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2.0.6
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=====
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### Significant changes relative to 2.0.5:
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1. Fixed "using JNI after critical get" errors that occurred on Android
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platforms when using any of the YUV encoding/compression/decompression/decoding
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methods in the TurboJPEG Java API.
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2. Fixed or worked around multiple issues with `jpeg_skip_scanlines()`:
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     - Fixed segfaults or "Corrupt JPEG data: premature end of data segment"
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errors in `jpeg_skip_scanlines()` that occurred when decompressing 4:2:2 or
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4:2:0 JPEG images using merged (non-fancy) upsampling/color conversion (that
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is, when setting `cinfo.do_fancy_upsampling` to `FALSE`.)  2.0.0[6] was a
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similar fix, but it did not cover all cases.
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     - `jpeg_skip_scanlines()` now throws an error if two-pass color
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quantization is enabled.  Two-pass color quantization never worked properly
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with `jpeg_skip_scanlines()`, and the issues could not readily be fixed.
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     - Fixed an issue whereby `jpeg_skip_scanlines()` always returned 0 when
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skipping past the end of an image.
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3. The Arm 64-bit (Armv8) Neon SIMD extensions can now be built using MinGW
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toolchains targetting Arm64 (AArch64) Windows binaries.
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4. Fixed unexpected visual artifacts that occurred when using
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`jpeg_crop_scanline()` and interblock smoothing while decompressing only the DC
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scan of a progressive JPEG image.
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5. Fixed an issue whereby libjpeg-turbo would not build if 12-bit-per-component
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JPEG support (`WITH_12BIT`) was enabled along with libjpeg v7 or libjpeg v8
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API/ABI emulation (`WITH_JPEG7` or `WITH_JPEG8`.)
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2.0.5
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=====
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### Significant changes relative to 2.0.4:
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1. Worked around issues in the MIPS DSPr2 SIMD extensions that caused failures
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in the libjpeg-turbo regression tests.  Specifically, the
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`jsimd_h2v1_downsample_dspr2()` and `jsimd_h2v2_downsample_dspr2()` functions
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in the MIPS DSPr2 SIMD extensions are now disabled until/unless they can be
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fixed, and other functions that are incompatible with big endian MIPS CPUs are
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disabled when building libjpeg-turbo for such CPUs.
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2. Fixed an oversight in the `TJCompressor.compress(int)` method in the
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TurboJPEG Java API that caused an error ("java.lang.IllegalStateException: No
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source image is associated with this instance") when attempting to use that
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method to compress a YUV image.
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3. Fixed an issue (CVE-2020-13790) in the PPM reader that caused a buffer
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overrun in cjpeg, TJBench, or the `tjLoadImage()` function if one of the values
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in a binary PPM/PGM input file exceeded the maximum value defined in the file's
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header and that maximum value was less than 255.  libjpeg-turbo 1.5.0 already
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included a similar fix for binary PPM/PGM files with maximum values greater
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than 255.
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4. The TurboJPEG API library's global error handler, which is used in functions
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such as `tjBufSize()` and `tjLoadImage()` that do not require a TurboJPEG
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instance handle, is now thread-safe on platforms that support thread-local
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storage.
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2.0.4
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=====
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### Significant changes relative to 2.0.3:
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1. Fixed a regression in the Windows packaging system (introduced by
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2.0 beta1[2]) whereby, if both the 64-bit libjpeg-turbo SDK for GCC and the
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64-bit libjpeg-turbo SDK for Visual C++ were installed on the same system, only
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one of them could be uninstalled.
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2. Fixed a signed integer overflow and subsequent segfault that occurred when
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attempting to decompress images with more than 715827882 pixels using the
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64-bit C version of TJBench.
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3. Fixed out-of-bounds write in `tjDecompressToYUV2()` and
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`tjDecompressToYUVPlanes()` (sometimes manifesting as a double free) that
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occurred when attempting to decompress grayscale JPEG images that were
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compressed with a sampling factor other than 1 (for instance, with
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`cjpeg -grayscale -sample 2x2`).
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4. Fixed a regression introduced by 2.0.2[5] that caused the TurboJPEG API to
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incorrectly identify some JPEG images with unusual sampling factors as 4:4:4
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JPEG images.  This was known to cause a buffer overflow when attempting to
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decompress some such images using `tjDecompressToYUV2()` or
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`tjDecompressToYUVPlanes()`.
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5. Fixed an issue, detected by ASan, whereby attempting to losslessly transform
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a specially-crafted malformed JPEG image containing an extremely-high-frequency
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coefficient block (junk image data that could never be generated by a
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legitimate JPEG compressor) could cause the Huffman encoder's local buffer to
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be overrun. (Refer to 1.4.0[9] and 1.4beta1[15].)  Given that the buffer
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overrun was fully contained within the stack and did not cause a segfault or
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other user-visible errant behavior, and given that the lossless transformer
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(unlike the decompressor) is not generally exposed to arbitrary data exploits,
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this issue did not likely pose a security risk.
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6. The Arm 64-bit (Armv8) Neon SIMD assembly code now stores constants in a
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separate read-only data section rather than in the text section, to support
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execute-only memory layouts.
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2.0.3
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=====
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### Significant changes relative to 2.0.2:
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1. Fixed "using JNI after critical get" errors that occurred on Android
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platforms when passing invalid arguments to certain methods in the TurboJPEG
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Java API.
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2. Fixed a regression in the SIMD feature detection code, introduced by
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the AVX2 SIMD extensions (2.0 beta1[1]), that was known to cause an illegal
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instruction exception, in rare cases, on CPUs that lack support for CPUID leaf
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07H (or on which the maximum CPUID leaf has been limited by way of a BIOS
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setting.)
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3. The 4:4:0 (h1v2) fancy (smooth) chroma upsampling algorithm in the
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decompressor now uses a similar bias pattern to that of the 4:2:2 (h2v1) fancy
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chroma upsampling algorithm, rounding up or down the upsampled result for
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alternate pixels rather than always rounding down.  This ensures that,
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regardless of whether a 4:2:2 JPEG image is rotated or transposed prior to
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decompression (in the frequency domain) or after decompression (in the spatial
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domain), the final image will be similar.
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4. Fixed an integer overflow and subsequent segfault that occurred when
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attempting to compress or decompress images with more than 1 billion pixels
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using the TurboJPEG API.
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5. Fixed a regression introduced by 2.0 beta1[15] whereby attempting to
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generate a progressive JPEG image on an SSE2-capable CPU using a scan script
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containing one or more scans with lengths divisible by 16 would result in an
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error ("Missing Huffman code table entry") and an invalid JPEG image.
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6. Fixed an issue whereby `tjDecodeYUV()` and `tjDecodeYUVPlanes()` would throw
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an error ("Invalid progressive parameters") or a warning ("Inconsistent
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progression sequence") if passed a TurboJPEG instance that was previously used
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to decompress a progressive JPEG image.
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2.0.2
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=====
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### Significant changes relative to 2.0.1:
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1. Fixed a regression introduced by 2.0.1[5] that prevented a runtime search
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path (rpath) from being embedded in the libjpeg-turbo shared libraries and
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executables for macOS and iOS.  This caused a fatal error of the form
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"dyld: Library not loaded" when attempting to use one of the executables,
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unless `DYLD_LIBRARY_PATH` was explicitly set to the location of the
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libjpeg-turbo shared libraries.
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2. Fixed an integer overflow and subsequent segfault (CVE-2018-20330) that
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occurred when attempting to load a BMP file with more than 1 billion pixels
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using the `tjLoadImage()` function.
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3. Fixed a buffer overrun (CVE-2018-19664) that occurred when attempting to
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decompress a specially-crafted malformed JPEG image to a 256-color BMP using
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djpeg.
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4. Fixed a floating point exception that occurred when attempting to
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decompress a specially-crafted malformed JPEG image with a specified image
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width or height of 0 using the C version of TJBench.
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5. The TurboJPEG API will now decompress 4:4:4 JPEG images with 2x1, 1x2, 3x1,
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or 1x3 luminance and chrominance sampling factors.  This is a non-standard way
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of specifying 1x subsampling (normally 4:4:4 JPEGs have 1x1 luminance and
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chrominance sampling factors), but the JPEG format and the libjpeg API both
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allow it.
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6. Fixed a regression introduced by 2.0 beta1[7] that caused djpeg to generate
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incorrect PPM images when used with the `-colors` option.
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7. Fixed an issue whereby a static build of libjpeg-turbo (a build in which
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`ENABLE_SHARED` is `0`) could not be installed using the Visual Studio IDE.
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8. Fixed a severe performance issue in the Loongson MMI SIMD extensions that
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occurred when compressing RGB images whose image rows were not 64-bit-aligned.
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2.0.1
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=====
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### Significant changes relative to 2.0.0:
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1. Fixed a regression introduced with the new CMake-based Un*x build system,
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whereby jconfig.h could cause compiler warnings of the form
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`"HAVE_*_H" redefined` if it was included by downstream Autotools-based
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projects that used `AC_CHECK_HEADERS()` to check for the existence of locale.h,
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stddef.h, or stdlib.h.
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2. The `jsimd_quantize_float_dspr2()` and `jsimd_convsamp_float_dspr2()`
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functions in the MIPS DSPr2 SIMD extensions are now disabled at compile time
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if the soft float ABI is enabled.  Those functions use instructions that are
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incompatible with the soft float ABI.
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3. Fixed a regression in the SIMD feature detection code, introduced by
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the AVX2 SIMD extensions (2.0 beta1[1]), that caused libjpeg-turbo to crash on
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Windows 7 if Service Pack 1 was not installed.
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4. Fixed out-of-bounds read in cjpeg that occurred when attempting to compress
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a specially-crafted malformed color-index (8-bit-per-sample) Targa file in
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which some of the samples (color indices) exceeded the bounds of the Targa
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file's color table.
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5. Fixed an issue whereby installing a fully static build of libjpeg-turbo
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(a build in which `CFLAGS` contains `-static` and `ENABLE_SHARED` is `0`) would
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fail with "No valid ELF RPATH or RUNPATH entry exists in the file."
