// Copyright 2012 Google Inc. All Rights Reserved. // // Use of this source code is governed by a BSD-style license // that can be found in the COPYING file in the root of the source // tree. An additional intellectual property rights grant can be found // in the file PATENTS. All contributing project authors may // be found in the AUTHORS file in the root of the source tree. // ----------------------------------------------------------------------------- // // JPEG decode. #include "./jpegdec.h" #ifdef HAVE_CONFIG_H #include "webp/config.h" #endif #include <stdio.h> #ifdef WEBP_HAVE_JPEG #include <jpeglib.h> #include <jerror.h> #include <setjmp.h> #include <stdlib.h> #include <string.h> #include "webp/encode.h" #include "./imageio_util.h" #include "./metadata.h" // ----------------------------------------------------------------------------- // Metadata processing #ifndef JPEG_APP1 #define JPEG_APP1 … #endif #ifndef JPEG_APP2 #define JPEG_APP2 … #endif typedef struct { const uint8_t* data; size_t data_length; int seq; // this segment's sequence number [1, 255] for use in reassembly. } ICCPSegment; static void SaveMetadataMarkers(j_decompress_ptr dinfo) { const unsigned int max_marker_length = 0xffff; jpeg_save_markers(dinfo, JPEG_APP1, max_marker_length); // Exif/XMP jpeg_save_markers(dinfo, JPEG_APP2, max_marker_length); // ICC profile } static int CompareICCPSegments(const void* a, const void* b) { const ICCPSegment* s1 = (const ICCPSegment*)a; const ICCPSegment* s2 = (const ICCPSegment*)b; return s1->seq - s2->seq; } // Extract ICC profile segments from the marker list in 'dinfo', reassembling // and storing them in 'iccp'. // Returns true on success and false for memory errors and corrupt profiles. static int StoreICCP(j_decompress_ptr dinfo, MetadataPayload* const iccp) { // ICC.1:2010-12 (4.3.0.0) Annex B.4 Embedding ICC Profiles in JPEG files static const char kICCPSignature[] = "ICC_PROFILE"; static const size_t kICCPSignatureLength = 12; // signature includes '\0' static const size_t kICCPSkipLength = 14; // signature + seq & count int expected_count = 0; int actual_count = 0; int seq_max = 0; size_t total_size = 0; ICCPSegment iccp_segments[255]; jpeg_saved_marker_ptr marker; memset(iccp_segments, 0, sizeof(iccp_segments)); for (marker = dinfo->marker_list; marker != NULL; marker = marker->next) { if (marker->marker == JPEG_APP2 && marker->data_length > kICCPSkipLength && !memcmp(marker->data, kICCPSignature, kICCPSignatureLength)) { // ICC_PROFILE\0<seq><count>; 'seq' starts at 1. const int seq = marker->data[kICCPSignatureLength]; const int count = marker->data[kICCPSignatureLength + 1]; const size_t segment_size = marker->data_length - kICCPSkipLength; ICCPSegment* segment; if (segment_size == 0 || count == 0 || seq == 0) { fprintf(stderr, "[ICCP] size (%d) / count (%d) / sequence number (%d)" " cannot be 0!\n", (int)segment_size, seq, count); return 0; } if (expected_count == 0) { expected_count = count; } else if (expected_count != count) { fprintf(stderr, "[ICCP] Inconsistent segment count (%d / %d)!\n", expected_count, count); return 0; } segment = iccp_segments + seq - 1; if (segment->data_length != 0) { fprintf(stderr, "[ICCP] Duplicate segment number (%d)!\n" , seq); return 0; } segment->data = marker->data + kICCPSkipLength; segment->data_length = segment_size; segment->seq = seq; total_size += segment_size; if (seq > seq_max) seq_max = seq; ++actual_count; } } if (actual_count == 0) return 1; if (seq_max != actual_count) { fprintf(stderr, "[ICCP] Discontinuous segments, expected: %d actual: %d!