// 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/jpeg_data.h" #include #include "lib/jxl/base/printf_macros.h" #include "lib/jxl/base/status.h" #include "lib/jxl/common.h" // kMaxNumPasses, JPEGXL_ENABLE_TRANSCODE_JPEG namespace jxl { namespace jpeg { #if JPEGXL_ENABLE_TRANSCODE_JPEG namespace { enum JPEGComponentType : uint32_t { kGray = 0, kYCbCr = 1, kRGB = 2, kCustom = 3, }; struct JPEGInfo { size_t num_app_markers = 0; size_t num_com_markers = 0; size_t num_scans = 0; size_t num_intermarker = 0; bool has_dri = false; }; Status VisitMarker(uint8_t* marker, Visitor* visitor, JPEGInfo* info) { uint32_t marker32 = *marker - 0xc0; JXL_RETURN_IF_ERROR(visitor->Bits(6, 0x00, &marker32)); *marker = marker32 + 0xc0; if ((*marker & 0xf0) == 0xe0) { info->num_app_markers++; } if (*marker == 0xfe) { info->num_com_markers++; } if (*marker == 0xda) { info->num_scans++; } // We use a fake 0xff marker to signal intermarker data. if (*marker == 0xff) { info->num_intermarker++; } if (*marker == 0xdd) { info->has_dri = true; } return true; } } // namespace Status JPEGData::VisitFields(Visitor* visitor) { bool is_gray = components.size() == 1; JXL_RETURN_IF_ERROR(visitor->Bool(false, &is_gray)); if (visitor->IsReading()) { components.resize(is_gray ? 1 : 3); } JPEGInfo info; if (visitor->IsReading()) { uint8_t marker = 0xc0; do { JXL_RETURN_IF_ERROR(VisitMarker(&marker, visitor, &info)); marker_order.push_back(marker); if (marker_order.size() > 16384) { return JXL_FAILURE("Too many markers: %" PRIuS "\n", marker_order.size()); } } while (marker != 0xd9); } else { if (marker_order.size() > 16384) { return JXL_FAILURE("Too many markers: %" PRIuS "\n", marker_order.size()); } for (uint8_t& marker : marker_order) { JXL_RETURN_IF_ERROR(VisitMarker(&marker, visitor, &info)); } if (!marker_order.empty()) { // Last marker should always be EOI marker. JXL_ENSURE(marker_order.back() == 0xd9); } } // Size of the APP and COM markers. if (visitor->IsReading()) { app_data.resize(info.num_app_markers); app_marker_type.resize(info.num_app_markers); com_data.resize(info.num_com_markers); scan_info.resize(info.num_scans); } JXL_ENSURE(app_data.size() == info.num_app_markers); JXL_ENSURE(app_marker_type.size() == info.num_app_markers); JXL_ENSURE(com_data.size() == info.num_com_markers); JXL_ENSURE(scan_info.size() == info.num_scans); for (size_t i = 0; i < app_data.size(); i++) { auto& app = app_data[i]; // Encodes up to 8 different values. JXL_RETURN_IF_ERROR( visitor->U32(Val(0), Val(1), BitsOffset(1, 2), BitsOffset(2, 4), 0, reinterpret_cast(&app_marker_type[i]))); if (app_marker_type[i] != AppMarkerType::kUnknown && app_marker_type[i] != AppMarkerType::kICC && app_marker_type[i] != AppMarkerType::kExif && app_marker_type[i] != AppMarkerType::kXMP) { return JXL_FAILURE("Unknown app marker type %u", static_cast(app_marker_type[i])); } uint32_t len = app.size() - 1; JXL_RETURN_IF_ERROR(visitor->Bits(16, 0, &len)); if (visitor->IsReading()) app.resize(len + 1); if (app.size() < 3) { return JXL_FAILURE("Invalid marker size: %" PRIuS "\n", app.size()); } } for (auto& com : com_data) { uint32_t len = com.size() - 1; JXL_RETURN_IF_ERROR(visitor->Bits(16, 0, &len)); if (visitor->IsReading()) com.resize(len + 1); if (com.size() < 3) { return JXL_FAILURE("Invalid marker size: %" PRIuS "\n", com.size()); } } uint32_t num_quant_tables = quant.size(); JXL_RETURN_IF_ERROR( visitor->U32(Val(1), Val(2), Val(3), Val(4), 2, &num_quant_tables)); if (num_quant_tables == 4) { return JXL_FAILURE("Invalid number of quant tables"); } if (visitor->IsReading()) { quant.resize(num_quant_tables); } for (size_t i = 0; i < num_quant_tables; i++) { if (quant[i].precision > 1) { return JXL_FAILURE( "Quant tables with more than 16 bits are not supported"); } JXL_RETURN_IF_ERROR(visitor->Bits(1, 0, &quant[i].precision)); JXL_RETURN_IF_ERROR(visitor->Bits(2, i, &quant[i].index)); JXL_RETURN_IF_ERROR(visitor->Bool(true, &quant[i].is_last)); } JPEGComponentType component_type = components.size() == 1 && components[0].id == 1 ? JPEGComponentType::kGray : components.size() == 3 && components[0].id == 1 && components[1].id == 2 && components[2].id == 3 ? JPEGComponentType::kYCbCr : components.size() == 3 && components[0].id == 'R' && components[1].id == 'G' && components[2].id == 'B' ? JPEGComponentType::kRGB : JPEGComponentType::kCustom; JXL_RETURN_IF_ERROR( visitor->Bits(2, JPEGComponentType::kYCbCr, reinterpret_cast(&component_type))); uint32_t num_components; if (component_type == JPEGComponentType::kGray) { num_components = 1; } else if (component_type != JPEGComponentType::kCustom) { num_components = 3; } else { num_components = components.size(); JXL_RETURN_IF_ERROR( visitor->U32(Val(1), Val(2), Val(3), Val(4), 3, &num_components)); if (num_components != 1 && num_components != 3) { return JXL_FAILURE("Invalid number of components: %u", num_components); } } if (visitor->IsReading()) { components.resize(num_components); } if (component_type == JPEGComponentType::kCustom) { for (auto& component : components) { JXL_RETURN_IF_ERROR(visitor->Bits(8, 0, &component.id)); } } else if (component_type == JPEGComponentType::kGray) { components[0].id = 1; } else if (component_type == JPEGComponentType::kRGB) { components[0].id = 'R'; components[1].id = 'G'; components[2].id = 'B'; } else { components[0].id = 1; components[1].id = 2; components[2].id = 3; } size_t used_tables = 0; for (size_t i = 0; i < components.size(); i++) { JXL_RETURN_IF_ERROR(visitor->Bits(2, 0, &components[i].quant_idx)); if (components[i].quant_idx >= quant.size()) { return JXL_FAILURE("Invalid quant table for component %" PRIuS ": %u\n", i, components[i].quant_idx); } used_tables |= 1U << components[i].quant_idx; } for (size_t i = 0; i < quant.size(); i++) { if (used_tables & (1 << i)) continue; if (i == 0) return JXL_FAILURE("First quant table unused."); // Unused quant table has to be set to copy of previous quant table for (size_t j = 0; j < 64; j++) { if (quant[i].values[j] != quant[i - 1].values[j]) { return JXL_FAILURE("Non-trivial unused quant table"); } } } uint32_t num_huff = huffman_code.size(); JXL_RETURN_IF_ERROR(visitor->U32(Val(4), BitsOffset(3, 2), BitsOffset(4, 10), BitsOffset(6, 26), 4, &num_huff)); if (visitor->IsReading()) { huffman_code.resize(num_huff); } for (JPEGHuffmanCode& hc : huffman_code) { bool is_ac = ((hc.slot_id >> 4) != 0); uint32_t id = hc.slot_id & 0xF; JXL_RETURN_IF_ERROR(visitor->Bool(false, &is_ac)); JXL_RETURN_IF_ERROR(visitor->Bits(2, 0, &id)); hc.slot_id = (static_cast(is_ac) << 4) | id; JXL_RETURN_IF_ERROR(visitor->Bool(true, &hc.is_last)); size_t num_symbols = 0; for (size_t i = 0; i <= 16; i++) { JXL_RETURN_IF_ERROR(visitor->U32(Val(0), Val(1), BitsOffset(3, 2), Bits(8), 0, &hc.counts[i])); num_symbols += hc.counts[i]; } if (num_symbols < 1) { // Actually, at least 2 symbols are required, since one of them is EOI. return JXL_FAILURE("Empty Huffman table"); } if (num_symbols > hc.values.size()) { return JXL_FAILURE("Huffman code too large (%" PRIuS ")", num_symbols); } // Presence flags for 4 * 64 + 1 values. uint64_t value_slots[5] = {}; for (size_t i = 0; i < num_symbols; i++) { // Goes up to 256, included. Might have the same symbol appear twice... JXL_RETURN_IF_ERROR(visitor->U32(Bits(2), BitsOffset(2, 4), BitsOffset(4, 8), BitsOffset(8, 1), 0, &hc.values[i])); value_slots[hc.values[i] >> 6] |= static_cast(1) << (hc.values[i] & 0x3F); } if (hc.values[num_symbols - 1] != kJpegHuffmanAlphabetSize) { return JXL_FAILURE("Missing EOI symbol"); } // Last element, denoting EOI, have to be 1 after the loop. JXL_ENSURE(value_slots[4] == 1); size_t num_values = 1; for (size_t i = 0; i < 4; ++i) num_values += hwy::PopCount(value_slots[i]); if (num_values != num_symbols) { return JXL_FAILURE("Duplicate Huffman symbols"); } if (!is_ac) { bool only_dc = ((value_slots[0] >> kJpegDCAlphabetSize) | value_slots[1] | value_slots[2] | value_slots[3]) == 0; if (!only_dc) return JXL_FAILURE("Huffman symbols out of DC range"); } } for (auto& scan : scan_info) { JXL_RETURN_IF_ERROR( visitor->U32(Val(1), Val(2), Val(3), Val(4), 1, &scan.num_components)); if (scan.num_components >= 4) { return JXL_FAILURE("Invalid number of components in SOS marker"); } JXL_RETURN_IF_ERROR(visitor->Bits(6, 0, &scan.Ss)); JXL_RETURN_IF_ERROR(visitor->Bits(6, 63, &scan.Se)); JXL_RETURN_IF_ERROR(visitor->Bits(4, 0, &scan.Al)); JXL_RETURN_IF_ERROR(visitor->Bits(4, 0, &scan.Ah)); for (size_t i = 0; i < scan.num_components; i++) { JXL_RETURN_IF_ERROR(visitor->Bits(2, 0, &scan.components[i].comp_idx)); if (scan.components[i].comp_idx >= components.size()) { return JXL_FAILURE("Invalid component idx in SOS marker"); } JXL_RETURN_IF_ERROR(visitor->Bits(2, 0, &scan.components[i].ac_tbl_idx)); JXL_RETURN_IF_ERROR(visitor->Bits(2, 0, &scan.components[i].dc_tbl_idx)); } // TODO(veluca): actually set and use this value. JXL_RETURN_IF_ERROR(visitor->U32(Val(0), Val(1), Val(2), BitsOffset(3, 3), kMaxNumPasses - 1, &scan.last_needed_pass)); } // From here on, this is data that is not strictly necessary to get a valid // JPEG, but necessary for bit-exact JPEG reconstruction. if (info.has_dri) { JXL_RETURN_IF_ERROR(visitor->Bits(16, 