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2.0.0
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=====
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### Significant changes relative to 2.0 beta1:
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1. The TurboJPEG API can now decompress CMYK JPEG images that have subsampled M
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and Y components (not to be confused with YCCK JPEG images, in which the C/M/Y
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components have been transformed into luma and chroma.)   Previously, an error
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was generated ("Could not determine subsampling type for JPEG image") when such
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an image was passed to `tjDecompressHeader3()`, `tjTransform()`,
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`tjDecompressToYUVPlanes()`, `tjDecompressToYUV2()`, or the equivalent Java
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methods.
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2. Fixed an issue (CVE-2018-11813) whereby a specially-crafted malformed input
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file (specifically, a file with a valid Targa header but incomplete pixel data)
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would cause cjpeg to generate a JPEG file that was potentially thousands of
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times larger than the input file.  The Targa reader in cjpeg was not properly
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detecting that the end of the input file had been reached prematurely, so after
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all valid pixels had been read from the input, the reader injected dummy pixels
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with values of 255 into the JPEG compressor until the number of pixels
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specified in the Targa header had been compressed.  The Targa reader in cjpeg
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now behaves like the PPM reader and aborts compression if the end of the input
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file is reached prematurely.  Because this issue only affected cjpeg and not
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the underlying library, and because it did not involve any out-of-bounds reads
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or other exploitable behaviors, it was not believed to represent a security
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threat.
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3. Fixed an issue whereby the `tjLoadImage()` and `tjSaveImage()` functions
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would produce a "Bogus message code" error message if the underlying bitmap and
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PPM readers/writers threw an error that was specific to the readers/writers
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(as opposed to a general libjpeg API error.)
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4. Fixed an issue (CVE-2018-1152) whereby a specially-crafted malformed BMP
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file, one in which the header specified an image width of 1073741824 pixels,
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would trigger a floating point exception (division by zero) in the
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`tjLoadImage()` function when attempting to load the BMP file into a
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4-component image buffer.
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5. Fixed an issue whereby certain combinations of calls to
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`jpeg_skip_scanlines()` and `jpeg_read_scanlines()` could trigger an infinite
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loop when decompressing progressive JPEG images that use vertical chroma
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subsampling (for instance, 4:2:0 or 4:4:0.)
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6. Fixed a segfault in `jpeg_skip_scanlines()` that occurred when decompressing
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a 4:2:2 or 4:2:0 JPEG image using the merged (non-fancy) upsampling algorithms
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(that is, when setting `cinfo.do_fancy_upsampling` to `FALSE`.)
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7. The new CMake-based build system will now disable the MIPS DSPr2 SIMD
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extensions if it detects that the compiler does not support DSPr2 instructions.
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8. Fixed out-of-bounds read in cjpeg (CVE-2018-14498) that occurred when
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attempting to compress a specially-crafted malformed color-index
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(8-bit-per-sample) BMP file in which some of the samples (color indices)
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exceeded the bounds of the BMP file's color table.
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9. Fixed a signed integer overflow in the progressive Huffman decoder, detected
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by the Clang and GCC undefined behavior sanitizers, that could be triggered by
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attempting to decompress a specially-crafted malformed JPEG image.  This issue
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did not pose a security threat, but removing the warning made it easier to
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detect actual security issues, should they arise in the future.
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1.5.90 (2.0 beta1)
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==================
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### Significant changes relative to 1.5.3:
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1. Added AVX2 SIMD implementations of the colorspace conversion, chroma
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downsampling and upsampling, integer quantization and sample conversion, and
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accurate integer DCT/IDCT algorithms.  When using the accurate integer DCT/IDCT
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algorithms on AVX2-equipped CPUs, the compression of RGB images is
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approximately 13-36% (avg. 22%) faster (relative to libjpeg-turbo 1.5.x) with
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64-bit code and 11-21% (avg. 17%) faster with 32-bit code, and the
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decompression of RGB images is approximately 9-35% (avg. 17%) faster with
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64-bit code and 7-17% (avg. 12%) faster with 32-bit code.  (As tested on a
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3 GHz Intel Core i7.  Actual mileage may vary.)
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2. Overhauled the build system to use CMake on all platforms, and removed the
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autotools-based build system.  This decision resulted from extensive
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discussions within the libjpeg-turbo community.  libjpeg-turbo traditionally
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used CMake only for Windows builds, but there was an increasing amount of
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demand to extend CMake support to other platforms.  However, because of the
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unique nature of our code base (the need to support different assemblers on
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each platform, the need for Java support, etc.), providing dual build systems
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as other OSS imaging libraries do (including libpng and libtiff) would have
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created a maintenance burden.  The use of CMake greatly simplifies some aspects
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of our build system, owing to CMake's built-in support for various assemblers,
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Java, and unit testing, as well as generally fewer quirks that have to be
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worked around in order to implement our packaging system.  Eliminating
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autotools puts our project slightly at odds with the traditional practices of
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the OSS community, since most "system libraries" tend to be built with
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autotools, but it is believed that the benefits of this move outweigh the
shun-iwasawa 82a8f5
risks.  In addition to providing a unified build environment, switching to
shun-iwasawa 82a8f5
CMake allows for the use of various build tools and IDEs that aren't supported
shun-iwasawa 82a8f5
under autotools, including XCode, Ninja, and Eclipse.  It also eliminates the
shun-iwasawa 82a8f5
need to install autotools via MacPorts/Homebrew on OS X and allows
shun-iwasawa 82a8f5
libjpeg-turbo to be configured without the use of a terminal/command prompt.
shun-iwasawa 82a8f5
Extensive testing was conducted to ensure that all features provided by the
shun-iwasawa 82a8f5
autotools-based build system are provided by the new build system.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. The libjpeg API in this version of libjpeg-turbo now includes two additional
shun-iwasawa 82a8f5
functions, `jpeg_read_icc_profile()` and `jpeg_write_icc_profile()`, that can
shun-iwasawa 82a8f5
be used to extract ICC profile data from a JPEG file while decompressing or to
shun-iwasawa 82a8f5
embed ICC profile data in a JPEG file while compressing or transforming.  This
shun-iwasawa 82a8f5
eliminates the need for downstream projects, such as color management libraries
shun-iwasawa 82a8f5
and browsers, to include their own glueware for accomplishing this.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Improved error handling in the TurboJPEG API library:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
     - Introduced a new function (`tjGetErrorStr2()`) in the TurboJPEG C API
shun-iwasawa 82a8f5
that allows compression/decompression/transform error messages to be retrieved
shun-iwasawa 82a8f5
in a thread-safe manner.  Retrieving error messages from global functions, such
shun-iwasawa 82a8f5
as `tjInitCompress()` or `tjBufSize()`, is still thread-unsafe, but since those
shun-iwasawa 82a8f5
functions will only throw errors if passed an invalid argument or if a memory
shun-iwasawa 82a8f5
allocation failure occurs, thread safety is not as much of a concern.
shun-iwasawa 82a8f5
     - Introduced a new function (`tjGetErrorCode()`) in the TurboJPEG C API
shun-iwasawa 82a8f5
and a new method (`TJException.getErrorCode()`) in the TurboJPEG Java API that
shun-iwasawa 82a8f5
can be used to determine the severity of the last
shun-iwasawa 82a8f5
compression/decompression/transform error.  This allows applications to
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choose whether to ignore warnings (non-fatal errors) from the underlying
shun-iwasawa 82a8f5
libjpeg API or to treat them as fatal.
shun-iwasawa 82a8f5
     - Introduced a new flag (`TJFLAG_STOPONWARNING` in the TurboJPEG C API and
shun-iwasawa 82a8f5
`TJ.FLAG_STOPONWARNING` in the TurboJPEG Java API) that causes the library to
shun-iwasawa 82a8f5
immediately halt a compression/decompression/transform operation if it
shun-iwasawa 82a8f5
encounters a warning from the underlying libjpeg API (the default behavior is
shun-iwasawa 82a8f5
to allow the operation to complete unless a fatal error is encountered.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Introduced a new flag in the TurboJPEG C and Java APIs (`TJFLAG_PROGRESSIVE`
shun-iwasawa 82a8f5
and `TJ.FLAG_PROGRESSIVE`, respectively) that causes the library to use
shun-iwasawa 82a8f5
progressive entropy coding in JPEG images generated by compression and
shun-iwasawa 82a8f5
transform operations.  Additionally, a new transform option
shun-iwasawa 82a8f5
(`TJXOPT_PROGRESSIVE` in the C API and `TJTransform.OPT_PROGRESSIVE` in the
shun-iwasawa 82a8f5
Java API) has been introduced, allowing progressive entropy coding to be
shun-iwasawa 82a8f5
enabled for selected transforms in a multi-transform operation.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Introduced a new transform option in the TurboJPEG API (`TJXOPT_COPYNONE` in
shun-iwasawa 82a8f5
the C API and `TJTransform.OPT_COPYNONE` in the Java API) that allows the
shun-iwasawa 82a8f5
copying of markers (including EXIF and ICC profile data) to be disabled for a
shun-iwasawa 82a8f5
particular transform.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Added two functions to the TurboJPEG C API (`tjLoadImage()` and
shun-iwasawa 82a8f5
`tjSaveImage()`) that can be used to load/save a BMP or PPM/PGM image to/from a
shun-iwasawa 82a8f5
memory buffer with a specified pixel format and layout.  These functions
shun-iwasawa 82a8f5
replace the project-private (and slow) bmp API, which was previously used by
shun-iwasawa 82a8f5
TJBench, and they also provide a convenient way for first-time users of
shun-iwasawa 82a8f5
libjpeg-turbo to quickly develop a complete JPEG compression/decompression
shun-iwasawa 82a8f5
program.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. The TurboJPEG C API now includes a new convenience array (`tjAlphaOffset[]`)
shun-iwasawa 82a8f5
that contains the alpha component index for each pixel format (or -1 if the
shun-iwasawa 82a8f5
pixel format lacks an alpha component.)  The TurboJPEG Java API now includes a
shun-iwasawa 82a8f5
new method (`TJ.getAlphaOffset()`) that returns the same value.  In addition,
shun-iwasawa 82a8f5
the `tjRedOffset[]`, `tjGreenOffset[]`, and `tjBlueOffset[]` arrays-- and the
shun-iwasawa 82a8f5
corresponding `TJ.getRedOffset()`, `TJ.getGreenOffset()`, and
shun-iwasawa 82a8f5
`TJ.getBlueOffset()` methods-- now return -1 for `TJPF_GRAY`/`TJ.PF_GRAY`
shun-iwasawa 82a8f5
rather than 0.  This allows programs to easily determine whether a pixel format
shun-iwasawa 82a8f5
has red, green, blue, and alpha components.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Added a new example (tjexample.c) that demonstrates the basic usage of the
shun-iwasawa 82a8f5
TurboJPEG C API.  This example mirrors the functionality of TJExample.java.