\n", actual_count, seq_max); return 0; } if (expected_count != actual_count) { fprintf(stderr, "[ICCP] Segment count: %d does not match expected: %d!\n", actual_count, expected_count); return 0; } // The segments may appear out of order in the file, sort them based on // sequence number before assembling the payload. qsort(iccp_segments, actual_count, sizeof(*iccp_segments), CompareICCPSegments); iccp->bytes = (uint8_t*)malloc(total_size); if (iccp->bytes == NULL) return 0; iccp->size = total_size; { int i; size_t offset = 0; for (i = 0; i < seq_max; ++i) { memcpy(iccp->bytes + offset, iccp_segments[i].data, iccp_segments[i].data_length); offset += iccp_segments[i].data_length; } } return 1; } // Returns true on success and false for memory errors and corrupt profiles. // The caller must use MetadataFree() on 'metadata' in all cases. static int ExtractMetadataFromJPEG(j_decompress_ptr dinfo, Metadata* const metadata) { static const struct { int marker; const char* signature; size_t signature_length; size_t storage_offset; } kJPEGMetadataMap[] = { // Exif 2.2 Section 4.7.2 Interoperability Structure of APP1 ... { JPEG_APP1, "Exif\0", 6, METADATA_OFFSET(exif) }, // XMP Specification Part 3 Section 3 Embedding XMP Metadata ... #JPEG // TODO(jzern) Add support for 'ExtendedXMP' { JPEG_APP1, "http://ns.adobe.com/xap/1.0/", 29, METADATA_OFFSET(xmp) }, { 0, NULL, 0, 0 }, }; jpeg_saved_marker_ptr marker; // Treat ICC profiles separately as they may be segmented and out of order. if (!StoreICCP(dinfo, &metadata->iccp)) return 0; for (marker = dinfo->marker_list; marker != NULL; marker = marker->next) { int i; for (i = 0; kJPEGMetadataMap[i].marker != 0; ++i) { if (marker->marker == kJPEGMetadataMap[i].marker && marker->data_length > kJPEGMetadataMap[i].signature_length && !memcmp(marker->data, kJPEGMetadataMap[i].signature, kJPEGMetadataMap[i].signature_length)) { MetadataPayload* const payload = (MetadataPayload*)((uint8_t*)metadata + kJPEGMetadataMap[i].storage_offset); if (payload->bytes == NULL) { const char* marker_data = (const char*)marker->data + kJPEGMetadataMap[i].signature_length; const size_t marker_data_length = marker->data_length - kJPEGMetadataMap[i].signature_length; if (!MetadataCopy(marker_data, marker_data_length, payload)) return 0; } else { fprintf(stderr, "Ignoring additional '%s' marker\n", kJPEGMetadataMap[i].signature); } } } } return 1; } #undef JPEG_APP1 #undef JPEG_APP2 // ----------------------------------------------------------------------------- // JPEG decoding struct my_error_mgr { struct jpeg_error_mgr pub; jmp_buf setjmp_buffer; }; static void my_error_exit(j_common_ptr dinfo) { struct my_error_mgr* myerr = (struct my_error_mgr*)dinfo->err; fprintf(stderr, "libjpeg error: "); dinfo->err->output_message(dinfo); longjmp(myerr->setjmp_buffer, 1); } typedef struct { struct jpeg_source_mgr pub; const uint8_t* data; size_t data_size; } JPEGReadContext; static void ContextInit(j_decompress_ptr cinfo) { JPEGReadContext* const ctx = (JPEGReadContext*)cinfo->src; ctx->pub.next_input_byte = ctx->data; ctx->pub.bytes_in_buffer = ctx->data_size; } static boolean ContextFill(j_decompress_ptr cinfo) { // we shouldn't get here. ERREXIT(cinfo, JERR_FILE_READ); return FALSE; } static