// 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/enc_patch_dictionary.h" #include #include #include #include #include #include #include #include #include #include "lib/jxl/ans_params.h" #include "lib/jxl/base/compiler_specific.h" #include "lib/jxl/base/override.h" #include "lib/jxl/base/random.h" #include "lib/jxl/base/status.h" #include "lib/jxl/chroma_from_luma.h" #include "lib/jxl/color_management.h" #include "lib/jxl/common.h" #include "lib/jxl/dec_cache.h" #include "lib/jxl/dec_frame.h" #include "lib/jxl/enc_ans.h" #include "lib/jxl/enc_cache.h" #include "lib/jxl/enc_dot_dictionary.h" #include "lib/jxl/enc_frame.h" #include "lib/jxl/entropy_coder.h" #include "lib/jxl/frame_header.h" #include "lib/jxl/image.h" #include "lib/jxl/image_bundle.h" #include "lib/jxl/image_ops.h" #include "lib/jxl/patch_dictionary_internal.h" namespace jxl { // static void PatchDictionaryEncoder::Encode(const PatchDictionary& pdic, BitWriter* writer, size_t layer, AuxOut* aux_out) { JXL_ASSERT(pdic.HasAny()); std::vector> tokens(1); auto add_num = [&](int context, size_t num) { tokens[0].emplace_back(context, num); }; size_t num_ref_patch = 0; for (size_t i = 0; i < pdic.positions_.size();) { size_t i_start = i; while (i < pdic.positions_.size() && pdic.positions_[i].ref_pos == pdic.positions_[i_start].ref_pos) { i++; } num_ref_patch++; } add_num(kNumRefPatchContext, num_ref_patch); for (size_t i = 0; i < pdic.positions_.size();) { size_t i_start = i; while (i < pdic.positions_.size() && pdic.positions_[i].ref_pos == pdic.positions_[i_start].ref_pos) { i++; } size_t num = i - i_start; JXL_ASSERT(num > 0); add_num(kReferenceFrameContext, pdic.positions_[i_start].ref_pos.ref); add_num(kPatchReferencePositionContext, pdic.positions_[i_start].ref_pos.x0); add_num(kPatchReferencePositionContext, pdic.positions_[i_start].ref_pos.y0); add_num(kPatchSizeContext, pdic.positions_[i_start].ref_pos.xsize - 1); add_num(kPatchSizeContext, pdic.positions_[i_start].ref_pos.ysize - 1); add_num(kPatchCountContext, num - 1); for (size_t j = i_start; j < i; j++) { const PatchPosition& pos = pdic.positions_[j]; if (j == i_start) { add_num(kPatchPositionContext, pos.x); add_num(kPatchPositionContext, pos.y); } else { add_num(kPatchOffsetContext, PackSigned(pos.x - pdic.positions_[j - 1].x)); add_num(kPatchOffsetContext, PackSigned(pos.y - pdic.positions_[j - 1].y)); } JXL_ASSERT(pdic.shared_->metadata->m.extra_channel_info.size() + 1 == pos.blending.size()); for (size_t i = 0; i < pdic.shared_->metadata->m.extra_channel_info.size() + 1; i++) { const PatchBlending& info = pos.blending[i]; add_num(kPatchBlendModeContext, static_cast(info.mode)); if (UsesAlpha(info.mode) && pdic.shared_->metadata->m.extra_channel_info.size() > 1) { add_num(kPatchAlphaChannelContext, info.alpha_channel); } if (UsesClamp(info.mode)) { add_num(kPatchClampContext, info.clamp); } } } } EntropyEncodingData codes; std::vector context_map; BuildAndEncodeHistograms(HistogramParams(), kNumPatchDictionaryContexts, tokens, &codes, &context_map, writer, layer, aux_out); WriteTokens(tokens[0], codes, context_map, writer, layer, aux_out); } // static void PatchDictionaryEncoder::SubtractFrom(const PatchDictionary& pdic, Image3F* opsin) { // TODO(veluca): this can likely be optimized knowing it runs on full images. for (size_t y = 0; y < opsin->ysize(); y++) { if (y + 1 >= pdic.patch_starts_.size()) continue; float* JXL_RESTRICT