shun-iwasawa 82a8f5
Both files are now included in the libjpeg-turbo documentation.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. Fixed two signed integer overflows in the arithmetic decoder, detected by
shun-iwasawa 82a8f5
the Clang undefined behavior sanitizer, that could be triggered by attempting
shun-iwasawa 82a8f5
to decompress a specially-crafted malformed JPEG image.  These issues did not
shun-iwasawa 82a8f5
pose a security threat, but removing the warnings makes it easier to detect
shun-iwasawa 82a8f5
actual security issues, should they arise in the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Fixed a bug in the merged 4:2:0 upsampling/dithered RGB565 color conversion
shun-iwasawa 82a8f5
algorithm that caused incorrect dithering in the output image.  This algorithm
shun-iwasawa 82a8f5
now produces bitwise-identical results to the unmerged algorithms.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
12. The SIMD function symbols for x86[-64]/ELF, MIPS/ELF, macOS/x86[-64] (if
shun-iwasawa 82a8f5
libjpeg-turbo is built with YASM), and iOS/Arm[64] builds are now private.
shun-iwasawa 82a8f5
This prevents those symbols from being exposed in applications or shared
shun-iwasawa 82a8f5
libraries that link statically with libjpeg-turbo.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
13. Added Loongson MMI SIMD implementations of the RGB-to-YCbCr and
shun-iwasawa 82a8f5
YCbCr-to-RGB colorspace conversion, 4:2:0 chroma downsampling, 4:2:0 fancy
shun-iwasawa 82a8f5
chroma upsampling, integer quantization, and accurate integer DCT/IDCT
shun-iwasawa 82a8f5
algorithms.  When using the accurate integer DCT/IDCT, this speeds up the
shun-iwasawa 82a8f5
compression of RGB images by approximately 70-100% and the decompression of RGB
shun-iwasawa 82a8f5
images by approximately 2-3.5x.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
14. Fixed a build error when building with older MinGW releases (regression
shun-iwasawa 82a8f5
caused by 1.5.1[7].)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
15. Added SIMD acceleration for progressive Huffman encoding on SSE2-capable
shun-iwasawa 82a8f5
x86 and x86-64 platforms.  This speeds up the compression of full-color
shun-iwasawa 82a8f5
progressive JPEGs by about 85-90% on average (relative to libjpeg-turbo 1.5.x)
shun-iwasawa 82a8f5
when using modern Intel and AMD CPUs.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.5.3
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.5.2:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed a NullPointerException in the TurboJPEG Java wrapper that occurred
shun-iwasawa 82a8f5
when using the YUVImage constructor that creates an instance backed by separate
shun-iwasawa 82a8f5
image planes and allocates memory for the image planes.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Fixed an issue whereby the Java version of TJUnitTest would fail when
shun-iwasawa 82a8f5
testing BufferedImage encoding/decoding on big endian systems.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed a segfault in djpeg that would occur if an output format other than
shun-iwasawa 82a8f5
PPM/PGM was selected along with the `-crop` option.  The `-crop` option now
shun-iwasawa 82a8f5
works with the GIF and Targa formats as well (unfortunately, it cannot be made
shun-iwasawa 82a8f5
to work with the BMP and RLE formats due to the fact that those output engines
shun-iwasawa 82a8f5
write scanlines in bottom-up order.)  djpeg will now exit gracefully if an
shun-iwasawa 82a8f5
output format other than PPM/PGM, GIF, or Targa is selected along with the
shun-iwasawa 82a8f5
`-crop` option.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed an issue (CVE-2017-15232) whereby `jpeg_skip_scanlines()` would
shun-iwasawa 82a8f5
segfault if color quantization was enabled.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. TJBench (both C and Java versions) will now display usage information if any
shun-iwasawa 82a8f5
command-line argument is unrecognized.  This prevents the program from silently
shun-iwasawa 82a8f5
ignoring typos.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Fixed an access violation in tjbench.exe (Windows) that occurred when the
shun-iwasawa 82a8f5
program was used to decompress an existing JPEG image.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Fixed an ArrayIndexOutOfBoundsException in the TJExample Java program that
shun-iwasawa 82a8f5
occurred when attempting to decompress a JPEG image that had been compressed
shun-iwasawa 82a8f5
with 4:1:1 chrominance subsampling.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Fixed an issue whereby, when using `jpeg_skip_scanlines()` to skip to the
shun-iwasawa 82a8f5
end of a single-scan (non-progressive) image, subsequent calls to
shun-iwasawa 82a8f5
`jpeg_consume_input()` would return `JPEG_SUSPENDED` rather than
shun-iwasawa 82a8f5
`JPEG_REACHED_EOI`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. `jpeg_crop_scanline()` now works correctly when decompressing grayscale JPEG
shun-iwasawa 82a8f5
images that were compressed with a sampling factor other than 1 (for instance,
shun-iwasawa 82a8f5
with `cjpeg -grayscale -sample 2x2`).
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.5.2
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.5.1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed a regression introduced by 1.5.1[7] that prevented libjpeg-turbo from
shun-iwasawa 82a8f5
building with Android NDK platforms prior to android-21 (5.0).
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Fixed a regression introduced by 1.5.1[1] that prevented the MIPS DSPR2 SIMD
shun-iwasawa 82a8f5
code in libjpeg-turbo from building.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed a regression introduced by 1.5 beta1[11] that prevented the Java
shun-iwasawa 82a8f5
version of TJBench from outputting any reference images (the `-nowrite` switch
shun-iwasawa 82a8f5
was accidentally enabled by default.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. libjpeg-turbo should now build and run with full AltiVec SIMD acceleration
shun-iwasawa 82a8f5
on PowerPC-based AmigaOS 4 and OpenBSD systems.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed build and runtime errors on Windows that occurred when building
shun-iwasawa 82a8f5
libjpeg-turbo with libjpeg v7 API/ABI emulation and the in-memory
shun-iwasawa 82a8f5
source/destination managers.  Due to an oversight, the `jpeg_skip_scanlines()`
shun-iwasawa 82a8f5
and `jpeg_crop_scanline()` functions were not being included in jpeg7.dll when
shun-iwasawa 82a8f5
libjpeg-turbo was built with `-DWITH_JPEG7=1` and `-DWITH_MEMSRCDST=1`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Fixed "Bogus virtual array access" error that occurred when using the
shun-iwasawa 82a8f5
lossless crop feature in jpegtran or the TurboJPEG API, if libjpeg-turbo was
shun-iwasawa 82a8f5
built with libjpeg v7 API/ABI emulation.  This was apparently a long-standing
shun-iwasawa 82a8f5
bug that has existed since the introduction of libjpeg v7/v8 API/ABI emulation
shun-iwasawa 82a8f5
in libjpeg-turbo v1.1.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. The lossless transform features in jpegtran and the TurboJPEG API will now
shun-iwasawa 82a8f5
always attempt to adjust the EXIF image width and height tags if the image size
shun-iwasawa 82a8f5
changed as a result of the transform.  This behavior has always existed when
shun-iwasawa 82a8f5
using libjpeg v8 API/ABI emulation.  It was supposed to be available with
shun-iwasawa 82a8f5
libjpeg v7 API/ABI emulation as well but did not work properly due to a bug.
shun-iwasawa 82a8f5
Furthermore, there was never any good reason not to enable it with libjpeg v6b
shun-iwasawa 82a8f5
API/ABI emulation, since the behavior is entirely internal.  Note that
shun-iwasawa 82a8f5
`-copy all` must be passed to jpegtran in order to transfer the EXIF tags from
shun-iwasawa 82a8f5
the source image to the destination image.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Fixed several memory leaks in the TurboJPEG API library that could occur
shun-iwasawa 82a8f5
if the library was built with certain compilers and optimization levels
shun-iwasawa 82a8f5
(known to occur with GCC 4.x and clang with `-O1` and higher but not with
shun-iwasawa 82a8f5
GCC 5.x or 6.x) and one of the underlying libjpeg API functions threw an error
shun-iwasawa 82a8f5
after a TurboJPEG API function allocated a local buffer.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. The libjpeg-turbo memory manager will now honor the `max_memory_to_use`
shun-iwasawa 82a8f5
structure member in jpeg\_memory\_mgr, which can be set to the maximum amount
shun-iwasawa 82a8f5
of memory (in bytes) that libjpeg-turbo should use during decompression or
shun-iwasawa 82a8f5
multi-pass (including progressive) compression.  This limit can also be set
shun-iwasawa 82a8f5
using the `JPEGMEM` environment variable or using the `-maxmemory` switch in
shun-iwasawa 82a8f5
cjpeg/djpeg/jpegtran (refer to the respective man pages for more details.)
shun-iwasawa 82a8f5
This has been a documented feature of libjpeg since v5, but the
shun-iwasawa 82a8f5
`malloc()`/`free()` implementation of the memory manager (jmemnobs.c) never
shun-iwasawa 82a8f5
implemented the feature.  Restricting libjpeg-turbo's memory usage is useful
shun-iwasawa 82a8f5
for two reasons:  it allows testers to more easily work around the 2 GB limit
shun-iwasawa 82a8f5
in libFuzzer, and it allows developers of security-sensitive applications to
shun-iwasawa 82a8f5
more easily defend against one of the progressive JPEG exploits (LJT-01-004)
shun-iwasawa 82a8f5
identified in
shun-iwasawa 82a8f5
[this report](http://www.libjpeg-turbo.org/pmwiki/uploads/About/TwoIssueswiththeJPEGStandard.pdf).
