// 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/jpeg/dec_jpeg_data_writer.h" #include #include /* for memset, memcpy */ #include #include #include #include "lib/jxl/base/bits.h" #include "lib/jxl/common.h" #include "lib/jxl/image_bundle.h" #include "lib/jxl/jpeg/dec_jpeg_serialization_state.h" #include "lib/jxl/jpeg/jpeg_data.h" namespace jxl { namespace jpeg { namespace { enum struct SerializationStatus { NEEDS_MORE_INPUT, NEEDS_MORE_OUTPUT, ERROR, DONE }; const int kJpegPrecision = 8; // JpegBitWriter: buffer size const size_t kJpegBitWriterChunkSize = 16384; // DCTCodingState: maximum number of correction bits to buffer const int kJPEGMaxCorrectionBits = 1u << 16; // Returns non-zero if and only if x has a zero byte, i.e. one of // x & 0xff, x & 0xff00, ..., x & 0xff00000000000000 is zero. static JXL_INLINE uint64_t HasZeroByte(uint64_t x) { return (x - 0x0101010101010101ULL) & ~x & 0x8080808080808080ULL; } void JpegBitWriterInit(JpegBitWriter* bw, std::deque* output_queue) { bw->output = output_queue; bw->chunk = OutputChunk(kJpegBitWriterChunkSize); bw->pos = 0; bw->put_buffer = 0; bw->put_bits = 64; bw->healthy = true; bw->data = bw->chunk.buffer->data(); } static JXL_NOINLINE void SwapBuffer(JpegBitWriter* bw) { bw->chunk.len = bw->pos; bw->output->emplace_back(std::move(bw->chunk)); bw->chunk = OutputChunk(kJpegBitWriterChunkSize); bw->data = bw->chunk.buffer->data(); bw->pos = 0; } static JXL_INLINE void Reserve(JpegBitWriter* bw, size_t n_bytes) { if (JXL_UNLIKELY((bw->pos + n_bytes) > kJpegBitWriterChunkSize)) { SwapBuffer(bw); } } /** * Writes the given byte to the output, writes an extra zero if byte is 0xFF. * * This method is "careless" - caller must make sure that there is enough * space in the output buffer. Emits up to 2 bytes to buffer. */ static JXL_INLINE void EmitByte(JpegBitWriter* bw, int byte) { bw->data[bw->pos++] = byte; if (byte == 0xFF) bw->data[bw->pos++] = 0; } static JXL_INLINE void DischargeBitBuffer(JpegBitWriter* bw) { // At this point we are ready to emit the most significant 6 bytes of // put_buffer_ to the output. // The JPEG format requires that after every 0xff byte in the entropy // coded section, there is a zero byte, therefore we first check if any of // the 6 most significant bytes of put_buffer_ is 0xFF. Reserve(bw, 12); if (HasZeroByte(~bw->put_buffer | 0xFFFF)) { // We have a 0xFF byte somewhere, examine each byte and append a zero // byte if necessary. EmitByte(bw, (bw->put_buffer >> 56) & 0xFF); EmitByte(bw, (bw->put_buffer >> 48) & 0xFF); EmitByte(bw, (bw->put_buffer >> 40) & 0xFF); EmitByte(bw, (bw->put_buffer >> 32) & 0xFF); EmitByte(bw, (bw->put_buffer >> 24) & 0xFF); EmitByte(bw, (bw->put_buffer >> 16) & 0xFF); } else { // We don't have any 0xFF bytes, output all 6 bytes without checking. bw->data[bw->pos] = (bw->put_buffer >> 56) & 0xFF; bw->data[bw->pos + 1] = (bw->put_buffer >> 48) & 0xFF; bw->data[bw->pos + 2] = (bw->put_buffer >> 40) & 0xFF; bw->data[bw->pos + 3] = (bw->put_buffer >> 32) & 0xFF; bw->data[bw->pos + 4] = (bw->put_buffer >> 24) & 0xFF; bw->data[bw->pos + 5] = (bw->put_buffer >> 16) & 0xFF; bw->pos += 6; } bw->put_buffer <<= 48; bw->put_bits += 48; } static JXL_INLINE void WriteBits(JpegBitWriter* bw, int nbits, uint64_t bits) { // This is an optimization; if everything goes well, // then |nbits| is positive; if non-existing Huffman symbol is going to be // encoded, its length should be zero; later encoder could check the // "health" of JpegBitWriter. if (nbits == 