rows[3] = { opsin->PlaneRow(0, y), opsin->PlaneRow(1, y), opsin->PlaneRow(2, y), }; for (size_t id = pdic.patch_starts_[y]; id < pdic.patch_starts_[y + 1]; id++) { const PatchPosition& pos = pdic.positions_[pdic.sorted_patches_[id]]; size_t by = pos.y; size_t bx = pos.x; size_t xsize = pos.ref_pos.xsize; JXL_DASSERT(y >= by); JXL_DASSERT(y < by + pos.ref_pos.ysize); size_t iy = y - by; size_t ref = pos.ref_pos.ref; const float* JXL_RESTRICT ref_rows[3] = { pdic.shared_->reference_frames[ref].frame->color()->ConstPlaneRow( 0, pos.ref_pos.y0 + iy) + pos.ref_pos.x0, pdic.shared_->reference_frames[ref].frame->color()->ConstPlaneRow( 1, pos.ref_pos.y0 + iy) + pos.ref_pos.x0, pdic.shared_->reference_frames[ref].frame->color()->ConstPlaneRow( 2, pos.ref_pos.y0 + iy) + pos.ref_pos.x0, }; for (size_t ix = 0; ix < xsize; ix++) { for (size_t c = 0; c < 3; c++) { if (pos.blending[0].mode == PatchBlendMode::kAdd) { rows[c][bx + ix] -= ref_rows[c][ix]; } else if (pos.blending[0].mode == PatchBlendMode::kReplace) { rows[c][bx + ix] = 0; } else if (pos.blending[0].mode == PatchBlendMode::kNone) { // Nothing to do. } else { JXL_ABORT("Blending mode %u not yet implemented", (uint32_t)pos.blending[0].mode); } } } } } } namespace { struct PatchColorspaceInfo { float kChannelDequant[3]; float kChannelWeights[3]; explicit PatchColorspaceInfo(bool is_xyb) { if (is_xyb) { kChannelDequant[0] = 0.01615; kChannelDequant[1] = 0.08875; kChannelDequant[2] = 0.1922; kChannelWeights[0] = 30.0; kChannelWeights[1] = 3.0; kChannelWeights[2] = 1.0; } else { kChannelDequant[0] = 20.0f / 255; kChannelDequant[1] = 22.0f / 255; kChannelDequant[2] = 20.0f / 255; kChannelWeights[0] = 0.017 * 255; kChannelWeights[1] = 0.02 * 255; kChannelWeights[2] = 0.017 * 255; } } float ScaleForQuantization(float val, size_t c) { return val / kChannelDequant[c]; } int Quantize(float val, size_t c) { return truncf(ScaleForQuantization(val, c)); } bool is_similar_v(const float v1[3], const float v2[3], float threshold) { float distance = 0; for (size_t c = 0; c < 3; c++) { distance += std::fabs(v1[c] - v2[c]) * kChannelWeights[c]; } return distance <= threshold; } }; std::vector FindTextLikePatches( const Image3F& opsin, const PassesEncoderState* JXL_RESTRICT state, ThreadPool* pool, AuxOut* aux_out, bool is_xyb) { if (state->cparams.patches == Override::kOff) return {}; PatchColorspaceInfo pci(is_xyb); float kSimilarThreshold = 0.8f; auto is_similar_impl = [&pci](std::pair p1, std::pair p2, const float* JXL_RESTRICT rows[3], size_t stride, float threshold) { float v1[3], v2[3]; for (size_t c = 0; c < 3; c++) { v1[c] = rows[c][p1.second * stride + p1.first]; v2[c] = rows[c][p2.second * stride + p2.first]; } return pci.is_similar_v(v1, v2, threshold); }; std::atomic has_screenshot_areas{false}; const size_t opsin_stride = opsin.PixelsPerRow(); const float* JXL_RESTRICT opsin_rows[3] = {opsin.ConstPlaneRow(0, 0), opsin.ConstPlaneRow(1, 0), opsin.ConstPlaneRow(2, 0)}; auto is_same = [&opsin_rows, opsin_stride](std::pair p1, std::pair p2) { for (size_t c = 0; c < 3; c++) { float v1 = opsin_rows[c][p1.second * opsin_stride + p1.first]; float v2 = opsin_rows[c][p2.second * opsin_stride + p2.first]; if (std::fabs(v1 - v2) > 1e-4) { return false; } } return true; }; auto is_similar = [&](std::pair p1, std::pair p2) { return is_similar_impl(p1, p2, opsin_rows, opsin_stride, kSimilarThreshold); }; constexpr int64_t kPatchSide = 4; constexpr int64_t kExtraSide = 