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. TJBench will now run each benchmark for 1 second prior to starting the
shun-iwasawa 82a8f5
timer, in order to improve the consistency of the results.  Furthermore, the
shun-iwasawa 82a8f5
`-warmup` option is now used to specify the amount of warmup time rather than
shun-iwasawa 82a8f5
the number of warmup iterations.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Fixed an error (`short jump is out of range`) that occurred when assembling
shun-iwasawa 82a8f5
the 32-bit x86 SIMD extensions with NASM versions prior to 2.04.  This was a
shun-iwasawa 82a8f5
regression introduced by 1.5 beta1[12].
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.5.1
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.5.0:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Previously, the undocumented `JSIMD_FORCE*` environment variables could be
shun-iwasawa 82a8f5
used to force-enable a particular SIMD instruction set if multiple instruction
shun-iwasawa 82a8f5
sets were available on a particular platform.  On x86 platforms, where CPU
shun-iwasawa 82a8f5
feature detection is bulletproof and multiple SIMD instruction sets are
shun-iwasawa 82a8f5
available, it makes sense for those environment variables to allow forcing the
shun-iwasawa 82a8f5
use of an instruction set only if that instruction set is available.  However,
shun-iwasawa 82a8f5
since the ARM implementations of libjpeg-turbo can only use one SIMD
shun-iwasawa 82a8f5
instruction set, and since their feature detection code is less bulletproof
shun-iwasawa 82a8f5
(parsing /proc/cpuinfo), it makes sense for the `JSIMD_FORCENEON` environment
shun-iwasawa 82a8f5
variable to bypass the feature detection code and really force the use of NEON
shun-iwasawa 82a8f5
instructions.  A new environment variable (`JSIMD_FORCEDSPR2`) was introduced
shun-iwasawa 82a8f5
in the MIPS implementation for the same reasons, and the existing
shun-iwasawa 82a8f5
`JSIMD_FORCENONE` environment variable was extended to that implementation.
shun-iwasawa 82a8f5
These environment variables provide a workaround for those attempting to test
shun-iwasawa 82a8f5
ARM and MIPS builds of libjpeg-turbo in QEMU, which passes through
shun-iwasawa 82a8f5
/proc/cpuinfo from the host system.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. libjpeg-turbo previously assumed that AltiVec instructions were always
shun-iwasawa 82a8f5
available on PowerPC platforms, which led to "illegal instruction" errors when
shun-iwasawa 82a8f5
running on PowerPC chips that lack AltiVec support (such as the older 7xx/G3
shun-iwasawa 82a8f5
and newer e5500 series.)  libjpeg-turbo now examines /proc/cpuinfo on
shun-iwasawa 82a8f5
Linux/Android systems and enables AltiVec instructions only if the CPU supports
shun-iwasawa 82a8f5
them.  It also now provides two environment variables, `JSIMD_FORCEALTIVEC` and
shun-iwasawa 82a8f5
`JSIMD_FORCENONE`, to force-enable and force-disable AltiVec instructions in
shun-iwasawa 82a8f5
environments where /proc/cpuinfo is an unreliable means of CPU feature
shun-iwasawa 82a8f5
detection (such as when running in QEMU.)  On OS X, libjpeg-turbo continues to
shun-iwasawa 82a8f5
assume that AltiVec support is always available, which means that libjpeg-turbo
shun-iwasawa 82a8f5
cannot be used with G3 Macs unless you set the environment variable
shun-iwasawa 82a8f5
`JSIMD_FORCENONE` to `1`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed an issue whereby 64-bit ARM (AArch64) builds of libjpeg-turbo would
shun-iwasawa 82a8f5
crash when built with recent releases of the Clang/LLVM compiler.  This was
shun-iwasawa 82a8f5
caused by an ABI conformance issue in some of libjpeg-turbo's 64-bit NEON SIMD
shun-iwasawa 82a8f5
routines.  Those routines were incorrectly using 64-bit instructions to
shun-iwasawa 82a8f5
transfer a 32-bit JDIMENSION argument, whereas the ABI allows the upper
shun-iwasawa 82a8f5
(unused) 32 bits of a 32-bit argument's register to be undefined.  The new
shun-iwasawa 82a8f5
Clang/LLVM optimizer uses load combining to transfer multiple adjacent 32-bit
shun-iwasawa 82a8f5
structure members into a single 64-bit register, and this exposed the ABI
shun-iwasawa 82a8f5
conformance issue.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fancy upsampling is now supported when decompressing JPEG images that use
shun-iwasawa 82a8f5
4:4:0 (h1v2) chroma subsampling.  These images are generated when losslessly
shun-iwasawa 82a8f5
rotating or transposing JPEG images that use 4:2:2 (h2v1) chroma subsampling.
shun-iwasawa 82a8f5
The h1v2 fancy upsampling algorithm is not currently SIMD-accelerated.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. If merged upsampling isn't SIMD-accelerated but YCbCr-to-RGB conversion is,
shun-iwasawa 82a8f5
then libjpeg-turbo will now disable merged upsampling when decompressing YCbCr
shun-iwasawa 82a8f5
JPEG images into RGB or extended RGB output images.  This significantly speeds
shun-iwasawa 82a8f5
up the decompression of 4:2:0 and 4:2:2 JPEGs on ARM platforms if fancy
shun-iwasawa 82a8f5
upsampling is not used (for example, if the `-nosmooth` option to djpeg is
shun-iwasawa 82a8f5
specified.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. The TurboJPEG API will now decompress 4:2:2 and 4:4:0 JPEG images with
shun-iwasawa 82a8f5
2x2 luminance sampling factors and 2x1 or 1x2 chrominance sampling factors.
shun-iwasawa 82a8f5
This is a non-standard way of specifying 2x subsampling (normally 4:2:2 JPEGs
shun-iwasawa 82a8f5
have 2x1 luminance and 1x1 chrominance sampling factors, and 4:4:0 JPEGs have
shun-iwasawa 82a8f5
1x2 luminance and 1x1 chrominance sampling factors), but the JPEG format and
shun-iwasawa 82a8f5
the libjpeg API both allow it.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Fixed an unsigned integer overflow in the libjpeg memory manager, detected
shun-iwasawa 82a8f5
by the Clang undefined behavior sanitizer, that could be triggered by
shun-iwasawa 82a8f5
attempting to decompress a specially-crafted malformed JPEG image.  This issue
shun-iwasawa 82a8f5
affected only 32-bit code and did not pose a security threat, but removing the
shun-iwasawa 82a8f5
warning makes it easier to detect actual security issues, should they arise in
shun-iwasawa 82a8f5
the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Fixed additional negative left shifts and other issues reported by the GCC
shun-iwasawa 82a8f5
and Clang undefined behavior sanitizers when attempting to decompress
shun-iwasawa 82a8f5
specially-crafted malformed JPEG images.  None of these issues posed a security
shun-iwasawa 82a8f5
threat, but removing the warnings makes it easier to detect actual security
shun-iwasawa 82a8f5
issues, should they arise in the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Fixed an out-of-bounds array reference, introduced by 1.4.90[2] (partial
shun-iwasawa 82a8f5
image decompression) and detected by the Clang undefined behavior sanitizer,
shun-iwasawa 82a8f5
that could be triggered by a specially-crafted malformed JPEG image with more
shun-iwasawa 82a8f5
than four components.  Because the out-of-bounds reference was still within the
shun-iwasawa 82a8f5
same structure, it was not known to pose a security threat, but removing the
shun-iwasawa 82a8f5
warning makes it easier to detect actual security issues, should they arise in
shun-iwasawa 82a8f5
the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. Fixed another ABI conformance issue in the 64-bit ARM (AArch64) NEON SIMD
shun-iwasawa 82a8f5
code.  Some of the routines were incorrectly reading and storing data below the
shun-iwasawa 82a8f5
stack pointer, which caused segfaults in certain applications under specific
shun-iwasawa 82a8f5
circumstances.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.5.0
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.5 beta1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed an issue whereby a malformed motion-JPEG frame could cause the "fast
shun-iwasawa 82a8f5
path" of libjpeg-turbo's Huffman decoder to read from uninitialized memory.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Added libjpeg-turbo version and build information to the global string table
shun-iwasawa 82a8f5
of the libjpeg and TurboJPEG API libraries.  This is a common practice in other
shun-iwasawa 82a8f5
infrastructure libraries, such as OpenSSL and libpng, because it makes it easy
shun-iwasawa 82a8f5
to examine an application binary and determine which version of the library the
shun-iwasawa 82a8f5
application was linked against.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed a couple of issues in the PPM reader that would cause buffer overruns
shun-iwasawa 82a8f5
in cjpeg if one of the values in a binary PPM/PGM input file exceeded the
shun-iwasawa 82a8f5
maximum value defined in the file's header and that maximum value was greater
shun-iwasawa 82a8f5
than 255.  libjpeg-turbo 1.4.2 already included a similar fix for ASCII PPM/PGM
shun-iwasawa 82a8f5
files.  Note that these issues were not security bugs, since they were confined
shun-iwasawa 82a8f5
to the cjpeg program and did not affect any of the libjpeg-turbo libraries.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed an issue whereby attempting to decompress a JPEG file with a corrupt
shun-iwasawa 82a8f5
header using the `tjDecompressToYUV2()` function would cause the function to
shun-iwasawa 82a8f5
abort without returning an error and, under certain circumstances, corrupt the
shun-iwasawa 82a8f5
stack.  This only occurred if `tjDecompressToYUV2()` was called prior to
shun-iwasawa 82a8f5
calling `tjDecompressHeader3()`, or if the return value from
shun-iwasawa 82a8f5
`tjDecompressHeader3()` was ignored (both cases represent incorrect usage of
shun-iwasawa 82a8f5
the TurboJPEG API.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed an issue in the ARM 32-bit SIMD-accelerated Huffman encoder that
shun-iwasawa 82a8f5