0) { bw->healthy = false; return; } bw->put_bits -= nbits; bw->put_buffer |= (bits << bw->put_bits); if (bw->put_bits <= 16) DischargeBitBuffer(bw); } void EmitMarker(JpegBitWriter* bw, int marker) { Reserve(bw, 2); JXL_DASSERT(marker != 0xFF); bw->data[bw->pos++] = 0xFF; bw->data[bw->pos++] = marker; } bool JumpToByteBoundary(JpegBitWriter* bw, const uint8_t** pad_bits, const uint8_t* pad_bits_end) { size_t n_bits = bw->put_bits & 7u; uint8_t pad_pattern; if (*pad_bits == nullptr) { pad_pattern = (1u << n_bits) - 1; } else { pad_pattern = 0; const uint8_t* src = *pad_bits; // TODO(eustas): bitwise reading looks insanely ineffective... while (n_bits--) { pad_pattern <<= 1; if (src >= pad_bits_end) return false; // TODO(eustas): DCHECK *src == {0, 1} pad_pattern |= !!*(src++); } *pad_bits = src; } Reserve(bw, 16); while (bw->put_bits <= 56) { int c = (bw->put_buffer >> 56) & 0xFF; EmitByte(bw, c); bw->put_buffer <<= 8; bw->put_bits += 8; } if (bw->put_bits < 64) { int pad_mask = 0xFFu >> (64 - bw->put_bits); int c = ((bw->put_buffer >> 56) & ~pad_mask) | pad_pattern; EmitByte(bw, c); } bw->put_buffer = 0; bw->put_bits = 64; return true; } void JpegBitWriterFinish(JpegBitWriter* bw) { if (bw->pos == 0) return; bw->chunk.len = bw->pos; bw->output->emplace_back(std::move(bw->chunk)); bw->chunk = OutputChunk(nullptr, 0); bw->data = nullptr; bw->pos = 0; } void DCTCodingStateInit(DCTCodingState* s) { s->eob_run_ = 0; s->cur_ac_huff_ = nullptr; s->refinement_bits_.clear(); s->refinement_bits_.reserve(kJPEGMaxCorrectionBits); } enum OutputModes { kModeHistogram, kModeWrite, }; template static JXL_INLINE void WriteSymbol(int symbol, HuffmanCodeTable* table, JpegBitWriter* bw) { if (kOutputMode == OutputModes::kModeHistogram) { ++table->depth[symbol]; } else { WriteBits(bw, table->depth[symbol], table->code[symbol]); } } // Emit all buffered data to the bit stream using the given Huffman code and // bit writer. template static JXL_INLINE void Flush(DCTCodingState* s, JpegBitWriter* bw) { if (s->eob_run_ > 0) { int nbits = FloorLog2Nonzero(s->eob_run_); int symbol = nbits << 4u; WriteSymbol(symbol, s->cur_ac_huff_, bw); if (nbits > 0) { WriteBits(bw, nbits, s->eob_run_ & ((1 << nbits) - 1)); } s->eob_run_ = 0; } for (size_t i = 0; i < s->refinement_bits_.size(); ++i) { WriteBits(bw, 1, s->refinement_bits_[i]); } s->refinement_bits_.clear(); } // Buffer some more data at the end-of-band (the last non-zero or newly // non-zero coefficient within the [Ss, Se] spectral band). template static JXL_INLINE void BufferEndOfBand(DCTCodingState* s, HuffmanCodeTable* ac_huff, const std::vector* new_bits, JpegBitWriter* bw) { if (s->eob_run_ == 0) { s->cur_ac_huff_ = ac_huff; } ++s->eob_run_; if (new_bits) { s->refinement_bits_.insert(s->refinement_bits_.end(), new_bits->begin(), new_bits->end()); } if (s->eob_run_ == 0x7FFF || s->refinement_bits_.size() > kJPEGMaxCorrectionBits - kDCTBlockSize + 1) { Flush(s, bw); } } bool BuildHuffmanCodeTable(const JPEGHuffmanCode& huff, HuffmanCodeTable* table) { int huff_code[kJpegHuffmanAlphabetSize]; // +1 for a sentinel element. uint32_t huff_size[kJpegHuffmanAlphabetSize + 1]; int p = 0; for (size_t l = 1; l <= kJpegHuffmanMaxBitLength; ++l) { int i = huff.counts[l]; if (p + i > kJpegHuffmanAlphabetSize + 1) { return false; } while (i--) huff_size[p++] = l; } if (p == 0) { return true; } // Reuse sentinel element. int last_p = p - 1; huff_size[last_p] = 0; int code = 0; uint32_t si = huff_size[0]; p = 0; while (huff_size[p]) { while ((huff_size[p]) == si) { huff_code[p++] = code; code++; } code <<= 1; si++; } for (p = 0; p < last_p; p++) { int i = huff.values[p]; table->depth[i] = huff_size[p]; table->code[i] = huff_code[p]; } return true; } bool EncodeSOI(SerializationState* state) { state->output_queue.push_back(OutputChunk({0xFF, 0xD8})); return true; } bool EncodeEOI(const JPEGData& jpg, SerializationState* state) { state->output_queue.push_back(OutputChunk({0xFF, 0xD9})); state->output_queue.emplace_back(jpg.tail_data); return true; } bool EncodeSOF(const JPEGData& jpg, uint8_t marker, SerializationState* state) { if (marker <= 0xC2) state->is_progressive = (marker == 0xC2); const size_t n_comps = jpg.components.size(); const size_t marker_len = 8 + 3 * n_comps; state->output_queue.emplace_back(marker_len + 2); uint8_t* data = state->output_queue.back().buffer->data(); size_t pos = 0; data[pos++] = 0xFF; data[pos++] = marker; data[pos++] = marker_len >> 8u; data[pos++] = marker_len & 0xFFu; data[pos++] = kJpegPrecision; data[pos++] = jpg.height >> 8u; data[pos++] = jpg.height & 0xFFu; data[pos++] = jpg.width >> 8u; data[pos++] = jpg.width & 0xFFu; data[pos++] = n_comps; for (size_t i = 0; i < n_comps; ++i) { data[pos++] = jpg.components[i].id; data[pos++] = ((jpg.components[i].h_samp_factor << 4u) | (jpg.components[i].v_samp_factor)); const size_t quant_idx = jpg.components[i].quant_idx; if (quant_idx >= jpg.quant.size()) return false; data[pos++] = jpg.quant[quant_idx].index; } return true; } bool EncodeSOS(const JPEGData& jpg, const JPEGScanInfo& scan_info, SerializationState* state) { const size_t n_scans = scan_info.num_components; const size_t marker_len = 6 + 2 * n_scans; state->output_queue.emplace_back(marker_len + 2); uint8_t* data = state->output_queue.back().buffer->data(); size_t pos = 0; data[pos++] = 0xFF; data[pos++] = 0xDA; data[pos++] = marker_len >> 8u; data[pos++] = marker_len & 0xFFu; data[pos++] = n_scans; for (size_t i = 0; i < n_scans; ++i) { const JPEGComponentScanInfo& si = scan_info.components[i]; if (si.comp_idx >= jpg.components.size()) return false; data[pos++] = jpg.components[si.comp_idx].id; data[pos++] = (si.dc_tbl_idx << 4u) + si.ac_tbl_idx; } data[pos++] = scan_info.Ss; data[pos++] = scan_info.Se; data[pos++] = ((scan_info.Ah << 4u) | (scan_info.Al)); return true; } bool EncodeDHT(const JPEGData& jpg, SerializationState* state) { const std::vector& huffman_code = jpg.huffman_code; size_t marker_len = 2; for (size_t i = state->dht_index; i < huffman_code.size(); ++i) { const JPEGHuffmanCode& huff = huffman_code[i]; marker_len += kJpegHuffmanMaxBitLength; for (size_t j = 0; j < huff.counts.size(); ++j) { marker_len += huff.counts[j]; } if (huff.is_last) break; } state->output_queue.emplace_back(marker_len + 2); uint8_t* data = state->output_queue.back().buffer->data(); size_t pos = 0; data[pos++] = 0xFF; data[pos++] = 0xC4; data[pos++] = marker_len >> 8u; data[pos++] = marker_len & 0xFFu; while (true) { const size_t huffman_code_index = state->dht_index++; if (huffman_code_index >= huffman_code.size()) { return false; } const JPEGHuffmanCode& huff = huffman_code[huffman_code_index]; size_t index = huff.slot_id; HuffmanCodeTable* huff_table; if (index & 0x10) { index -= 0x10; huff_table = &state->ac_huff_table[index]; } else { huff_table = &state->dc_huff_table[index]; } // TODO(eustas): cache // TODO(eustas): set up non-existing symbols if (!BuildHuffmanCodeTable(huff, huff_table)) { return false; } size_t total_count = 0; size_t max_length = 0; for (size_t i = 0; i < huff.counts.size(); ++i) { if (huff.counts[i] != 0) { max_length = i; } total_count += huff.counts[i]; } --total_count; data[pos++] = huff.slot_id; for (size_t i = 1; i <= kJpegHuffmanMaxBitLength; ++i) { data[pos++] = (i == max_length ? huff.counts[i] - 1 : huff.counts[i]); } for (size_t i = 0; i < total_count; ++i) { data[pos++] = huff.values[i]; } if (huff.is_last) break; } return true; } bool EncodeDQT(const JPEGData& jpg, SerializationState* state) { int marker_len = 2; for (size_t i = state->dqt_index; i < jpg.quant.size(); ++i) { const JPEGQuantTable& table = jpg.quant[i]; marker_len += 1 + (table.precision ? 2 : 1) * kDCTBlockSize; if (table.is_last) break; } state->output_queue.emplace_back(marker_len + 2); uint8_t* data = state->output_queue.back().buffer->data(); size_t pos = 0; data[pos++] = 0xFF; data[pos++] = 0xDB; data[pos++] = marker_len >> 8u; data[pos++] = marker_len & 0xFFu; while (true) { const size_t idx = state->dqt_index++; if (idx >= jpg.quant.size()) { return false; // corrupt input } const JPEGQuantTable& table = jpg.quant[idx]; data[pos++] = (table.precision << 4u) + table.index; for (size_t i = 0; i < kDCTBlockSize; ++i) { int val_idx = kJPEGNaturalOrder[i]; int val = table.values[val_idx]; if (table.precision) { data[pos++] = val >> 8u; } data[pos++] = val & 0xFFu; } if (table.is_last) break; } return true; } bool EncodeDRI(const JPEGData& jpg, SerializationState* state) { state->seen_dri_marker = true; OutputChunk dri_marker = {0xFF, 0xDD, 0, 4, static_cast(jpg.restart_interval >> 8), static_cast(jpg.restart_interval & 0xFF)}; state->output_queue.push_back(std::move(dri_marker)); return true; } bool EncodeRestart(uint8_t marker, SerializationState* state) { state->output_queue.push_back(OutputChunk({0xFF, marker})); return true; } bool EncodeAPP(const JPEGData& jpg, uint8_t marker, SerializationState* state) { // TODO(eustas): check that marker corresponds to payload? (void)marker; size_t app_index = state->app_index++; if (app_index >= jpg.app_data.size()) return false; state->output_queue.push_back(OutputChunk({0xFF})); state->output_queue.emplace_back(jpg.app_data[app_index]); return true; } bool EncodeCOM(const JPEGData& jpg, SerializationState* state) { size_t com_index = state->com_index++; if (com_index >= jpg.com_data.size()) return false; state->output_queue.push_back(OutputChunk({0xFF})); state->output_queue.emplace_back(jpg.com_data[com_index]); return true; } bool EncodeInterMarkerData(const JPEGData& jpg, SerializationState* state) { size_t index = state->data_index++; if (index >= jpg.inter_marker_data.size()) return false; state->output_queue.emplace_back(jpg.inter_marker_data[index]); return true; } template bool EncodeDCTBlockSequential(const coeff_t* coeffs, HuffmanCodeTable* dc_huff, HuffmanCodeTable* ac_huff, int num_zero_runs, coeff_t* last_dc_coeff, JpegBitWriter* bw) { coeff_t temp2; coeff_t temp; temp2 = coeffs[0]; temp = temp2 - *last_dc_coeff; *last_dc_coeff = temp2; temp2 = temp; if (temp < 0) { temp = -temp; if (temp < 0) return false; temp2--; } int dc_nbits = (temp == 0) ? 