// Copyright (c) the JPEG XL Project Authors. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. #include "lib/jxl/test_image.h" #include #include #include #include #include "lib/extras/dec/color_description.h" #include "lib/extras/dec/color_hints.h" #include "lib/extras/dec/decode.h" #include "lib/jxl/base/byte_order.h" #include "lib/jxl/base/random.h" #include "lib/jxl/base/span.h" #include "lib/jxl/base/status.h" #include "lib/jxl/color_encoding_internal.h" namespace jxl { namespace test { namespace { void StoreValue(float val, size_t bits_per_sample, JxlPixelFormat format, uint8_t** out) { const float mul = (1u << bits_per_sample) - 1; if (format.data_type == JXL_TYPE_UINT8) { **out = val * mul; } else if (format.data_type == JXL_TYPE_UINT16) { uint16_t uval = val * mul; if (SwapEndianness(format.endianness)) { uval = JXL_BSWAP16(uval); } memcpy(*out, &uval, 2); } else if (format.data_type == JXL_TYPE_FLOAT) { // TODO(szabadka) Add support for custom bits / exponent bits floats. if (SwapEndianness(format.endianness)) { val = BSwapFloat(val); } memcpy(*out, &val, 4); } else { // TODO(szabadka) Add support for FLOAT16. } *out += extras::PackedImage::BitsPerChannel(format.data_type) / 8; } void FillPackedImage(size_t bits_per_sample, uint16_t seed, extras::PackedImage* image) { const size_t xsize = image->xsize; const size_t ysize = image->ysize; const JxlPixelFormat format = image->format; // Cause more significant image difference for successive seeds. Rng generator(seed); // Returns random integer in interval [0, max_value) auto rngu = [&generator](size_t max_value) -> size_t { return generator.UniformU(0, max_value); }; // Returns random float in interval [0.0, max_value) auto rngf = [&generator](float max_value) { return generator.UniformF(0.0f, max_value); }; // Dark background gradient color float r0 = rngf(0.5f); float g0 = rngf(0.5f); float b0 = rngf(0.5f); float a0 = rngf(0.5f); float r1 = rngf(0.5f); float g1 = rngf(0.5f); float b1 = rngf(0.5f); float a1 = rngf(0.5f); // Circle with different color size_t circle_x = rngu(xsize); size_t circle_y = rngu(ysize); size_t circle_r = rngu(std::min(xsize, ysize)); // Rectangle with random noise size_t rect_x0 = rngu(xsize); size_t rect_y0 = rngu(ysize); size_t rect_x1 = rngu(xsize); size_t rect_y1 = rngu(ysize); if (rect_x1 < rect_x0) std::swap(rect_x0, rect_y1); if (rect_y1 < rect_y0) std::swap(rect_y0, rect_y1); // Create pixel content to test, actual content does not matter as long as it // can be compared after roundtrip. const float imul16 = 1.0f / 65536.0f; for (size_t y = 0; y < ysize; y++) { uint8_t* out = reinterpret_cast(image->pixels()) + y * image->stride; for (size_t x = 0; x < xsize; x++) { float r = r0 * (ysize - y - 1) / ysize + r1 * y / ysize; float g = g0 * (ysize - y - 1) / ysize + g1 * y / ysize; float b = b0 * (ysize - y - 1) / ysize + b1 * y / ysize; float a = a0 * (ysize - y - 1) / ysize + a1 * y / ysize; // put some shape in there for visual debugging if ((x - circle_x) * (x - circle_x) + (y - circle_y) * (y - circle_y) < circle_r * circle_r) { r = std::min(1.0f, ((65535 - x * y) ^ seed) * imul16); g = std::min(1.0f, ((x << 8) + y + seed) * imul16); b = std::min(1.0f, ((y << 8) + x * seed) * imul16); a = std::min(1.0f, (32768 + x * 256 - y) * imul16); } else if (x > rect_x0 && x < rect_x1 && y > rect_y0 && y < rect_y1) { r = rngf(1.0f); g = rngf(1.0f); b = rngf(1.0f); a = rngf(1.0f); } if (format.num_channels == 1) { StoreValue(g, bits_per_sample, format, &out); } else if (format.num_channels == 2) { StoreValue(g, bits_per_sample, format, &out); StoreValue(a, bits_per_sample, format, &out); } else if (format.num_channels == 