4; // Look for kPatchSide size squares, naturally aligned, that all have the same // pixel values. ImageB is_screenshot_like(DivCeil(opsin.xsize(), kPatchSide), DivCeil(opsin.ysize(), kPatchSide)); ZeroFillImage(&is_screenshot_like); uint8_t* JXL_RESTRICT screenshot_row = is_screenshot_like.Row(0); const size_t screenshot_stride = is_screenshot_like.PixelsPerRow(); const auto process_row = [&](const uint32_t y, size_t /* thread */) { for (uint64_t x = 0; x < opsin.xsize() / kPatchSide; x++) { bool all_same = true; for (size_t iy = 0; iy < static_cast(kPatchSide); iy++) { for (size_t ix = 0; ix < static_cast(kPatchSide); ix++) { size_t cx = x * kPatchSide + ix; size_t cy = y * kPatchSide + iy; if (!is_same({cx, cy}, {x * kPatchSide, y * kPatchSide})) { all_same = false; break; } } } if (!all_same) continue; size_t num = 0; size_t num_same = 0; for (int64_t iy = -kExtraSide; iy < kExtraSide + kPatchSide; iy++) { for (int64_t ix = -kExtraSide; ix < kExtraSide + kPatchSide; ix++) { int64_t cx = x * kPatchSide + ix; int64_t cy = y * kPatchSide + iy; if (cx < 0 || static_cast(cx) >= opsin.xsize() || // cy < 0 || static_cast(cy) >= opsin.ysize()) { continue; } num++; if (is_same({cx, cy}, {x * kPatchSide, y * kPatchSide})) num_same++; } } // Too few equal pixels nearby. if (num_same * 8 < num * 7) continue; screenshot_row[y * screenshot_stride + x] = 1; has_screenshot_areas = true; } }; JXL_CHECK(RunOnPool(pool, 0, opsin.ysize() / kPatchSide, ThreadPool::NoInit, process_row, "IsScreenshotLike")); // TODO(veluca): also parallelize the rest of this function. if (WantDebugOutput(aux_out)) { aux_out->DumpPlaneNormalized("screenshot_like", is_screenshot_like); } constexpr int kSearchRadius = 1; if (!ApplyOverride(state->cparams.patches, has_screenshot_areas)) { return {}; } // Search for "similar enough" pixels near the screenshot-like areas. ImageB is_background(opsin.xsize(), opsin.ysize()); ZeroFillImage(&is_background); Image3F background(opsin.xsize(), opsin.ysize()); ZeroFillImage(&background); constexpr size_t kDistanceLimit = 50; float* JXL_RESTRICT background_rows[3] = { background.PlaneRow(0, 0), background.PlaneRow(1, 0), background.PlaneRow(2, 0), }; const size_t background_stride = background.PixelsPerRow(); uint8_t* JXL_RESTRICT is_background_row = is_background.Row(0); const size_t is_background_stride = is_background.PixelsPerRow(); std::vector< std::pair, std::pair>> queue; size_t queue_front = 0; for (size_t y = 0; y < opsin.ysize(); y++) { for (size_t x = 0; x < opsin.xsize(); x++) { if (!screenshot_row[screenshot_stride * (y / kPatchSide) + (x / kPatchSide)]) continue; queue.push_back({{x, y}, {x, y}}); } } while (queue.size() != queue_front) { std::pair cur = queue[queue_front].first; std::pair src = queue[queue_front].second; queue_front++; if (is_background_row[cur.second * is_background_stride + cur.first]) continue; is_background_row[cur.second * is_background_stride + cur.first] = 1; for (size_t c = 0; c < 3; c++) { background_rows[c][cur.second * background_stride + cur.first] = opsin_rows[c][src.second * opsin_stride + src.first]; } for (int dx = -kSearchRadius; dx <= kSearchRadius; dx++) { for (int dy = -kSearchRadius; dy <= kSearchRadius; dy++) { if (dx == 0 && dy == 0) continue; int next_first = cur.first + dx; int next_second = cur.second + dy; if (next_first < 0 || next_second < 0 || static_cast(next_first) >= opsin.xsize() || static_cast(next_second) >= opsin.ysize()) { continue; } if (static_cast( std::abs(next_first - static_cast(src.first)) + std::abs(next_second - static_cast(src.second))) > kDistanceLimit) { continue; } std::pair next{next_first, next_second}; if (is_similar(src, next)) { if (!screenshot_row[next.second / kPatchSide * screenshot_stride + next.first / kPatchSide] || is_same(src, next)) { if (!is_background_row[next.second * is_background_stride + next.first]) queue.emplace_back(next, src); } } } } } queue.clear(); ImageF ccs; Rng rng(0); bool paint_ccs = false; if (WantDebugOutput(aux_out)) { aux_out->DumpPlaneNormalized("is_background", is_background); if (is_xyb) { aux_out->DumpXybImage("background", background); } else { aux_out->DumpImage("background", background); } ccs = ImageF(opsin.xsize(), opsin.ysize()); ZeroFillImage(&ccs); paint_ccs = true; } constexpr float kVerySimilarThreshold = 0.03f; constexpr float kHasSimilarThreshold = 0.03f; const float* JXL_RESTRICT const_background_rows[3] = { background_rows[0], background_rows[1], background_rows[2]}; auto is_similar_b = [&](std::pair p1, std::pair p2) { return is_similar_impl(p1, p2, const_background_rows, background_stride, kVerySimilarThreshold); }; constexpr int kMinPeak = 2; constexpr int kHasSimilarRadius = 2; std::vector info; // Find small CC outside the "similar enough" areas, compute bounding boxes, // and run heuristics to exclude some patches. ImageB visited(opsin.xsize(), opsin.ysize()); ZeroFillImage(&visited); uint8_t* JXL_RESTRICT visited_row = visited.Row(0); const size_t visited_stride = visited.PixelsPerRow(); std::vector> cc; std::vector> stack; for (size_t y = 0; y < opsin.ysize(); y++) { for (size_t x = 0; x < opsin.xsize(); x++) { if (is_background_row[y * is_background_stride + x]) continue; cc.clear(); stack.clear(); stack.emplace_back(x, y); size_t min_x = x; size_t max_x = x; size_t min_y = y; size_t max_y = y; std::pair reference; bool found_border = false; bool all_similar = true; while (!stack.empty()) { std::pair cur = stack.back(); stack.pop_back(); if (visited_row[cur.second * visited_stride + cur.first]) continue; visited_row[cur.second * visited_stride + cur.first] = 1; if (cur.first < min_x) min_x = cur.first; if (cur.first > max_x) max_x = cur.first; if (cur.second < min_y) min_y = cur.second; if (cur.second > max_y) max_y = cur.second; if (paint_ccs) { cc.push_back(cur); } for (int dx = -kSearchRadius; dx <= kSearchRadius; dx++) { for (int dy = -kSearchRadius; dy <= kSearchRadius; dy++) { if (dx == 0 && dy == 0) continue; int next_first = static_cast(cur.first) + dx; int next_second = static_cast(cur.second) + dy; if (next_first < 0 || next_second < 0 || static_cast(next_first) >= opsin.xsize() || static_cast(next_second) >= opsin.ysize()) { continue; } std::pair next{next_first, next_second}; if (!is_background_row[next.second * is_background_stride + next.first]) { stack.push_back(next); } else { if (!found_border) { reference = next; found_border = true; } else { if (!is_similar_b(next, reference)) all_similar = false; } } } } } if (!found_border || !all_similar || max_x - min_x >= kMaxPatchSize || max_y - min_y >= kMaxPatchSize) { continue; } size_t bpos = background_stride * reference.second + reference.first; float ref[3] = {background_rows[0][bpos], background_rows[1][bpos], background_rows[2][bpos]}; bool has_similar = false; for (size_t iy = std::max( static_cast(min_y) - kHasSimilarRadius, 0); iy < std::min(max_y + kHasSimilarRadius + 1, opsin.ysize()); iy++) { for (size_t ix = std::max( static_cast(min_x) - kHasSimilarRadius, 0); ix < std::min(max_x + kHasSimilarRadius + 1, opsin.xsize()); ix++) { size_t opos = opsin_stride * iy + ix; float px[3] = {opsin_rows[0][opos], opsin_rows[1][opos], opsin_rows[2][opos]}; if (pci.is_similar_v(ref, px, kHasSimilarThreshold)) { has_similar = true; } } } if (!has_similar) continue; info.emplace_back(); info.back().second.emplace_back(min_x, min_y); QuantizedPatch& patch = info.back().first; patch.xsize = max_x - min_x + 1; patch.ysize = max_y - min_y + 1; int max_value = 0; for (size_t c : {1, 0, 2}) { for (size_t iy = min_y; iy <= max_y; iy++) { for (size_t ix = min_x; ix <= max_x; ix++) { size_t offset = (iy - min_y) * patch.xsize + ix - min_x; patch.fpixels[c][offset] = opsin_rows[c][iy * opsin_stride + ix] - ref[c]; int val = pci.Quantize(patch.fpixels[c][offset], c); patch.pixels[c][offset] = val; if (std::abs(val) > max_value) max_value = std::abs(val); } } } if (max_value < kMinPeak) { info.pop_back(); continue; } if (paint_ccs) { float cc_color = rng.UniformF(0.5, 1.0); for (std::pair p : cc) { ccs.Row(p.second)[p.first] = cc_color; } } } } if (paint_ccs) { JXL_ASSERT(WantDebugOutput(aux_out)); aux_out->DumpPlaneNormalized("ccs", ccs); } if (info.empty()) { return {}; } // Remove duplicates. constexpr size_t kMinPatchOccurences = 2; std::sort(info.begin(), info.end()); size_t unique = 0; for (size_t i = 1; i < info.size(); i++) { if (info[i].first == info[unique].first) { info[unique].second.insert(info[unique].second.end(), info[i].second.begin(), info[i].second.end()); } else { if (info[unique].second.size() >= kMinPatchOccurences) { unique++; } info[unique] = info[i]; } } if (info[unique].second.size() >= kMinPatchOccurences) { unique++; } info.resize(unique); size_t max_patch_size = 0; for (size_t i = 0; i < info.size(); i++) { size_t pixels = info[i].first.xsize * info[i].first.ysize; if (pixels > max_patch_size) max_patch_size = pixels; } // don't use patches if all patches are smaller than this constexpr size_t kMinMaxPatchSize = 20; if (max_patch_size < kMinMaxPatchSize) return {}; return info; } } // namespace void FindBestPatchDictionary(const Image3F& opsin, PassesEncoderState* JXL_RESTRICT state, const JxlCmsInterface& cms, ThreadPool* pool, AuxOut* aux_out, bool is_xyb) { std::vector info = FindTextLikePatches(opsin, state, pool, aux_out, is_xyb); // TODO(veluca): this doesn't work if both dots and patches are enabled. // For now, since dots and patches are not likely to occur in the same kind of // images, disable dots if some patches were found. if (info.empty() && ApplyOverride( state->cparams.dots, state->cparams.speed_tier <= SpeedTier::kSquirrel && state->cparams.butteraugli_distance >= kMinButteraugliForDots)) { info = FindDotDictionary(state->cparams, opsin, state->shared.cmap, pool); } if (info.empty()) return; std::sort( info.begin(), info.end(), [&](const PatchInfo& a, const PatchInfo& b) { return a.first.xsize * a.first.ysize > b.first.xsize * b.first.ysize; }); size_t max_x_size = 0; size_t max_y_size = 0; size_t total_pixels = 0; for (size_t i = 0; i < info.size(); i++) { size_t pixels = info[i].first.xsize * info[i].first.ysize; if (max_x_size < info[i].first.xsize) max_x_size = info[i].first.xsize; if (max_y_size < info[i].first.ysize) max_y_size = info[i].first.ysize; total_pixels += pixels; } // Bin-packing & conversion of patches. constexpr float kBinPackingSlackness = 1.05f; size_t ref_xsize = std::max(max_x_size, std::sqrt(total_pixels)); size_t ref_ysize = std::max(max_y_size, std::sqrt(total_pixels)); std::vector> ref_positions(info.size()); // TODO(veluca): allow partial overlaps of patches that have the same pixels. size_t max_y = 0; do { max_y = 0; // Increase packed image size. ref_xsize = ref_xsize * kBinPackingSlackness + 1; ref_ysize = ref_ysize * kBinPackingSlackness + 1; ImageB occupied(ref_xsize, ref_ysize); ZeroFillImage(&occupied); uint8_t* JXL_RESTRICT occupied_rows = occupied.Row(0); size_t occupied_stride = occupied.PixelsPerRow(); bool success = true; // For every patch... for (size_t patch = 0; patch < info.size(); patch++) { size_t x0 = 0; size_t y0 = 0; size_t xsize = info[patch].first.xsize; size_t ysize = info[patch].first.ysize; bool found = false; // For every possible start position ... for (; y0 + ysize <= ref_ysize; y0++) { x0 = 0; for (; x0 + xsize <= ref_xsize; x0++) { bool has_occupied_pixel = false; size_t x = x0; // Check if it is possible to place the patch in this position in the // reference frame. for (size_t y = y0; y < y0 + ysize; y++) { x = x0; for (; x < x0 + xsize; x++) { if (occupied_rows[y * occupied_stride + x]) { has_occupied_pixel = true; break; } } } // end of positioning check if (!has_occupied_pixel) { found = true; break; } x0 = x; // Jump to next pixel after the occupied one. } if (found) break; } // end of start position checking // We didn't find a possible position: repeat from the beginning with a // larger reference frame size. if (!found) { success = false; break; } // We found a position: mark the corresponding positions in the reference // image as used. ref_positions[patch] = {x0, y0}; for (size_t y = y0; y < y0 + ysize; y++) { for (size_t x = x0; x < x0 + xsize; x++) { occupied_rows[y * occupied_stride + x] = true; } } max_y = std::max(max_y, y0 + ysize); } if (success) break; } while (true); JXL_ASSERT(ref_ysize >= max_y); ref_ysize = max_y; Image3F reference_frame(ref_xsize, ref_ysize); // TODO(veluca): figure out a better way to fill the image. ZeroFillImage(&reference_frame); std::vector positions; float* JXL_RESTRICT ref_rows[3] = { reference_frame.PlaneRow(0, 0), reference_frame.PlaneRow(1, 0), reference_frame.PlaneRow(2, 0), }; size_t ref_stride = reference_frame.PixelsPerRow(); for (size_t i = 0; i < info.size(); i++) { PatchReferencePosition ref_pos; ref_pos.xsize = info[i].first.xsize; ref_pos.ysize = info[i].first.ysize; ref_pos.x0 = ref_positions[i].first; ref_pos.y0 = ref_positions[i].second; ref_pos.ref = 0; for (size_t y = 0; y < ref_pos.ysize; y++) { for (size_t x = 0; x < ref_pos.xsize; x++) { for (size_t c = 0; c < 3; c++) { ref_rows[c][(y + ref_pos.y0) * ref_stride + x + ref_pos.x0] = info[i].first.fpixels[c][y * ref_pos.xsize + x]; } } } // Add color channels, ignore other channels. std::vector blending_info( state->shared.metadata->m.extra_channel_info.size() + 1, PatchBlending{PatchBlendMode::kNone, 0, false}); blending_info[0].mode = PatchBlendMode::kAdd; for (const auto& pos : info[i].second) { positions.emplace_back( PatchPosition{pos.first, pos.second, blending_info, ref_pos}); } } CompressParams cparams = state->cparams; // Recursive application of patches could create very weird issues. cparams.patches = Override::kOff; RoundtripPatchFrame(&reference_frame, state, 