prevented the code from assembling properly with clang.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. The `jpeg_stdio_src()`, `jpeg_mem_src()`, `jpeg_stdio_dest()`, and
shun-iwasawa 82a8f5
`jpeg_mem_dest()` functions in the libjpeg API will now throw an error if a
shun-iwasawa 82a8f5
source/destination manager has already been assigned to the compress or
shun-iwasawa 82a8f5
decompress object by a different function or by the calling program.  This
shun-iwasawa 82a8f5
prevents these functions from attempting to reuse a source/destination manager
shun-iwasawa 82a8f5
structure that was allocated elsewhere, because there is no way to ensure that
shun-iwasawa 82a8f5
it would be big enough to accommodate the new source/destination manager.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.4.90 (1.5 beta1)
shun-iwasawa 82a8f5
==================
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.4.2:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Added full SIMD acceleration for PowerPC platforms using AltiVec VMX
shun-iwasawa 82a8f5
(128-bit SIMD) instructions.  Although the performance of libjpeg-turbo on
shun-iwasawa 82a8f5
PowerPC was already good, due to the increased number of registers available
shun-iwasawa 82a8f5
to the compiler vs. x86, it was still possible to speed up compression by about
shun-iwasawa 82a8f5
3-4x and decompression by about 2-2.5x (relative to libjpeg v6b) through the
shun-iwasawa 82a8f5
use of AltiVec instructions.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Added two new libjpeg API functions (`jpeg_skip_scanlines()` and
shun-iwasawa 82a8f5
`jpeg_crop_scanline()`) that can be used to partially decode a JPEG image.  See
shun-iwasawa 82a8f5
[libjpeg.txt](libjpeg.txt) for more details.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. The TJCompressor and TJDecompressor classes in the TurboJPEG Java API now
shun-iwasawa 82a8f5
implement the Closeable interface, so those classes can be used with a
shun-iwasawa 82a8f5
try-with-resources statement.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. The TurboJPEG Java classes now throw unchecked idiomatic exceptions
shun-iwasawa 82a8f5
(IllegalArgumentException, IllegalStateException) for unrecoverable errors
shun-iwasawa 82a8f5
caused by incorrect API usage, and those classes throw a new checked exception
shun-iwasawa 82a8f5
type (TJException) for errors that are passed through from the C library.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Source buffers for the TurboJPEG C API functions, as well as the
shun-iwasawa 82a8f5
`jpeg_mem_src()` function in the libjpeg API, are now declared as const
shun-iwasawa 82a8f5
pointers.  This facilitates passing read-only buffers to those functions and
shun-iwasawa 82a8f5
ensures the caller that the source buffer will not be modified.  This should
shun-iwasawa 82a8f5
not create any backward API or ABI incompatibilities with prior libjpeg-turbo
shun-iwasawa 82a8f5
releases.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. The MIPS DSPr2 SIMD code can now be compiled to support either FR=0 or FR=1
shun-iwasawa 82a8f5
FPUs.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Fixed additional negative left shifts and other issues reported by the GCC
shun-iwasawa 82a8f5
and Clang undefined behavior sanitizers.  Most of these issues affected only
shun-iwasawa 82a8f5
32-bit code, and none of them was known to pose a security threat, but removing
shun-iwasawa 82a8f5
the warnings makes it easier to detect actual security issues, should they
shun-iwasawa 82a8f5
arise in the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Removed the unnecessary `.arch` directive from the ARM64 NEON SIMD code.
shun-iwasawa 82a8f5
This directive was preventing the code from assembling using the clang
shun-iwasawa 82a8f5
integrated assembler.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Fixed a regression caused by 1.4.1[6] that prevented 32-bit and 64-bit
shun-iwasawa 82a8f5
libjpeg-turbo RPMs from being installed simultaneously on recent Red Hat/Fedora
shun-iwasawa 82a8f5
distributions.  This was due to the addition of a macro in jconfig.h that
shun-iwasawa 82a8f5
allows the Huffman codec to determine the word size at compile time.  Since
shun-iwasawa 82a8f5
that macro differs between 32-bit and 64-bit builds, this caused a conflict
shun-iwasawa 82a8f5
between the i386 and x86_64 RPMs (any differing files, other than executables,
shun-iwasawa 82a8f5
are not allowed when 32-bit and 64-bit RPMs are installed simultaneously.)
shun-iwasawa 82a8f5
Since the macro is used only internally, it has been moved into jconfigint.h.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. The x86-64 SIMD code can now be disabled at run time by setting the
shun-iwasawa 82a8f5
`JSIMD_FORCENONE` environment variable to `1` (the other SIMD implementations
shun-iwasawa 82a8f5
already had this capability.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Added a new command-line argument to TJBench (`-nowrite`) that prevents the
shun-iwasawa 82a8f5
benchmark from outputting any images.  This removes any potential operating
shun-iwasawa 82a8f5
system overhead that might be caused by lazy writes to disk and thus improves
shun-iwasawa 82a8f5
the consistency of the performance measurements.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
12. Added SIMD acceleration for Huffman encoding on SSE2-capable x86 and x86-64
shun-iwasawa 82a8f5
platforms.  This speeds up the compression of full-color JPEGs by about 10-15%
shun-iwasawa 82a8f5
on average (relative to libjpeg-turbo 1.4.x) when using modern Intel and AMD
shun-iwasawa 82a8f5
CPUs.  Additionally, this works around an issue in the clang optimizer that
shun-iwasawa 82a8f5
prevents it (as of this writing) from achieving the same performance as GCC
shun-iwasawa 82a8f5
when compiling the C version of the Huffman encoder
shun-iwasawa 82a8f5
(<https: bugs="" llvm.org="" show_bug.cgi?id="16035">).  For the purposes of</https:>
shun-iwasawa 82a8f5
benchmarking or regression testing, SIMD-accelerated Huffman encoding can be
shun-iwasawa 82a8f5
disabled by setting the `JSIMD_NOHUFFENC` environment variable to `1`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
13. Added ARM 64-bit (ARMv8) NEON SIMD implementations of the commonly-used
shun-iwasawa 82a8f5
compression algorithms (including the accurate integer forward DCT and h2v2 &
shun-iwasawa 82a8f5
h2v1 downsampling algorithms, which are not accelerated in the 32-bit NEON
shun-iwasawa 82a8f5
implementation.)  This speeds up the compression of full-color JPEGs by about
shun-iwasawa 82a8f5
75% on average on a Cavium ThunderX processor and by about 2-2.5x on average on
shun-iwasawa 82a8f5
Cortex-A53 and Cortex-A57 cores.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
14. Added SIMD acceleration for Huffman encoding on NEON-capable ARM 32-bit
shun-iwasawa 82a8f5
and 64-bit platforms.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
    For 32-bit code, this speeds up the compression of full-color JPEGs by
shun-iwasawa 82a8f5
about 30% on average on a typical iOS device (iPhone 4S, Cortex-A9) and by
shun-iwasawa 82a8f5
about 6-7% on average on a typical Android device (Nexus 5X, Cortex-A53 and
shun-iwasawa 82a8f5
Cortex-A57), relative to libjpeg-turbo 1.4.x.  Note that the larger speedup
shun-iwasawa 82a8f5
under iOS is due to the fact that iOS builds use LLVM, which does not optimize
shun-iwasawa 82a8f5
the C Huffman encoder as well as GCC does.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
    For 64-bit code, NEON-accelerated Huffman encoding speeds up the
shun-iwasawa 82a8f5
compression of full-color JPEGs by about 40% on average on a typical iOS device
shun-iwasawa 82a8f5
(iPhone 5S, Apple A7) and by about 7-8% on average on a typical Android device
shun-iwasawa 82a8f5
(Nexus 5X, Cortex-A53 and Cortex-A57), in addition to the speedup described in
shun-iwasawa 82a8f5
[13] above.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
    For the purposes of benchmarking or regression testing, SIMD-accelerated
shun-iwasawa 82a8f5
Huffman encoding can be disabled by setting the `JSIMD_NOHUFFENC` environment
shun-iwasawa 82a8f5
variable to `1`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
15. pkg-config (.pc) scripts are now included for both the libjpeg and
shun-iwasawa 82a8f5
TurboJPEG API libraries on Un*x systems.  Note that if a project's build system
shun-iwasawa 82a8f5
relies on these scripts, then it will not be possible to build that project
shun-iwasawa 82a8f5
with libjpeg or with a prior version of libjpeg-turbo.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
16. Optimized the ARM 64-bit (ARMv8) NEON SIMD decompression routines to
shun-iwasawa 82a8f5
improve performance on CPUs with in-order pipelines.  This speeds up the
shun-iwasawa 82a8f5
decompression of full-color JPEGs by nearly 2x on average on a Cavium ThunderX
shun-iwasawa 82a8f5
processor and by about 15% on average on a Cortex-A53 core.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
17. Fixed an issue in the accelerated Huffman decoder that could have caused
shun-iwasawa 82a8f5
the decoder to read past the end of the input buffer when a malformed,
shun-iwasawa 82a8f5
specially-crafted JPEG image was being decompressed.  In prior versions of
shun-iwasawa 82a8f5
libjpeg-turbo, the accelerated Huffman decoder was invoked (in most cases) only
shun-iwasawa 82a8f5
if there were > 128 bytes of data in the input buffer.  However, it is possible
shun-iwasawa 82a8f5
to construct a JPEG image in which a single Huffman block is over 430 bytes
shun-iwasawa 82a8f5
long, so this version of libjpeg-turbo activates the accelerated Huffman
shun-iwasawa 82a8f5
decoder only if there are > 512 bytes of data in the input buffer.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
18. Fixed a memory leak in tjunittest encountered when running the program
shun-iwasawa 82a8f5
with the `-yuv` option.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.4.2
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.4.1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed an issue whereby cjpeg would segfault if a Windows bitmap with a