3) { StoreValue(r, bits_per_sample, format, &out); StoreValue(g, bits_per_sample, format, &out); StoreValue(b, bits_per_sample, format, &out); } else if (format.num_channels == 4) { StoreValue(r, bits_per_sample, format, &out); StoreValue(g, bits_per_sample, format, &out); StoreValue(b, bits_per_sample, format, &out); StoreValue(a, bits_per_sample, format, &out); } } } } } // namespace std::vector GetSomeTestImage(size_t xsize, size_t ysize, size_t num_channels, uint16_t seed) { // Cause more significant image difference for successive seeds. Rng generator(seed); // Returns random integer in interval [0, max_value) auto rng = [&generator](size_t max_value) -> size_t { return generator.UniformU(0, max_value); }; // Dark background gradient color uint16_t r0 = rng(32768); uint16_t g0 = rng(32768); uint16_t b0 = rng(32768); uint16_t a0 = rng(32768); uint16_t r1 = rng(32768); uint16_t g1 = rng(32768); uint16_t b1 = rng(32768); uint16_t a1 = rng(32768); // Circle with different color size_t circle_x = rng(xsize); size_t circle_y = rng(ysize); size_t circle_r = rng(std::min(xsize, ysize)); // Rectangle with random noise size_t rect_x0 = rng(xsize); size_t rect_y0 = rng(ysize); size_t rect_x1 = rng(xsize); size_t rect_y1 = rng(ysize); if (rect_x1 < rect_x0) std::swap(rect_x0, rect_y1); if (rect_y1 < rect_y0) std::swap(rect_y0, rect_y1); size_t num_pixels = xsize * ysize; // 16 bits per channel, big endian, 4 channels std::vector pixels(num_pixels * num_channels * 2); // Create pixel content to test, actual content does not matter as long as it // can be compared after roundtrip. for (size_t y = 0; y < ysize; y++) { for (size_t x = 0; x < xsize; x++) { uint16_t r = r0 * (ysize - y - 1) / ysize + r1 * y / ysize; uint16_t g = g0 * (ysize - y - 1) / ysize + g1 * y / ysize; uint16_t b = b0 * (ysize - y - 1) / ysize + b1 * y / ysize; uint16_t a = a0 * (ysize - y - 1) / ysize + a1 * y / ysize; // put some shape in there for visual debugging if ((x - circle_x) * (x - circle_x) + (y - circle_y) * (y - circle_y) < circle_r * circle_r) { r = (65535 - x * y) ^ seed; g = (x << 8) + y + seed; b = (y << 8) + x * seed; a = 32768 + x * 256 - y; } else if (x > rect_x0 && x < rect_x1 && y > rect_y0 && y < rect_y1) { r = rng(65536); g = rng(65536); b = rng(65536); a = rng(65536); } size_t i = (y * xsize + x) * 2 * num_channels; pixels[i + 0] = (r >> 8); pixels[i + 1] = (r & 255); if (num_channels >= 2) { // This may store what is called 'g' in the alpha channel of a 2-channel // image, but that's ok since the content is arbitrary pixels[i + 2] = (g >> 8); pixels[i + 3] = (g & 255); } if (num_channels >= 3) { pixels[i + 4] = (b >> 8); pixels[i + 5] = (b & 255); } if (num_channels >= 4) { pixels[i + 6] = (a >> 8); pixels[i + 7] = (a & 255); } } } return pixels; } TestImage::TestImage() { SetChannels(3); SetAllBitDepths(8); SetColorEncoding("RGB_D65_SRG_Rel_SRG"); } TestImage& TestImage::DecodeFromBytes(const std::vector& bytes) { ColorEncoding c_enc; JXL_CHECK(c_enc.FromExternal(ppf_.color_encoding)); extras::ColorHints color_hints; color_hints.Add("color_space", Description(c_enc)); JXL_CHECK(extras::DecodeBytes(Bytes(bytes), color_hints, &ppf_)); return *this; } TestImage& TestImage::ClearMetadata() { ppf_.metadata = extras::PackedMetadata(); return *this; } TestImage& TestImage::SetDimensions(size_t xsize, size_t ysize) { if (xsize <= ppf_.info.xsize && ysize <= ppf_.info.ysize) { for (auto& frame : ppf_.frames) { CropLayerInfo(xsize, ysize, &frame.frame_info.layer_info); CropImage(xsize, ysize, &frame.color); for (auto& ec : frame.extra_channels) { CropImage(xsize, ysize, &ec); } } } else { JXL_CHECK(ppf_.info.xsize == 0 && ppf_.info.ysize == 0); } ppf_.info.xsize = xsize; ppf_.info.ysize = ysize; return *this; } TestImage& TestImage::SetChannels(size_t num_channels) { JXL_CHECK(ppf_.frames.empty()); JXL_CHECK(!ppf_.preview_frame); ppf_.info.num_color_channels = num_channels < 3 ? 