray_8_SkColorType);
const SkImageInfo color565Info = colorInfo.makeColorType(kRGB_565_SkColorType);
for (uint32_t padding : paddings) {
// Calculate row bytes
const size_t colorRowBytes = SkColorTypeBytesPerPixel(kN32_SkColorType) * width
+ padding;
const size_t indexRowBytes = width + padding;
const size_t grayRowBytes = indexRowBytes;
const size_t color565RowBytes =
SkColorTypeBytesPerPixel(kRGB_565_SkColorType) * width + padding;
// If there is padding, we can invent an offset to change the memory alignment
for (uint32_t offset = 0; offset <= padding; offset += 4) {
// Test all possible start rows with all possible end rows
for (uint32_t startRow = 0; startRow < height; startRow++) {
for (uint32_t endRow = startRow; endRow < height; endRow++) {
// Test fill with each color type
check_fill(r, colorInfo, startRow, endRow, colorRowBytes, offset);
check_fill(r, grayInfo, startRow, endRow, grayRowBytes, offset);
check_fill(r, color565Info, startRow, endRow, color565RowBytes, offset);
}
}
}
}
}
}
}
DEF_TEST(SwizzleOpts, r) {
uint32_t dst, src;
// forall c, c*255 == c, c*0 == 0
for (int c = 0; c <= 255; c++) {
src = (255<<24) | c;
SkOpts::RGBA_to_rgbA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == src);
SkOpts::RGBA_to_bgrA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == (uint32_t)((255<<24) | (c<<16)));
src = (0<<24) | c;
SkOpts::RGBA_to_rgbA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == 0);
SkOpts::RGBA_to_bgrA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == 0);
}
// check a totally arbitrary color
src = 0xFACEB004;
SkOpts::RGBA_to_rgbA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == 0xFACAAD04);
// swap red and blue
SkOpts::RGBA_to_BGRA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == 0xFA04B0CE);
// all together now
SkOpts::RGBA_to_bgrA(&dst, &src, 1);
REPORTER_ASSERT(r, dst == 0xFA04ADCA);
}
DEF_TEST(PublicSwizzleOpts, r) {
uint32_t dst, src;
// check a totally arbitrary color
src = 0xFACEB004;
SkSwapRB(&dst, &src, 1);
REPORTER_ASSERT(r, dst == 0xFA04B0CE);
}
using fn_reciprocal = float (*)(float);
static void test_reciprocal_alpha(
skiatest::Reporter* reporter,
fn_reciprocal test255, fn_reciprocal test1) {
REPORTER_ASSERT(reporter, test255(0) == 0);
for (uint32_t i = 1; i < 256; ++i) {
const float r = test255(i);
const float e = (255.0f / i);
REPORTER_ASSERT(reporter, r == e);
}
REPORTER_ASSERT(reporter, test1(0) == 0);
for (uint32_t i = 1; i < 256; ++i) {
const float normalized = i / 255.0f;
const float r = test1(normalized);
const float e = (1.0f / normalized);
REPORTER_ASSERT(reporter, r == e);
}
}
#define SK_OPTS_NS test
#define SK_OPTS_TARGET SK_OPTS_TARGET_DEFAULT
#include "src/opts/SkOpts_SetTarget.h"
#include "src/opts/SkSwizzler_opts.inc"
DEF_TEST(ReciprocalAlphaOptimized, reporter) {
test_reciprocal_alpha(reporter,
SK_OPTS_NS::reciprocal_alpha_times_255,
SK_OPTS_NS::reciprocal_alpha);
}
DEF_TEST(ReciprocalAlphaPortable, reporter) {
test_reciprocal_alpha(reporter,
SK_OPTS_NS::reciprocal_alpha_times_255_portable,
SK_OPTS_NS::reciprocal_alpha_portable);
}
// The stages of RasterPipeline unpremul calcExpected needs to simulate.
// SI void from_8888(U32 _8888, F* r, F* g, F* b, F* a) {
// *r = cast((_8888 ) & 0xff) * (1/255.0f);
// *g = cast((_8888 >> 8) & 0xff) * (1/255.0f);
// *b = cast((_8888 >> 16) & 0xff) * (1/255.0f);
// *a = cast((_8888 >> 24) ) * (1/255.0f);
// }
// STAGE(unpremul, NoCtx) {
// float inf = sk_bit_cast<float>(0x7f800000);
// auto scale = if_then_else(1.0f/a < inf, 1.0f/a, 0.0f);
// r *= scale;
// g *= scale;
// b *= scale;
// }
// STAGE(store_8888, const SkRasterPipeline_MemoryCtx* ctx) {
// auto ptr = ptr_at_xy<uint32_t>(ctx, dx,dy);
//
// U32 px = to_unorm(r, 255)
// | to_unorm(g, 255) << 8
// | to_unorm(b, 255) << 16
// | to_unorm(a, 255) << 24;
// store(ptr, px);
// }
uint32_t calcExpected(float alpha, float comp) {
if (alpha == 0) {
return 0;
}
const float normalized = comp * (1.0f / 255.0f);
const float normalizedA = alpha * (1.0f / 255.0f);
const float inverseAlpha = 1.0f / normalizedA;
const float unpremul = normalized * inverseAlpha;
const float scaledAndPinned = std::min(255.0f, unpremul * 255.0f);
return SK_OPTS_NS::pixel_round_as_RP(scaledAndPinned);
};
DEF_TEST(UnpremulSimulatingRP, reporter) {
for (uint32_t a = 0; a < 256; ++a) {
for (uint32_t c = 0; c < 256; ++c) {
const uint32_t expected = calcExpected(a, c);
const float normalizedA = a * (1.0f / 255.0f);
const float invA = SK_OPTS_NS::reciprocal_alpha(normalizedA);
const uint32_t actual = SK_OPTS_NS::unpremul_simulating_RP(invA, c);
if (actual != expected) {
SkDebugf("a: %u c: %u expected: %u actual: %u\n", a, c, expected, actual);
}
REPORTER_ASSERT(reporter, actual == expected);
}
}
}
#include "src/opts/SkOpts_RestoreTarget.h"