shun-iwasawa 82a8f5
negative width or height was used as an input image (Windows bitmaps can have
shun-iwasawa 82a8f5
a negative height if they are stored in top-down order, but such files are
shun-iwasawa 82a8f5
rare and not supported by libjpeg-turbo.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Fixed an issue whereby, under certain circumstances, libjpeg-turbo would
shun-iwasawa 82a8f5
incorrectly encode certain JPEG images when quality=100 and the fast integer
shun-iwasawa 82a8f5
forward DCT were used.  This was known to cause `make test` to fail when the
shun-iwasawa 82a8f5
library was built with `-march=haswell` on x86 systems.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed an issue whereby libjpeg-turbo would crash when built with the latest
shun-iwasawa 82a8f5
& greatest development version of the Clang/LLVM compiler.  This was caused by
shun-iwasawa 82a8f5
an x86-64 ABI conformance issue in some of libjpeg-turbo's 64-bit SSE2 SIMD
shun-iwasawa 82a8f5
routines.  Those routines were incorrectly using a 64-bit `mov` instruction to
shun-iwasawa 82a8f5
transfer a 32-bit JDIMENSION argument, whereas the x86-64 ABI allows the upper
shun-iwasawa 82a8f5
(unused) 32 bits of a 32-bit argument's register to be undefined.  The new
shun-iwasawa 82a8f5
Clang/LLVM optimizer uses load combining to transfer multiple adjacent 32-bit
shun-iwasawa 82a8f5
structure members into a single 64-bit register, and this exposed the ABI
shun-iwasawa 82a8f5
conformance issue.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed a bug in the MIPS DSPr2 4:2:0 "plain" (non-fancy and non-merged)
shun-iwasawa 82a8f5
upsampling routine that caused a buffer overflow (and subsequent segfault) when
shun-iwasawa 82a8f5
decompressing a 4:2:0 JPEG image whose scaled output width was less than 16
shun-iwasawa 82a8f5
pixels.  The "plain" upsampling routines are normally only used when
shun-iwasawa 82a8f5
decompressing a non-YCbCr JPEG image, but they are also used when decompressing
shun-iwasawa 82a8f5
a JPEG image whose scaled output height is 1.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed various negative left shifts and other issues reported by the GCC and
shun-iwasawa 82a8f5
Clang undefined behavior sanitizers.  None of these was known to pose a
shun-iwasawa 82a8f5
security threat, but removing the warnings makes it easier to detect actual
shun-iwasawa 82a8f5
security issues, should they arise in the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.4.1
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.4.0:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. tjbench now properly handles CMYK/YCCK JPEG files.  Passing an argument of
shun-iwasawa 82a8f5
`-cmyk` (instead of, for instance, `-rgb`) will cause tjbench to internally
shun-iwasawa 82a8f5
convert the source bitmap to CMYK prior to compression, to generate YCCK JPEG
shun-iwasawa 82a8f5
files, and to internally convert the decompressed CMYK pixels back to RGB after
shun-iwasawa 82a8f5
decompression (the latter is done automatically if a CMYK or YCCK JPEG is
shun-iwasawa 82a8f5
passed to tjbench as a source image.)  The CMYK<->RGB conversion operation is
shun-iwasawa 82a8f5
not benchmarked.  NOTE: The quick & dirty CMYK<->RGB conversions that tjbench
shun-iwasawa 82a8f5
uses are suitable for testing only.  Proper conversion between CMYK and RGB
shun-iwasawa 82a8f5
requires a color management system.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. `make test` now performs additional bitwise regression tests using tjbench,
shun-iwasawa 82a8f5
mainly for the purpose of testing compression from/decompression to a subregion
shun-iwasawa 82a8f5
of a larger image buffer.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. `make test` no longer tests the regression of the floating point DCT/IDCT
shun-iwasawa 82a8f5
by default, since the results of those tests can vary if the algorithms in
shun-iwasawa 82a8f5
question are not implemented using SIMD instructions on a particular platform.
shun-iwasawa 82a8f5
See the comments in [Makefile.am](Makefile.am) for information on how to
shun-iwasawa 82a8f5
re-enable the tests and to specify an expected result for them based on the
shun-iwasawa 82a8f5
particulars of your platform.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. The NULL color conversion routines have been significantly optimized,
shun-iwasawa 82a8f5
which speeds up the compression of RGB and CMYK JPEGs by 5-20% when using
shun-iwasawa 82a8f5
64-bit code and 0-3% when using 32-bit code, and the decompression of those
shun-iwasawa 82a8f5
images by 10-30% when using 64-bit code and 3-12% when using 32-bit code.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed an "illegal instruction" error that occurred when djpeg from a
shun-iwasawa 82a8f5
SIMD-enabled libjpeg-turbo MIPS build was executed with the `-nosmooth` option
shun-iwasawa 82a8f5
on a MIPS machine that lacked DSPr2 support.  The MIPS SIMD routines for h2v1
shun-iwasawa 82a8f5
and h2v2 merged upsampling were not properly checking for the existence of
shun-iwasawa 82a8f5
DSPr2.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Performance has been improved significantly on 64-bit non-Linux and
shun-iwasawa 82a8f5
non-Windows platforms (generally 10-20% faster compression and 5-10% faster
shun-iwasawa 82a8f5
decompression.)  Due to an oversight, the 64-bit version of the accelerated
shun-iwasawa 82a8f5
Huffman codec was not being compiled in when libjpeg-turbo was built on
shun-iwasawa 82a8f5
platforms other than Windows or Linux.  Oops.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Fixed an extremely rare bug in the Huffman encoder that caused 64-bit
shun-iwasawa 82a8f5
builds of libjpeg-turbo to incorrectly encode a few specific test images when
shun-iwasawa 82a8f5
quality=98, an optimized Huffman table, and the accurate integer forward DCT
shun-iwasawa 82a8f5
were used.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. The Windows (CMake) build system now supports building only static or only
shun-iwasawa 82a8f5
shared libraries.  This is accomplished by adding either `-DENABLE_STATIC=0` or
shun-iwasawa 82a8f5
`-DENABLE_SHARED=0` to the CMake command line.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. TurboJPEG API functions will now return an error code if a warning is
shun-iwasawa 82a8f5
triggered in the underlying libjpeg API.  For instance, if a JPEG file is
shun-iwasawa 82a8f5
corrupt, the TurboJPEG decompression functions will attempt to decompress
shun-iwasawa 82a8f5
as much of the image as possible, but those functions will now return -1 to
shun-iwasawa 82a8f5
indicate that the decompression was not entirely successful.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. Fixed a bug in the MIPS DSPr2 4:2:2 fancy upsampling routine that caused a
shun-iwasawa 82a8f5
buffer overflow (and subsequent segfault) when decompressing a 4:2:2 JPEG image
shun-iwasawa 82a8f5
in which the right-most MCU was 5 or 6 pixels wide.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.4.0
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.4 beta1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed a build issue on OS X PowerPC platforms (md5cmp failed to build
shun-iwasawa 82a8f5
because OS X does not provide the `le32toh()` and `htole32()` functions.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. The non-SIMD RGB565 color conversion code did not work correctly on big
shun-iwasawa 82a8f5
endian machines.  This has been fixed.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed an issue in `tjPlaneSizeYUV()` whereby it would erroneously return 1
shun-iwasawa 82a8f5
instead of -1 if `componentID` was > 0 and `subsamp` was `TJSAMP_GRAY`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed an issue in `tjBufSizeYUV2()` whereby it would erroneously return 0
shun-iwasawa 82a8f5
instead of -1 if `width` was < 1.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. The Huffman encoder now uses `clz` and `bsr` instructions for bit counting
shun-iwasawa 82a8f5
on ARM64 platforms (see 1.4 beta1[5].)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. The `close()` method in the TJCompressor and TJDecompressor Java classes is
shun-iwasawa 82a8f5
now idempotent.  Previously, that method would call the native `tjDestroy()`
shun-iwasawa 82a8f5
function even if the TurboJPEG instance had already been destroyed.  This
shun-iwasawa 82a8f5
caused an exception to be thrown during finalization, if the `close()` method
shun-iwasawa 82a8f5
had already been called.  The exception was caught, but it was still an
shun-iwasawa 82a8f5
expensive operation.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. The TurboJPEG API previously generated an error (`Could not determine
shun-iwasawa 82a8f5
subsampling type for JPEG image`) when attempting to decompress grayscale JPEG
shun-iwasawa 82a8f5
images that were compressed with a sampling factor other than 1 (for instance,
shun-iwasawa 82a8f5
with `cjpeg -grayscale -sample 2x2`).  Subsampling technically has no meaning
shun-iwasawa 82a8f5
with grayscale JPEGs, and thus the horizontal and vertical sampling factors
shun-iwasawa 82a8f5
for such images are ignored by the decompressor.  However, the TurboJPEG API
shun-iwasawa 82a8f5
was being too rigid and was expecting the sampling factors to be equal to 1
shun-iwasawa 82a8f5
before it treated the image as a grayscale JPEG.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. cjpeg, djpeg, and jpegtran now accept an argument of `-version`, which will
shun-iwasawa 82a8f5
print the library version and exit.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Referring to 1.4 beta1[15], another extremely rare circumstance was
shun-iwasawa 82a8f5
discovered under which the Huffman encoder's local buffer can be overrun
shun-iwasawa 82a8f5
when a buffered destination manager is being used and an
shun-iwasawa 82a8f5
extremely-high-frequency block (basically junk image data) is being encoded.