void ContextSkip(j_decompress_ptr cinfo, long jump_size) { JPEGReadContext* const ctx = (JPEGReadContext*)cinfo->src; size_t jump = (size_t)jump_size; if (jump > ctx->pub.bytes_in_buffer) { // Don't overflow the buffer. jump = ctx->pub.bytes_in_buffer; } ctx->pub.bytes_in_buffer -= jump; ctx->pub.next_input_byte += jump; } static void ContextTerm(j_decompress_ptr cinfo) { (void)cinfo; } static void ContextSetup(volatile struct jpeg_decompress_struct* const cinfo, JPEGReadContext* const ctx) { cinfo->src = (struct jpeg_source_mgr*)ctx; ctx->pub.init_source = ContextInit; ctx->pub.fill_input_buffer = ContextFill; ctx->pub.skip_input_data = ContextSkip; ctx->pub.resync_to_restart = jpeg_resync_to_restart; ctx->pub.term_source = ContextTerm; ctx->pub.bytes_in_buffer = 0; ctx->pub.next_input_byte = NULL; } int ReadJPEG(const uint8_t* const data, size_t data_size, WebPPicture* const pic, int keep_alpha, Metadata* const metadata) { volatile int ok = 0; int width, height; int64_t stride; volatile struct jpeg_decompress_struct dinfo; struct my_error_mgr jerr; uint8_t* volatile rgb = NULL; JSAMPROW buffer[1]; JPEGReadContext ctx; if (data == NULL || data_size == 0 || pic == NULL) return 0; (void)keep_alpha; memset(&ctx, 0, sizeof(ctx)); ctx.data = data; ctx.data_size = data_size; memset((j_decompress_ptr)&dinfo, 0, sizeof(dinfo)); // for setjmp safety dinfo.err = jpeg_std_error(&jerr.pub); jerr.pub.error_exit = my_error_exit; if (setjmp(jerr.setjmp_buffer)) { Error: MetadataFree(metadata); jpeg_destroy_decompress((j_decompress_ptr)&dinfo); goto End; } jpeg_create_decompress((j_decompress_ptr)&dinfo); ContextSetup(&dinfo, &ctx); if (metadata != NULL) SaveMetadataMarkers((j_decompress_ptr)&dinfo); jpeg_read_header((j_decompress_ptr)&dinfo, TRUE); dinfo.out_color_space = JCS_RGB; dinfo.do_fancy_upsampling = TRUE; jpeg_start_decompress((j_decompress_ptr)&dinfo); if (dinfo.output_components != 3) { goto Error; } width = dinfo.output_width; height = dinfo.output_height; stride = (int64_t)dinfo.output_width * dinfo.output_components * sizeof(*rgb); if (stride != (int)stride || !ImgIoUtilCheckSizeArgumentsOverflow(stride, height)) { goto Error; } rgb = (uint8_t*)malloc((size_t)stride * height); if (rgb == NULL) { goto Error; } buffer[0] = (JSAMPLE*)rgb; while (dinfo.output_scanline < dinfo.output_height) { if (jpeg_read_scanlines((j_decompress_ptr)&dinfo, buffer, 1) != 1) { goto Error; } buffer[0] += stride; } if (metadata != NULL) { ok = ExtractMetadataFromJPEG((j_decompress_ptr)&dinfo, metadata); if (!ok) { fprintf(stderr, "Error extracting JPEG metadata!\n"); goto Error; } } jpeg_finish_decompress((j_decompress_ptr)&dinfo); jpeg_destroy_decompress((j_decompress_ptr)&dinfo); // WebP conversion. pic->width = width; pic->height = height; ok = WebPPictureImportRGB(pic, rgb, (int)stride); if (!ok) { pic->width = 0; // WebPPictureImportRGB() barely touches 'pic' on failure. pic->height = 0; // Just reset dimensions but keep any 'custom_ptr' etc. MetadataFree(metadata); // In case the caller forgets to free it on error. } End: free(rgb); return ok; } #else // !WEBP_HAVE_JPEG int ReadJPEG(const uint8_t* const data, size_t data_size, struct WebPPicture* const pic, int keep_alpha, struct Metadata* const metadata) { … } #endif // WEBP_HAVE_JPEG // -----------------------------------------------------------------------------
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