| // Copyright 2019 Joe Drago. All rights reserved. |
| // SPDX-License-Identifier: BSD-2-Clause |
| |
| #include "avif/avif.h" |
| |
| extern "C" int LLVMFuzzerTestOneInput(const uint8_t * Data, size_t Size) |
| { |
| static avifRGBFormat rgbFormats[] = { AVIF_RGB_FORMAT_RGB, AVIF_RGB_FORMAT_RGBA }; |
| static size_t rgbFormatsCount = sizeof(rgbFormats) / sizeof(rgbFormats[0]); |
| |
| static avifChromaUpsampling upsamplings[] = { AVIF_CHROMA_UPSAMPLING_BILINEAR, AVIF_CHROMA_UPSAMPLING_NEAREST }; |
| static size_t upsamplingsCount = sizeof(upsamplings) / sizeof(upsamplings[0]); |
| |
| static uint32_t rgbDepths[] = { 8, 10 }; |
| static size_t rgbDepthsCount = sizeof(rgbDepths) / sizeof(rgbDepths[0]); |
| |
| static uint32_t yuvDepths[] = { 8, 10 }; |
| static size_t yuvDepthsCount = sizeof(yuvDepths) / sizeof(yuvDepths[0]); |
| |
| avifDecoder * decoder = avifDecoderCreate(); |
| decoder->allowProgressive = AVIF_TRUE; |
| // ClusterFuzz passes -rss_limit_mb=2560 to avif_decode_fuzzer. Empirically setting |
| // decoder->imageSizeLimit to this value allows avif_decode_fuzzer to consume no more than |
| // 2560 MB of memory. |
| static_assert(11 * 1024 * 10 * 1024 <= AVIF_DEFAULT_IMAGE_SIZE_LIMIT, ""); |
| decoder->imageSizeLimit = 11 * 1024 * 10 * 1024; |
| avifIO * io = avifIOCreateMemoryReader(Data, Size); |
| // Simulate Chrome's avifIO object, which is not persistent. |
| io->persistent = AVIF_FALSE; |
| avifDecoderSetIO(decoder, io); |
| avifResult result = avifDecoderParse(decoder); |
| if (result == AVIF_RESULT_OK) { |
| for (int loop = 0; loop < 2; ++loop) { |
| while (avifDecoderNextImage(decoder) == AVIF_RESULT_OK) { |
| if (((decoder->image->width * decoder->image->height) > (47 * 1024 * 1024)) || (loop != 0) || |
| (decoder->imageIndex != 0)) { |
| // Skip the YUV<->RGB conversion tests, which are time-consuming for large |
| // images. It suffices to run these tests only for loop == 0 and only for the |
| // first image of an image sequence. |
| continue; |
| } |
| avifRGBImage rgb; |
| avifRGBImageSetDefaults(&rgb, decoder->image); |
| |
| for (size_t rgbFormatsIndex = 0; rgbFormatsIndex < rgbFormatsCount; ++rgbFormatsIndex) { |
| for (size_t upsamplingsIndex = 0; upsamplingsIndex < upsamplingsCount; ++upsamplingsIndex) { |
| for (size_t rgbDepthsIndex = 0; rgbDepthsIndex < rgbDepthsCount; ++rgbDepthsIndex) { |
| // Convert to RGB |
| rgb.format = rgbFormats[rgbFormatsIndex]; |
| rgb.depth = rgbDepths[rgbDepthsIndex]; |
| rgb.chromaUpsampling = upsamplings[upsamplingsIndex]; |
| avifRGBImageAllocatePixels(&rgb); |
| avifResult rgbResult = avifImageYUVToRGB(decoder->image, &rgb); |
| // Since avifImageRGBToYUV() ignores rgb.chromaUpsampling, we only need |
| // to test avifImageRGBToYUV() with a single upsamplingsIndex. |
| if ((rgbResult == AVIF_RESULT_OK) && (upsamplingsIndex == 0)) { |
| for (size_t yuvDepthsIndex = 0; yuvDepthsIndex < yuvDepthsCount; ++yuvDepthsIndex) { |
| // ... and back to YUV |
| avifImage * tempImage = avifImageCreate(decoder->image->width, |
| decoder->image->height, |
| yuvDepths[yuvDepthsIndex], |
| decoder->image->yuvFormat); |
| avifResult yuvResult = avifImageRGBToYUV(tempImage, &rgb); |
| if (yuvResult != AVIF_RESULT_OK) { |
| } |
| avifImageDestroy(tempImage); |
| } |
| } |
| |
| avifRGBImageFreePixels(&rgb); |
| } |
| } |
| } |
| } |
| |
| if (loop != 1) { |
| result = avifDecoderReset(decoder); |
| if (result == AVIF_RESULT_OK) { |
| } else { |
| break; |
| } |
| } |
| } |
| } |
| |
| avifDecoderDestroy(decoder); |
| return 0; // Non-zero return values are reserved for future use. |
| } |