shun-iwasawa 82a8f5
Even though the Huffman local buffer was increased from 128 bytes to 136 bytes
shun-iwasawa 82a8f5
to address the previous issue, the new issue caused even the larger buffer to
shun-iwasawa 82a8f5
be overrun.  Further analysis reveals that, in the absolute worst case (such as
shun-iwasawa 82a8f5
setting alternating AC coefficients to 32767 and -32768 in the JPEG scanning
shun-iwasawa 82a8f5
order), the Huffman encoder can produce encoded blocks that approach double the
shun-iwasawa 82a8f5
size of the unencoded blocks.  Thus, the Huffman local buffer was increased to
shun-iwasawa 82a8f5
256 bytes, which should prevent any such issue from re-occurring in the future.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. The new `tjPlaneSizeYUV()`, `tjPlaneWidth()`, and `tjPlaneHeight()`
shun-iwasawa 82a8f5
functions were not actually usable on any platform except OS X and Windows,
shun-iwasawa 82a8f5
because those functions were not included in the libturbojpeg mapfile.  This
shun-iwasawa 82a8f5
has been fixed.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Restored the `JPP()`, `JMETHOD()`, and `FAR` macros in the libjpeg-turbo
shun-iwasawa 82a8f5
header files.  The `JPP()` and `JMETHOD()` macros were originally implemented
shun-iwasawa 82a8f5
in libjpeg as a way of supporting non-ANSI compilers that lacked support for
shun-iwasawa 82a8f5
prototype parameters.  libjpeg-turbo has never supported such compilers, but
shun-iwasawa 82a8f5
some software packages still use the macros to define their own prototypes.
shun-iwasawa 82a8f5
Similarly, libjpeg-turbo has never supported MS-DOS and other platforms that
shun-iwasawa 82a8f5
have far symbols, but some software packages still use the `FAR` macro.  A
shun-iwasawa 82a8f5
pretty good argument can be made that this is a bad practice on the part of the
shun-iwasawa 82a8f5
software in question, but since this affects more than one package, it's just
shun-iwasawa 82a8f5
easier to fix it here.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
12. Fixed issues that were preventing the ARM 64-bit SIMD code from compiling
shun-iwasawa 82a8f5
for iOS, and included an ARMv8 architecture in all of the binaries installed by
shun-iwasawa 82a8f5
the "official" libjpeg-turbo SDK for OS X.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.3.90 (1.4 beta1)
shun-iwasawa 82a8f5
==================
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.3.1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. New features in the TurboJPEG API:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
     - YUV planar images can now be generated with an arbitrary line padding
shun-iwasawa 82a8f5
(previously only 4-byte padding, which was compatible with X Video, was
shun-iwasawa 82a8f5
supported.)
shun-iwasawa 82a8f5
     - The decompress-to-YUV function has been extended to support image
shun-iwasawa 82a8f5
scaling.
shun-iwasawa 82a8f5
     - JPEG images can now be compressed from YUV planar source images.
shun-iwasawa 82a8f5
     - YUV planar images can now be decoded into RGB or grayscale images.
shun-iwasawa 82a8f5
     - 4:1:1 subsampling is now supported.  This is mainly included for
shun-iwasawa 82a8f5
compatibility, since 4:1:1 is not fully accelerated in libjpeg-turbo and has no
shun-iwasawa 82a8f5
significant advantages relative to 4:2:0.
shun-iwasawa 82a8f5
     - CMYK images are now supported.  This feature allows CMYK source images
shun-iwasawa 82a8f5
to be compressed to YCCK JPEGs and YCCK or CMYK JPEGs to be decompressed to
shun-iwasawa 82a8f5
CMYK destination images.  Conversion between CMYK/YCCK and RGB or YUV images is
shun-iwasawa 82a8f5
not supported.  Such conversion requires a color management system and is thus
shun-iwasawa 82a8f5
out of scope for a codec library.
shun-iwasawa 82a8f5
     - The handling of YUV images in the Java API has been significantly
shun-iwasawa 82a8f5
refactored and should now be much more intuitive.
shun-iwasawa 82a8f5
     - The Java API now supports encoding a YUV image from an arbitrary
shun-iwasawa 82a8f5
position in a large image buffer.
shun-iwasawa 82a8f5
     - All of the YUV functions now have a corresponding function that operates
shun-iwasawa 82a8f5
on separate image planes instead of a unified image buffer.  This allows for
shun-iwasawa 82a8f5
compressing/decoding from or decompressing/encoding to a subregion of a larger
shun-iwasawa 82a8f5
YUV image.  It also allows for handling YUV formats that swap the order of the
shun-iwasawa 82a8f5
U and V planes.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Added SIMD acceleration for DSPr2-capable MIPS platforms.  This speeds up
shun-iwasawa 82a8f5
the compression of full-color JPEGs by 70-80% on such platforms and
shun-iwasawa 82a8f5
decompression by 25-35%.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. If an application attempts to decompress a Huffman-coded JPEG image whose
shun-iwasawa 82a8f5
header does not contain Huffman tables, libjpeg-turbo will now insert the
shun-iwasawa 82a8f5
default Huffman tables.  In order to save space, many motion JPEG video frames
shun-iwasawa 82a8f5
are encoded without the default Huffman tables, so these frames can now be
shun-iwasawa 82a8f5
successfully decompressed by libjpeg-turbo without additional work on the part
shun-iwasawa 82a8f5
of the application.  An application can still override the Huffman tables, for
shun-iwasawa 82a8f5
instance to re-use tables from a previous frame of the same video.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. The Mac packaging system now uses pkgbuild and productbuild rather than
shun-iwasawa 82a8f5
PackageMaker (which is obsolete and no longer supported.)  This means that
shun-iwasawa 82a8f5
OS X 10.6 "Snow Leopard" or later must be used when packaging libjpeg-turbo,
shun-iwasawa 82a8f5
although the packages produced can be installed on OS X 10.5 "Leopard" or
shun-iwasawa 82a8f5
later.  OS X 10.4 "Tiger" is no longer supported.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. The Huffman encoder now uses `clz` and `bsr` instructions for bit counting
shun-iwasawa 82a8f5
on ARM platforms rather than a lookup table.  This reduces the memory footprint
shun-iwasawa 82a8f5
by 64k, which may be important for some mobile applications.  Out of four
shun-iwasawa 82a8f5
Android devices that were tested, two demonstrated a small overall performance
shun-iwasawa 82a8f5
loss (~3-4% on average) with ARMv6 code and a small gain (also ~3-4%) with
shun-iwasawa 82a8f5
ARMv7 code when enabling this new feature, but the other two devices
shun-iwasawa 82a8f5
demonstrated a significant overall performance gain with both ARMv6 and ARMv7
shun-iwasawa 82a8f5
code (~10-20%) when enabling the feature.  Actual mileage may vary.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Worked around an issue with Visual C++ 2010 and later that caused incorrect
shun-iwasawa 82a8f5
pixels to be generated when decompressing a JPEG image to a 256-color bitmap,
shun-iwasawa 82a8f5
if compiler optimization was enabled when libjpeg-turbo was built.  This caused
shun-iwasawa 82a8f5
the regression tests to fail when doing a release build under Visual C++ 2010
shun-iwasawa 82a8f5
and later.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Improved the accuracy and performance of the non-SIMD implementation of the
shun-iwasawa 82a8f5
floating point inverse DCT (using code borrowed from libjpeg v8a and later.)
shun-iwasawa 82a8f5
The accuracy of this implementation now matches the accuracy of the SSE/SSE2
shun-iwasawa 82a8f5
implementation.  Note, however, that the floating point DCT/IDCT algorithms are
shun-iwasawa 82a8f5
mainly a legacy feature.  They generally do not produce significantly better
shun-iwasawa 82a8f5
accuracy than the accurate integer DCT/IDCT algorithms, and they are quite a
shun-iwasawa 82a8f5
bit slower.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Added a new output colorspace (`JCS_RGB565`) to the libjpeg API that allows
shun-iwasawa 82a8f5
for decompressing JPEG images into RGB565 (16-bit) pixels.  If dithering is not
shun-iwasawa 82a8f5
used, then this code path is SIMD-accelerated on ARM platforms.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Numerous obsolete features, such as support for non-ANSI compilers and
shun-iwasawa 82a8f5
support for the MS-DOS memory model, were removed from the libjpeg code,
shun-iwasawa 82a8f5
greatly improving its readability and making it easier to maintain and extend.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. Fixed a segfault that occurred when calling `output_message()` with
shun-iwasawa 82a8f5
`msg_code` set to `JMSG_COPYRIGHT`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Fixed an issue whereby wrjpgcom was allowing comments longer than 65k
shun-iwasawa 82a8f5
characters to be passed on the command line, which was causing it to generate
shun-iwasawa 82a8f5
incorrect JPEG files.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
12. Fixed a bug in the build system that was causing the Windows version of
shun-iwasawa 82a8f5
wrjpgcom to be built using the rdjpgcom source code.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
13. Restored 12-bit-per-component JPEG support.  A 12-bit version of
shun-iwasawa 82a8f5
libjpeg-turbo can now be built by passing an argument of `--with-12bit` to
shun-iwasawa 82a8f5
configure (Unix) or `-DWITH_12BIT=1` to cmake (Windows.)  12-bit JPEG support
shun-iwasawa 82a8f5
is included only for convenience.  Enabling this feature disables all of the
shun-iwasawa 82a8f5
performance features in libjpeg-turbo, as well as arithmetic coding and the
shun-iwasawa 82a8f5
TurboJPEG API.  The resulting library still contains the other libjpeg-turbo
shun-iwasawa 82a8f5
features (such as the colorspace extensions), but in general, it performs no
shun-iwasawa 82a8f5
faster than libjpeg v6b.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
14. Added ARM 64-bit SIMD acceleration for the YCC-to-RGB color conversion
shun-iwasawa 82a8f5
and IDCT algorithms (both are used during JPEG decompression.)  For unknown
shun-iwasawa 82a8f5
reasons (probably related to clang), this code cannot currently be compiled for
shun-iwasawa 82a8f5
iOS.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
15. Fixed an extremely rare bug (CVE-2014-9092) that could cause the Huffman
shun-iwasawa 82a8f5
encoder's local buffer to overrun when a very high-frequency MCU is compressed
shun-iwasawa 82a8f5
using quality 100 and no subsampling, and when the JPEG output buffer is being
shun-iwasawa 82a8f5
dynamically resized by the destination manager.  This issue was so rare that,
shun-iwasawa 82a8f5
even with a test program specifically designed to make the bug occur (by
shun-iwasawa 82a8f5
injecting random high-frequency YUV data into the compressor), it was
shun-iwasawa 82a8f5
reproducible only once in about every 25 million iterations.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
16. Fixed an oversight in the TurboJPEG C wrapper:  if any of the JPEG
shun-iwasawa 82a8f5
compression functions was called repeatedly with the same
shun-iwasawa 82a8f5
automatically-allocated destination buffer, then TurboJPEG would erroneously
shun-iwasawa 82a8f5
assume that the `jpegSize` parameter was equal to the size of the buffer, when
shun-iwasawa 82a8f5
in fact that parameter was probably equal to the size of the most recently
shun-iwasawa 82a8f5
compressed JPEG image.  If the size of the previous JPEG image was not as large
shun-iwasawa 82a8f5
as the current JPEG image, then TurboJPEG would unnecessarily reallocate the
shun-iwasawa 82a8f5
destination buffer.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.3.1
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.3.0:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. On Un*x systems, `make install` now installs the libjpeg-turbo libraries
shun-iwasawa 82a8f5
into /opt/libjpeg-turbo/lib32 by default on any 32-bit system, not just x86,
shun-iwasawa 82a8f5
and into /opt/libjpeg-turbo/lib64 by default on any 64-bit system, not just
shun-iwasawa 82a8f5
x86-64.  You can override this by overriding either the `prefix` or `libdir`
shun-iwasawa 82a8f5
configure variables.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. The Windows installer now places a copy of the TurboJPEG DLLs in the same
shun-iwasawa 82a8f5
directory as the rest of the libjpeg-turbo binaries.  This was mainly done
shun-iwasawa 82a8f5
to support TurboVNC 1.3, which bundles the DLLs in its Windows installation.