1 : 3; ppf_.info.num_extra_channels = num_channels - ppf_.info.num_color_channels; if (ppf_.info.num_extra_channels > 0 && ppf_.info.alpha_bits == 0) { ppf_.info.alpha_bits = ppf_.info.bits_per_sample; ppf_.info.alpha_exponent_bits = ppf_.info.exponent_bits_per_sample; } ppf_.extra_channels_info.clear(); for (size_t i = 1; i < ppf_.info.num_extra_channels; ++i) { extras::PackedExtraChannel ec; ec.index = i; JxlEncoderInitExtraChannelInfo(JXL_CHANNEL_ALPHA, &ec.ec_info); if (ec.ec_info.bits_per_sample == 0) { ec.ec_info.bits_per_sample = ppf_.info.bits_per_sample; ec.ec_info.exponent_bits_per_sample = ppf_.info.exponent_bits_per_sample; } ppf_.extra_channels_info.emplace_back(std::move(ec)); } format_.num_channels = std::min(static_cast(4), num_channels); if (ppf_.info.num_color_channels == 1 && ppf_.color_encoding.color_space != JXL_COLOR_SPACE_GRAY) { SetColorEncoding("Gra_D65_Rel_SRG"); } return *this; } // Sets the same bit depth on color, alpha and all extra channels. TestImage& TestImage::SetAllBitDepths(uint32_t bits_per_sample, uint32_t exponent_bits_per_sample) { ppf_.info.bits_per_sample = bits_per_sample; ppf_.info.exponent_bits_per_sample = exponent_bits_per_sample; if (ppf_.info.num_extra_channels > 0) { ppf_.info.alpha_bits = bits_per_sample; ppf_.info.alpha_exponent_bits = exponent_bits_per_sample; } for (auto& ec : ppf_.extra_channels_info) { ec.ec_info.bits_per_sample = bits_per_sample; ec.ec_info.exponent_bits_per_sample = exponent_bits_per_sample; } format_.data_type = DefaultDataType(ppf_.info); return *this; } TestImage& TestImage::SetDataType(JxlDataType data_type) { format_.data_type = data_type; return *this; } TestImage& TestImage::SetEndianness(JxlEndianness endianness) { format_.endianness = endianness; return *this; } TestImage& TestImage::SetRowAlignment(size_t align) { format_.align = align; return *this; } TestImage& TestImage::SetColorEncoding(const std::string& description) { JXL_CHECK(ParseDescription(description, &ppf_.color_encoding)); ColorEncoding c_enc; JXL_CHECK(c_enc.FromExternal(ppf_.color_encoding)); IccBytes icc = c_enc.ICC(); JXL_CHECK(!icc.empty()); ppf_.icc.assign(icc.begin(), icc.end()); return *this; } TestImage& TestImage::CoalesceGIFAnimationWithAlpha() { JXL_ASSIGN_OR_DIE(extras::PackedFrame canvas, ppf_.frames[0].Copy()); JXL_CHECK(canvas.color.format.num_channels == 3); JXL_CHECK(canvas.color.format.data_type == JXL_TYPE_UINT8); JXL_CHECK(canvas.extra_channels.size() == 1); for (size_t i = 1; i < ppf_.frames.size(); i++) { const extras::PackedFrame& frame = ppf_.frames[i]; JXL_CHECK(frame.extra_channels.size() == 1); const JxlLayerInfo& layer_info = frame.frame_info.layer_info; JXL_ASSIGN_OR_DIE(extras::PackedFrame rendered, canvas.Copy()); uint8_t* pixels_rendered = reinterpret_cast(rendered.color.pixels()); const uint8_t* pixels_frame = reinterpret_cast(frame.color.pixels()); uint8_t* alpha_rendered = reinterpret_cast(rendered.extra_channels[0].pixels()); const uint8_t* alpha_frame = reinterpret_cast(frame.extra_channels[0].pixels()); for (size_t y = 0; y < frame.color.ysize; y++) { for (size_t x = 0; x < frame.color.xsize; x++) { size_t idx_frame = y * frame.color.xsize + x; size_t idx_rendered = ((layer_info.crop_y0 + y) * rendered.color.xsize + (layer_info.crop_x0 + x)); if (alpha_frame[idx_frame] != 0) { memcpy(&pixels_rendered[idx_rendered * 3], &pixels_frame[idx_frame * 3], 