0, cparams, cms, pool, true); // TODO(veluca): this assumes that applying patches is commutative, which is // not true for all blending modes. This code only produces kAdd patches, so // this works out. std::sort(positions.begin(), positions.end()); PatchDictionaryEncoder::SetPositions(&state->shared.image_features.patches, std::move(positions)); } void RoundtripPatchFrame(Image3F* reference_frame, PassesEncoderState* JXL_RESTRICT state, int idx, CompressParams& cparams, const JxlCmsInterface& cms, ThreadPool* pool, bool subtract) { FrameInfo patch_frame_info; cparams.resampling = 1; cparams.ec_resampling = 1; cparams.dots = Override::kOff; cparams.noise = Override::kOff; cparams.modular_mode = true; cparams.responsive = 0; cparams.progressive_dc = 0; cparams.progressive_mode = false; cparams.qprogressive_mode = false; // Use gradient predictor and not Predictor::Best. cparams.options.predictor = Predictor::Gradient; patch_frame_info.save_as_reference = idx; // always saved. patch_frame_info.frame_type = FrameType::kReferenceOnly; patch_frame_info.save_before_color_transform = true; ImageBundle ib(&state->shared.metadata->m); // TODO(veluca): metadata.color_encoding is a lie: ib is in XYB, but there is // no simple way to express that yet. patch_frame_info.ib_needs_color_transform = false; ib.SetFromImage(std::move(*reference_frame), state->shared.metadata->m.color_encoding); if (!ib.metadata()->extra_channel_info.empty()) { // Add dummy extra channels to the patch image: patch encoding does not yet // support extra channels, but the codec expects that the amount of extra // channels in frames matches that in the metadata of the codestream. std::vector extra_channels; extra_channels.reserve(ib.metadata()->extra_channel_info.size()); for (size_t i = 0; i < ib.metadata()->extra_channel_info.size(); i++) { extra_channels.emplace_back(ib.xsize(), ib.ysize()); // Must initialize the image with data to not affect blending with // uninitialized memory. // TODO(lode): patches must copy and use the real extra channels instead. ZeroFillImage(&extra_channels.back()); } ib.SetExtraChannels(std::move(extra_channels)); } PassesEncoderState roundtrip_state; auto special_frame = std::unique_ptr(new BitWriter()); JXL_CHECK(EncodeFrame(cparams, patch_frame_info, state->shared.metadata, ib, &roundtrip_state, cms, pool, special_frame.get(), nullptr)); const Span encoded = special_frame->GetSpan(); state->special_frames.emplace_back(std::move(special_frame)); if (subtract) { BitReader br(encoded); ImageBundle decoded(&state->shared.metadata->m); PassesDecoderState dec_state; JXL_CHECK(dec_state.output_encoding_info.Set( *state->shared.metadata, ColorEncoding::LinearSRGB( state->shared.metadata->m.color_encoding.IsGray()))); JXL_CHECK(DecodeFrame({}, &dec_state, pool, &br, &decoded, *state->shared.metadata, /*constraints=*/nullptr)); size_t ref_xsize = dec_state.shared_storage.reference_frames[idx].storage.color()->xsize(); // if the frame itself uses patches, we need to decode another frame if (!ref_xsize) { JXL_CHECK(DecodeFrame({}, &dec_state, pool, &br, &decoded, *state->shared.metadata, /*constraints=*/nullptr)); } JXL_CHECK(br.Close()); state->shared.reference_frames[idx] = std::move(dec_state.shared_storage.reference_frames[idx]); } else { state->shared.reference_frames[idx].storage = std::move(ib); } state->shared.reference_frames[idx].frame = &state->shared.reference_frames[idx].storage; } } // namespace jxl