0 : (FloorLog2Nonzero(temp) + 1); WriteSymbol(dc_nbits, dc_huff, bw); if (dc_nbits >= 12) return false; if (dc_nbits > 0) { WriteBits(bw, dc_nbits, temp2 & ((1u << dc_nbits) - 1)); } int r = 0; for (int k = 1; k < 64; ++k) { if ((temp = coeffs[kJPEGNaturalOrder[k]]) == 0) { r++; continue; } if (temp < 0) { temp = -temp; if (temp < 0) return false; temp2 = ~temp; } else { temp2 = temp; } while (r > 15) { WriteSymbol(0xf0, ac_huff, bw); r -= 16; } int ac_nbits = FloorLog2Nonzero(temp) + 1; if (ac_nbits >= 16) return false; int symbol = (r << 4u) + ac_nbits; WriteSymbol(symbol, ac_huff, bw); WriteBits(bw, ac_nbits, temp2 & ((1 << ac_nbits) - 1)); r = 0; } for (int i = 0; i < num_zero_runs; ++i) { WriteSymbol(0xf0, ac_huff, bw); r -= 16; } if (r > 0) { WriteSymbol(0, ac_huff, bw); } return true; } template bool EncodeDCTBlockProgressive(const coeff_t* coeffs, HuffmanCodeTable* dc_huff, HuffmanCodeTable* ac_huff, int Ss, int Se, int Al, int num_zero_runs, DCTCodingState* coding_state, coeff_t* last_dc_coeff, JpegBitWriter* bw) { bool eob_run_allowed = Ss > 0; coeff_t temp2; coeff_t temp; if (Ss == 0) { temp2 = coeffs[0] >> Al; temp = temp2 - *last_dc_coeff; *last_dc_coeff = temp2; temp2 = temp; if (temp < 0) { temp = -temp; if (temp < 0) return false; temp2--; } int nbits = (temp == 0) ? 0 : (FloorLog2Nonzero(temp) + 1); WriteSymbol(nbits, dc_huff, bw); if (nbits > 0) { WriteBits(bw, nbits, temp2 & ((1 << nbits) - 1)); } ++Ss; } if (Ss > Se) { return true; } int r = 0; for (int k = Ss; k <= Se; ++k) { if ((temp = coeffs[kJPEGNaturalOrder[k]]) == 0) { r++; continue; } if (temp < 0) { temp = -temp; if (temp < 0) return false; temp >>= Al; temp2 = ~temp; } else { temp >>= Al; temp2 = temp; } if (temp == 0) { r++; continue; } Flush(coding_state, bw); while (r > 15) { WriteSymbol(0xf0, ac_huff, bw); r -= 16; } int nbits = FloorLog2Nonzero(temp) + 1; int symbol = (r << 4u) + nbits; WriteSymbol(symbol, ac_huff, bw); WriteBits(bw, nbits, temp2 & ((1 << nbits) - 1)); r = 0; } if (num_zero_runs > 0) { Flush(coding_state, bw); for (int i = 0; i < num_zero_runs; ++i) { WriteSymbol(0xf0, ac_huff, bw); r -= 16; } } if (r > 0) { BufferEndOfBand(coding_state, ac_huff, nullptr, bw); if (!eob_run_allowed) { Flush(coding_state, bw); } } return true; } template bool EncodeRefinementBits(const coeff_t* coeffs, HuffmanCodeTable* ac_huff, int Ss, int Se, int Al, DCTCodingState* coding_state, JpegBitWriter* bw) { bool eob_run_allowed = Ss > 0; if (Ss == 0) { // Emit next bit of DC component. WriteBits(bw, 1, (coeffs[0] >> Al) & 1); ++Ss; } if (Ss > Se) { return true; } int abs_values[kDCTBlockSize]; int eob = 0; for (int k = Ss; k <= Se; k++) { const coeff_t abs_val = std::abs(coeffs[kJPEGNaturalOrder[k]]); abs_values[k] = abs_val >> Al; if (abs_values[k] == 1) { eob = k; } } int r = 0; std::vector refinement_bits; refinement_bits.reserve(kDCTBlockSize); for (int k = Ss; k <= Se; k++) { if (abs_values[k] == 0) { r++; continue; } while (r > 15 && k <= eob) { Flush(coding_state, bw); WriteSymbol(0xf0, ac_huff, bw); r -= 16; for (int bit : refinement_bits) { WriteBits(bw, 1, bit); } refinement_bits.clear(); } if (abs_values[k] > 1) { refinement_bits.push_back(abs_values[k] & 1u); continue; } Flush(coding_state, bw); int symbol = (r << 4u) + 1; int new_non_zero_bit = (coeffs[kJPEGNaturalOrder[k]] < 0) ? 0 : 1; WriteSymbol(symbol, ac_huff, bw); WriteBits(bw, 1, new_non_zero_bit); for (int bit : refinement_bits) { WriteBits(bw, 1, bit); } refinement_bits.clear(); r = 0; } if (r > 0 || !refinement_bits.empty()) { BufferEndOfBand(coding_state, ac_huff, &refinement_bits, bw); if (!eob_run_allowed) { Flush(coding_state, bw); } } return true; } size_t NumHistograms(const JPEGData& jpg) { size_t num = 0; for (const auto& si : jpg.scan_info) { num += si.num_components; } return num; } size_t HistogramIndex(const JPEGData& jpg, size_t scan_index, size_t component_index) { size_t idx = 0; for (size_t i = 0; i < scan_index; ++i) { idx += jpg.scan_info[i].num_components; } return idx + component_index; } template SerializationStatus JXL_NOINLINE DoEncodeScan(const JPEGData& jpg, SerializationState* state) { const JPEGScanInfo& scan_info = jpg.scan_info[state->scan_index]; EncodeScanState& ss = state->scan_state; const int restart_interval = state->seen_dri_marker ? jpg.restart_interval : 0; const auto get_next_extra_zero_run_index = [&ss, &scan_info]() -> int { if (ss.extra_zero_runs_pos < scan_info.extra_zero_runs.size()) { return scan_info.extra_zero_runs[ss.extra_zero_runs_pos].block_idx; } else { return -1; } }; const auto get_next_reset_point = [&ss, &scan_info]() -> int { if (ss.next_reset_point_pos < scan_info.reset_points.size()) { return scan_info.reset_points[ss.next_reset_point_pos++]; } else { return -1; } }; if (ss.stage == EncodeScanState::HEAD) { if (!EncodeSOS(jpg, scan_info, state)) return SerializationStatus::ERROR; JpegBitWriterInit(&ss.bw, &state->output_queue); DCTCodingStateInit(&ss.coding_state); ss.restarts_to_go = restart_interval; ss.next_restart_marker = 0; ss.block_scan_index = 0; ss.extra_zero_runs_pos = 0; ss.next_extra_zero_run_index = get_next_extra_zero_run_index(); ss.next_reset_point_pos = 0; ss.next_reset_point = get_next_reset_point(); ss.mcu_y = 0; memset(ss.last_dc_coeff, 0, sizeof(ss.last_dc_coeff)); ss.stage = EncodeScanState::BODY; } JpegBitWriter* bw = &ss.bw; DCTCodingState* coding_state = &ss.coding_state; JXL_DASSERT(ss.stage == EncodeScanState::BODY); // "Non-interleaved" means color data comes in separate scans, in other words // each scan can contain only one color component. const bool is_interleaved = (scan_info.num_components > 1); int MCUs_per_row = 0; int MCU_rows = 0; jpg.CalculateMcuSize(scan_info, &MCUs_per_row, &MCU_rows); const bool is_progressive = state->is_progressive; const int Al = is_progressive ? scan_info.Al : 0; const int Ss = is_progressive ? scan_info.Ss : 0; const int Se = is_progressive ? scan_info.Se : 63; // DC-only is defined by [0..0] spectral range. const bool want_ac = ((Ss != 0) || (Se != 0)); // TODO: support streaming decoding again. const bool complete_ac = true; const bool has_ac = true; if (want_ac && !has_ac) return SerializationStatus::NEEDS_MORE_INPUT; // |has_ac| implies |complete_dc| but not vice versa; for the sake of // simplicity we pretend they are equal, because they are separated by just a // few bytes of input. const bool complete_dc = has_ac; const bool complete = want_ac ? complete_ac : complete_dc; // When "incomplete" |ac_dc| tracks information about current ("incomplete") // band parsing progress. // FIXME: Is this always complete? // const int last_mcu_y = // complete ? MCU_rows : parsing_state.internal->ac_dc.next_mcu_y * // v_group; (void)complete; const int last_mcu_y = complete ? MCU_rows : 0; for (; ss.mcu_y < last_mcu_y; ++ss.mcu_y) { for (int mcu_x = 0; mcu_x < MCUs_per_row; ++mcu_x) { // Possibly emit a restart marker. if (restart_interval > 0 && ss.restarts_to_go == 0) { Flush(coding_state, bw); if (!JumpToByteBoundary(bw, &state->pad_bits, state->pad_bits_end)) { return SerializationStatus::ERROR; } EmitMarker(bw, 0xD0 + ss.next_restart_marker); ss.next_restart_marker += 1; ss.next_restart_marker &= 0x7; ss.restarts_to_go = restart_interval; memset(ss.last_dc_coeff, 0, sizeof(ss.last_dc_coeff)); } // Encode one MCU for (size_t i = 0; i < scan_info.num_components; ++i) { const JPEGComponentScanInfo& si = scan_info.components[i]; const