3); alpha_rendered[idx_rendered] = alpha_frame[idx_frame]; } } } if (layer_info.save_as_reference != 0) { JXL_ASSIGN_OR_DIE(canvas, rendered.Copy()); } ppf_.frames[i] = std::move(rendered); } return *this; } TestImage::Frame::Frame(TestImage* parent, bool is_preview, size_t index) : parent_(parent), is_preview_(is_preview), index_(index) {} void TestImage::Frame::ZeroFill() { memset(frame().color.pixels(), 0, frame().color.pixels_size); for (auto& ec : frame().extra_channels) { memset(ec.pixels(), 0, ec.pixels_size); } } void TestImage::Frame::RandomFill(uint16_t seed) { FillPackedImage(ppf().info.bits_per_sample, seed, &frame().color); for (size_t i = 0; i < ppf().extra_channels_info.size(); ++i) { FillPackedImage(ppf().extra_channels_info[i].ec_info.bits_per_sample, seed + 1 + i, &frame().extra_channels[i]); } } void TestImage::Frame::SetValue(size_t y, size_t x, size_t c, float val) { const extras::PackedImage& color = frame().color; JxlPixelFormat format = color.format; JXL_CHECK(y < ppf().info.ysize); JXL_CHECK(x < ppf().info.xsize); JXL_CHECK(c < format.num_channels); size_t pwidth = extras::PackedImage::BitsPerChannel(format.data_type) / 8; size_t idx = ((y * color.xsize + x) * format.num_channels + c) * pwidth; uint8_t* pixels = reinterpret_cast(frame().color.pixels()); uint8_t* p = pixels + idx; StoreValue(val, ppf().info.bits_per_sample, frame().color.format, &p); } TestImage::Frame TestImage::AddFrame() { size_t index = ppf_.frames.size(); JXL_ASSIGN_OR_DIE( extras::PackedFrame frame, extras::PackedFrame::Create(ppf_.info.xsize, ppf_.info.ysize, format_)); for (size_t i = 0; i < ppf_.extra_channels_info.size(); ++i) { JxlPixelFormat ec_format = {1, format_.data_type, format_.endianness, 0}; JXL_ASSIGN_OR_DIE(extras::PackedImage image, extras::PackedImage::Create(ppf_.info.xsize, ppf_.info.ysize, ec_format)); frame.extra_channels.emplace_back(std::move(image)); } ppf_.frames.emplace_back(std::move(frame)); return Frame(this, false, index); } TestImage::Frame TestImage::AddPreview(size_t xsize, size_t ysize) { JXL_ASSIGN_OR_DIE(extras::PackedFrame frame, extras::PackedFrame::Create(xsize, ysize, format_)); for (size_t i = 0; i < ppf_.extra_channels_info.size(); ++i) { JxlPixelFormat ec_format = {1, format_.data_type, format_.endianness, 0}; JXL_ASSIGN_OR_DIE(extras::PackedImage image, extras::PackedImage::Create(xsize, ysize, ec_format)); frame.extra_channels.emplace_back(std::move(image)); } ppf_.preview_frame = make_unique(std::move(frame)); return Frame(this, true, 0); } void TestImage::CropLayerInfo(size_t xsize, size_t ysize, JxlLayerInfo* info) { if (info->crop_x0 < static_cast(xsize)) { info->xsize = std::min(info->xsize, xsize - info->crop_x0); } else { info->xsize = 0; } if (info->crop_y0 < static_cast(ysize)) { info->ysize = std::min(info->ysize, ysize - info->crop_y0); } else { info->ysize = 0; } } void TestImage::CropImage(size_t xsize, size_t ysize, extras::PackedImage* image) { size_t new_stride = (image->stride / image->xsize) * xsize; uint8_t* buf = reinterpret_cast(image->pixels()); for (size_t y = 0; y < ysize; ++y) { memmove(&buf[y * new_stride], &buf[y * image->stride], new_stride); } image->xsize = xsize; image->ysize = ysize; image->stride = new_stride; image->pixels_size = ysize * new_stride; } JxlDataType TestImage::DefaultDataType(const JxlBasicInfo& info) { if (info.bits_per_sample == 16 && info.exponent_bits_per_sample == 5) { return JXL_TYPE_FLOAT16; } else if (info.exponent_bits_per_sample > 0 || info.bits_per_sample > 16) { return JXL_TYPE_FLOAT; } else if (info.bits_per_sample > 8) { return JXL_TYPE_UINT16; } else { return JXL_TYPE_UINT8; } } } // namespace test } // namespace jxl