0, &restart_interval)); } for (auto& scan : scan_info) { uint32_t num_reset_points = scan.reset_points.size(); JXL_RETURN_IF_ERROR(visitor->U32(Val(0), BitsOffset(2, 1), BitsOffset(4, 4), BitsOffset(16, 20), 0, &num_reset_points)); if (visitor->IsReading()) { scan.reset_points.resize(num_reset_points); } int last_block_idx = -1; for (auto& block_idx : scan.reset_points) { block_idx -= last_block_idx + 1; JXL_RETURN_IF_ERROR(visitor->U32(Val(0), BitsOffset(3, 1), BitsOffset(5, 9), BitsOffset(28, 41), 0, &block_idx)); block_idx += last_block_idx + 1; if (block_idx >= (3u << 26)) { // At most 8K x 8K x num_channels blocks are possible in a JPEG. // So valid block indices are below 3 * 2^26. return JXL_FAILURE("Invalid block ID: %u", block_idx); } last_block_idx = block_idx; } uint32_t num_extra_zero_runs = scan.extra_zero_runs.size(); JXL_RETURN_IF_ERROR(visitor->U32(Val(0), BitsOffset(2, 1), BitsOffset(4, 4), BitsOffset(16, 20), 0, &num_extra_zero_runs)); if (visitor->IsReading()) { scan.extra_zero_runs.resize(num_extra_zero_runs); } last_block_idx = -1; for (auto& extra_zero_run : scan.extra_zero_runs) { uint32_t& block_idx = extra_zero_run.block_idx; JXL_RETURN_IF_ERROR(visitor->U32(Val(1), BitsOffset(2, 2), BitsOffset(4, 5), BitsOffset(8, 20), 1, &extra_zero_run.num_extra_zero_runs)); block_idx -= last_block_idx + 1; JXL_RETURN_IF_ERROR(visitor->U32(Val(0), BitsOffset(3, 1), BitsOffset(5, 9), BitsOffset(28, 41), 0, &block_idx)); block_idx += last_block_idx + 1; if (block_idx > (3u << 26)) { return JXL_FAILURE("Invalid block ID: %u", block_idx); } last_block_idx = block_idx; } } std::vector inter_marker_data_sizes; inter_marker_data_sizes.reserve(info.num_intermarker); for (size_t i = 0; i < info.num_intermarker; ++i) { uint32_t len = visitor->IsReading() ? 0 : inter_marker_data[i].size(); JXL_RETURN_IF_ERROR(visitor->Bits(16, 0, &len)); if (visitor->IsReading()) inter_marker_data_sizes.emplace_back(len); } uint32_t tail_data_len = tail_data.size(); if (!visitor->IsReading() && tail_data_len > 4260096) { return JXL_FAILURE("Tail data too large (max size = 4260096, size = %u)", tail_data_len); } JXL_RETURN_IF_ERROR(visitor->U32(Val(0), BitsOffset(8, 1), BitsOffset(16, 257), BitsOffset(22, 65793), 0, &tail_data_len)); JXL_RETURN_IF_ERROR(visitor->Bool(false, &has_zero_padding_bit)); if (has_zero_padding_bit) { uint32_t nbit = padding_bits.size(); JXL_RETURN_IF_ERROR(visitor->Bits(24, 0, &nbit)); if (visitor->IsReading()) { JXL_RETURN_IF_ERROR(CheckHasEnoughBits(visitor, nbit)); padding_bits.reserve(std::min(1024u, nbit)); for (uint32_t i = 0; i < nbit; i++) { bool bbit = false; JXL_RETURN_IF_ERROR(visitor->Bool(false, &bbit)); padding_bits.push_back(TO_JXL_BOOL(bbit)); } } else { for (uint8_t& bit : padding_bits) { bool bbit = FROM_JXL_BOOL(bit); JXL_RETURN_IF_ERROR(visitor->Bool(false, &bbit)); bit = TO_JXL_BOOL(bbit); } } } { size_t dht_index = 0; size_t scan_index = 0; bool is_progressive = false; bool ac_ok[kMaxHuffmanTables] = {false}; bool dc_ok[kMaxHuffmanTables] = {false}; for (uint8_t marker : marker_order) { if (marker == 0xC2) { is_progressive = true; } else if (marker == 0xC4) { for (; dht_index < huffman_code.size();) { const JPEGHuffmanCode& huff = huffman_code[dht_index++]; size_t index = huff.slot_id; if (index & 0x10) { index -= 0x10; ac_ok[index] = true; } else { dc_ok[index] = true; } if (huff.is_last) break; } } else if (marker == 0xDA) { const JPEGScanInfo& si = scan_info[scan_index++]; for (size_t i = 0; i < si.num_components; ++i) { const JPEGComponentScanInfo& csi = si.components[i]; size_t dc_tbl_idx = csi.dc_tbl_idx; size_t ac_tbl_idx = csi.ac_tbl_idx; bool want_dc = !is_progressive || (si.Ss == 0); if (want_dc && !dc_ok[dc_tbl_idx]) { return JXL_FAILURE("DC Huffman table used before defined"); } bool want_ac = !is_progressive || (si.Ss != 0) || (si.Se != 0); if (want_ac && !ac_ok[ac_tbl_idx]) { return JXL_FAILURE("AC Huffman table used before defined"); } } } } } // Apply postponed actions. if (visitor->IsReading()) { tail_data.resize(tail_data_len); JXL_ENSURE(inter_marker_data_sizes.size() == info.num_intermarker); inter_marker_data.reserve(info.num_intermarker); for (size_t i = 0; i < info.num_intermarker; ++i) { inter_marker_data.emplace_back(inter_marker_data_sizes[i]); } } return true; } #endif // JPEGXL_ENABLE_TRANSCODE_JPEG void JPEGData::CalculateMcuSize(const JPEGScanInfo& scan, int* MCUs_per_row, int* MCU_rows) const { const bool is_interleaved = (scan.num_components > 1); const JPEGComponent& base_component = components[scan.components[0].comp_idx]; // h_group / v_group act as numerators for converting number of blocks to // number of MCU. In interleaved mode it is 1, so MCU is represented with // max_*_samp_factor blocks. In non-interleaved mode we choose numerator to // be the samping factor, consequently MCU is always represented with single // block. const int h_group = is_interleaved ? 1 : base_component.h_samp_factor; const int v_group = is_interleaved ? 1 : base_component.v_samp_factor; int max_h_samp_factor = 1; int max_v_samp_factor = 1; for (const auto& c : components) { max_h_samp_factor = std::max(c.h_samp_factor, max_h_samp_factor); max_v_samp_factor = std::max(c.v_samp_factor, max_v_samp_factor); } *MCUs_per_row = DivCeil(width * h_group, 8 * max_h_samp_factor); *MCU_rows = DivCeil(height * v_group, 8 * max_v_samp_factor); } #if JPEGXL_ENABLE_TRANSCODE_JPEG Status SetJPEGDataFromICC(const std::vector& icc, jpeg::JPEGData* jpeg_data) { size_t icc_pos = 0; for (size_t i = 0; i < jpeg_data->app_data.size(); i++) { if (jpeg_data->app_marker_type[i] != jpeg::AppMarkerType::kICC) { continue; } size_t len = jpeg_data->app_data[i].size() - 17; if (icc_pos + len > icc.size()) { return JXL_FAILURE( "ICC length is less than APP markers: requested %" PRIuS " more bytes, " "%" PRIuS " available", len, icc.size() - icc_pos); } memcpy(&jpeg_data->app_data[i][17], icc.data() + icc_pos, len); icc_pos += len; } if (icc_pos != icc.size() && icc_pos != 0) { return JXL_FAILURE("ICC length is more than APP markers"); } return true; } #endif // JPEGXL_ENABLE_TRANSCODE_JPEG } // namespace jpeg } // namespace jxl