JPEGComponent& c = jpg.components[si.comp_idx]; size_t dc_tbl_idx = (kOutputMode == OutputModes::kModeHistogram ? HistogramIndex(jpg, state->scan_index, i) : si.dc_tbl_idx); size_t ac_tbl_idx = (kOutputMode == OutputModes::kModeHistogram ? HistogramIndex(jpg, state->scan_index, i) : si.ac_tbl_idx); HuffmanCodeTable* dc_huff = &state->dc_huff_table[dc_tbl_idx]; HuffmanCodeTable* ac_huff = &state->ac_huff_table[ac_tbl_idx]; int n_blocks_y = is_interleaved ? c.v_samp_factor : 1; int n_blocks_x = is_interleaved ? c.h_samp_factor : 1; for (int iy = 0; iy < n_blocks_y; ++iy) { for (int ix = 0; ix < n_blocks_x; ++ix) { int block_y = ss.mcu_y * n_blocks_y + iy; int block_x = mcu_x * n_blocks_x + ix; int block_idx = block_y * c.width_in_blocks + block_x; if (ss.block_scan_index == ss.next_reset_point) { Flush(coding_state, bw); ss.next_reset_point = get_next_reset_point(); } int num_zero_runs = 0; if (ss.block_scan_index == ss.next_extra_zero_run_index) { num_zero_runs = scan_info.extra_zero_runs[ss.extra_zero_runs_pos] .num_extra_zero_runs; ++ss.extra_zero_runs_pos; ss.next_extra_zero_run_index = get_next_extra_zero_run_index(); } const coeff_t* coeffs = &c.coeffs[block_idx << 6]; bool ok; if (kMode == 0) { ok = EncodeDCTBlockSequential( coeffs, dc_huff, ac_huff, num_zero_runs, ss.last_dc_coeff + si.comp_idx, bw); } else if (kMode == 1) { ok = EncodeDCTBlockProgressive( coeffs, dc_huff, ac_huff, Ss, Se, Al, num_zero_runs, coding_state, ss.last_dc_coeff + si.comp_idx, bw); } else { ok = EncodeRefinementBits(coeffs, ac_huff, Ss, Se, Al, coding_state, bw); } if (!ok) return SerializationStatus::ERROR; ++ss.block_scan_index; } } } --ss.restarts_to_go; } } if (ss.mcu_y < MCU_rows) { if (!bw->healthy) return SerializationStatus::ERROR; return SerializationStatus::NEEDS_MORE_INPUT; } Flush(coding_state, bw); if (!JumpToByteBoundary(bw, &state->pad_bits, state->pad_bits_end)) { return SerializationStatus::ERROR; } JpegBitWriterFinish(bw); ss.stage = EncodeScanState::HEAD; state->scan_index++; if (!bw->healthy) return SerializationStatus::ERROR; return SerializationStatus::DONE; } template static SerializationStatus JXL_INLINE EncodeScan(const JPEGData& jpg, SerializationState* state) { const JPEGScanInfo& scan_info = jpg.scan_info[state->scan_index]; const bool is_progressive = state->is_progressive; const int Al = is_progressive ? scan_info.Al : 0; const int Ah = is_progressive ? scan_info.Ah : 0; const int Ss = is_progressive ? scan_info.Ss : 0; const int Se = is_progressive ? scan_info.Se : 63; const bool need_sequential = !is_progressive || (Ah == 0 && Al == 0 && Ss == 0 && Se == 63); if (need_sequential) { return DoEncodeScan<0, kOutputMode>(jpg, state); } else if (Ah == 0) { return DoEncodeScan<1, kOutputMode>(jpg, state); } else { return DoEncodeScan<2, kOutputMode>(jpg, state); } } template SerializationStatus SerializeSection(uint8_t marker, SerializationState* state, const JPEGData& jpg) { const auto to_status = [](bool result) { return result ? SerializationStatus::DONE : SerializationStatus::ERROR; }; // TODO(eustas): add and use marker enum switch (marker) { case 0xC0: case 0xC1: case 0xC2: case 0xC9: case 0xCA: return to_status(EncodeSOF(jpg, marker, state)); case 0xC4: return to_status((kOutputMode == OutputModes::kModeHistogram) || EncodeDHT(jpg, state)); case 0xD0: case 0xD1: case 0xD2: case 0xD3: case 0xD4: case 0xD5: case 0xD6: case 0xD7: return to_status(EncodeRestart(marker, state)); case 0xD9: return to_status(EncodeEOI(jpg, state)); case 0xDA: return EncodeScan(jpg, state); case 0xDB: return to_status(EncodeDQT(jpg, state)); case 0xDD: return to_status(EncodeDRI(jpg, state)); case 0xE0: case 0xE1: case 0xE2: case 0xE3: case 0xE4: case 0xE5: case 0xE6: case 0xE7: case 0xE8: case 0xE9: case 0xEA: case 0xEB: case 0xEC: case 0xED: case 0xEE: case 0xEF: return to_status(EncodeAPP(jpg, marker, state)); case 0xFE: return to_status(EncodeCOM(jpg, state)); case 0xFF: return to_status(EncodeInterMarkerData(jpg, state)); default: return SerializationStatus::ERROR; } } // TODO(veluca): add streaming support again. template Status WriteJpegInternal(const JPEGData& jpg, const JPEGOutput& out, SerializationState* ss) { const auto maybe_push_output = [&]() -> Status { if (ss->stage != SerializationState::STAGE_ERROR) { while (!ss->output_queue.empty()) { auto& chunk = ss->output_queue.front(); size_t num_written = out(chunk.next, chunk.len); if (num_written == 0 && chunk.len > 0) { return StatusMessage(Status(StatusCode::kNotEnoughBytes), "Failed to write output"); } chunk.len -= num_written; if (chunk.len == 0) { ss->output_queue.pop_front(); } } } return true; }; while (true) { switch (ss->stage) { case SerializationState::STAGE_INIT: { // Valid Brunsli requires, at least, 0xD9 marker. // This might happen on corrupted stream, or on unconditioned JPEGData. // TODO(eustas): check D9 in the only one and is the last one. if (jpg.marker_order.empty()) { ss->stage = SerializationState::STAGE_ERROR; break; } if (kOutputMode == OutputModes::kModeHistogram) { size_t num_histo = NumHistograms(jpg); ss->dc_huff_table.resize(num_histo); ss->ac_huff_table.resize(num_histo); for (size_t i = 0; i < num_histo; ++i) { ss->dc_huff_table[i].InitDepths(); ss->ac_huff_table[i].InitDepths(); } } else { ss->dc_huff_table.resize(kMaxHuffmanTables); ss->ac_huff_table.resize(kMaxHuffmanTables); } if (jpg.has_zero_padding_bit) { ss->pad_bits = jpg.padding_bits.data(); ss->pad_bits_end = ss->pad_bits + jpg.padding_bits.size(); } EncodeSOI(ss); JXL_QUIET_RETURN_IF_ERROR(maybe_push_output()); ss->stage = SerializationState::STAGE_SERIALIZE_SECTION; break; } case SerializationState::STAGE_SERIALIZE_SECTION: { if (ss->section_index >= jpg.marker_order.size()) { ss->stage = SerializationState::STAGE_DONE; break; } uint8_t marker = jpg.marker_order[ss->section_index]; SerializationStatus status = SerializeSection(marker, ss, jpg); if (status == SerializationStatus::ERROR) { JXL_WARNING("Failed to encode marker 0x%.2x", marker); ss->stage = SerializationState::STAGE_ERROR; break; } JXL_QUIET_RETURN_IF_ERROR(maybe_push_output()); if (status == SerializationStatus::NEEDS_MORE_INPUT) { return JXL_FAILURE("Incomplete serialization data"); } else if (status != SerializationStatus::DONE) { JXL_DASSERT(false); ss->stage = SerializationState::STAGE_ERROR; break; } ++ss->section_index; break; } case SerializationState::STAGE_DONE: JXL_ASSERT(ss->output_queue.empty()); if (ss->pad_bits != nullptr && ss->pad_bits != ss->pad_bits_end) { return JXL_FAILURE("Invalid number of padding bits."); } return true; case SerializationState::STAGE_ERROR: return JXL_FAILURE("JPEG serialization error"); } } } } // namespace Status WriteJpeg(const JPEGData& jpg, const JPEGOutput& out) { SerializationState ss; return WriteJpegInternal(jpg, out, &ss); } Status ProcessJpeg(const JPEGData& jpg, SerializationState* ss) { auto nullout = [](const uint8_t* buf, size_t len) { return len; }; return WriteJpegInternal(jpg, nullout, ss); } } // namespace jpeg } // namespace jxl