shun-iwasawa 82a8f5
When using a 32-bit version of CMake on 64-bit Windows, it is impossible to
shun-iwasawa 82a8f5
access the c:\WINDOWS\system32 directory, which made it impossible for the
shun-iwasawa 82a8f5
TurboVNC build scripts to bundle the 64-bit TurboJPEG DLL.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed a bug whereby attempting to encode a progressive JPEG with arithmetic
shun-iwasawa 82a8f5
entropy coding (by passing arguments of `-progressive -arithmetic` to cjpeg or
shun-iwasawa 82a8f5
jpegtran, for instance) would result in an error, `Requested feature was
shun-iwasawa 82a8f5
omitted at compile time`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed a couple of issues (CVE-2013-6629 and CVE-2013-6630) whereby malformed
shun-iwasawa 82a8f5
JPEG images would cause libjpeg-turbo to use uninitialized memory during
shun-iwasawa 82a8f5
decompression.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed an error (`Buffer passed to JPEG library is too small`) that occurred
shun-iwasawa 82a8f5
when calling the TurboJPEG YUV encoding function with a very small (< 5x5)
shun-iwasawa 82a8f5
source image, and added a unit test to check for this error.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. The Java classes should now build properly under Visual Studio 2010 and
shun-iwasawa 82a8f5
later.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Fixed an issue that prevented SRPMs generated using the in-tree packaging
shun-iwasawa 82a8f5
tools from being rebuilt on certain newer Linux distributions.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Numerous minor fixes to eliminate compilation and build/packaging system
shun-iwasawa 82a8f5
warnings, fix cosmetic issues, improve documentation clarity, and other general
shun-iwasawa 82a8f5
source cleanup.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.3.0
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.3 beta1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. `make test` now works properly on FreeBSD, and it no longer requires the
shun-iwasawa 82a8f5
md5sum executable to be present on other Un*x platforms.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Overhauled the packaging system:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
     - To avoid conflict with vendor-supplied libjpeg-turbo packages, the
shun-iwasawa 82a8f5
official RPMs and DEBs for libjpeg-turbo have been renamed to
shun-iwasawa 82a8f5
"libjpeg-turbo-official".
shun-iwasawa 82a8f5
     - The TurboJPEG libraries are now located under /opt/libjpeg-turbo in the
shun-iwasawa 82a8f5
official Linux and Mac packages, to avoid conflict with vendor-supplied
shun-iwasawa 82a8f5
packages and also to streamline the packaging system.
shun-iwasawa 82a8f5
     - Release packages are now created with the directory structure defined
shun-iwasawa 82a8f5
by the configure variables `prefix`, `bindir`, `libdir`, etc. (Un\*x) or by the
shun-iwasawa 82a8f5
`CMAKE_INSTALL_PREFIX` variable (Windows.)  The exception is that the docs are
shun-iwasawa 82a8f5
always located under the system default documentation directory on Un\*x and
shun-iwasawa 82a8f5
Mac systems, and on Windows, the TurboJPEG DLL is always located in the Windows
shun-iwasawa 82a8f5
system directory.
shun-iwasawa 82a8f5
     - To avoid confusion, official libjpeg-turbo packages on Linux/Unix
shun-iwasawa 82a8f5
platforms (except for Mac) will always install the 32-bit libraries in
shun-iwasawa 82a8f5
/opt/libjpeg-turbo/lib32 and the 64-bit libraries in /opt/libjpeg-turbo/lib64.
shun-iwasawa 82a8f5
     - Fixed an issue whereby, in some cases, the libjpeg-turbo executables on
shun-iwasawa 82a8f5
Un*x systems were not properly linking with the shared libraries installed by
shun-iwasawa 82a8f5
the same package.
shun-iwasawa 82a8f5
     - Fixed an issue whereby building the "installer" target on Windows when
shun-iwasawa 82a8f5
`WITH_JAVA=1` would fail if the TurboJPEG JAR had not been previously built.
shun-iwasawa 82a8f5
     - Building the "install" target on Windows now installs files into the
shun-iwasawa 82a8f5
same places that the installer does.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed a Huffman encoder bug that prevented I/O suspension from working
shun-iwasawa 82a8f5
properly.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.2.90 (1.3 beta1)
shun-iwasawa 82a8f5
==================
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.2.1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Added support for additional scaling factors (3/8, 5/8, 3/4, 7/8, 9/8, 5/4,
shun-iwasawa 82a8f5
11/8, 3/2, 13/8, 7/4, 15/8, and 2) when decompressing.  Note that the IDCT will
shun-iwasawa 82a8f5
not be SIMD-accelerated when using any of these new scaling factors.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. The TurboJPEG dynamic library is now versioned.  It was not strictly
shun-iwasawa 82a8f5
necessary to do so, because TurboJPEG uses versioned symbols, and if a function
shun-iwasawa 82a8f5
changes in an ABI-incompatible way, that function is renamed and a legacy
shun-iwasawa 82a8f5
function is provided to maintain backward compatibility.  However, certain
shun-iwasawa 82a8f5
Linux distro maintainers have a policy against accepting any library that isn't
shun-iwasawa 82a8f5
versioned.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Extended the TurboJPEG Java API so that it can be used to compress a JPEG
shun-iwasawa 82a8f5
image from and decompress a JPEG image to an arbitrary position in a large
shun-iwasawa 82a8f5
image buffer.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. The `tjDecompressToYUV()` function now supports the `TJFLAG_FASTDCT` flag.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. The 32-bit supplementary package for amd64 Debian systems now provides
shun-iwasawa 82a8f5
symlinks in /usr/lib/i386-linux-gnu for the TurboJPEG libraries in /usr/lib32.
shun-iwasawa 82a8f5
This allows those libraries to be used on MultiArch-compatible systems (such as
shun-iwasawa 82a8f5
Ubuntu 11 and later) without setting the linker path.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. The TurboJPEG Java wrapper should now find the JNI library on Mac systems
shun-iwasawa 82a8f5
without having to pass `-Djava.library.path=/usr/lib` to java.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. TJBench has been ported to Java to provide a convenient way of validating
shun-iwasawa 82a8f5
the performance of the TurboJPEG Java API.  It can be run with
shun-iwasawa 82a8f5
`java -cp turbojpeg.jar TJBench`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. cjpeg can now be used to generate JPEG files with the RGB colorspace
shun-iwasawa 82a8f5
(feature ported from jpeg-8d.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. The width and height in the `-crop` argument passed to jpegtran can now be
shun-iwasawa 82a8f5
suffixed with `f` to indicate that, when the upper left corner of the cropping
shun-iwasawa 82a8f5
region is automatically moved to the nearest iMCU boundary, the bottom right
shun-iwasawa 82a8f5
corner should be moved by the same amount.  In other words, this feature causes
shun-iwasawa 82a8f5
jpegtran to strictly honor the specified width/height rather than the specified
shun-iwasawa 82a8f5
bottom right corner (feature ported from jpeg-8d.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. JPEG files using the RGB colorspace can now be decompressed into grayscale
shun-iwasawa 82a8f5
images (feature ported from jpeg-8d.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Fixed a regression caused by 1.2.1[7] whereby the build would fail with
shun-iwasawa 82a8f5
multiple "Mismatch in operand sizes" errors when attempting to build the x86
shun-iwasawa 82a8f5
SIMD code with NASM 0.98.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
12. The in-memory source/destination managers (`jpeg_mem_src()` and
shun-iwasawa 82a8f5
`jpeg_mem_dest()`) are now included by default when building libjpeg-turbo with
shun-iwasawa 82a8f5
libjpeg v6b or v7 emulation, so that programs can take advantage of these
shun-iwasawa 82a8f5
functions without requiring the use of the backward-incompatible libjpeg v8
shun-iwasawa 82a8f5
ABI.  The "age number" of the libjpeg-turbo library on Un*x systems has been
shun-iwasawa 82a8f5
incremented by 1 to reflect this.  You can disable this feature with a
shun-iwasawa 82a8f5
configure/CMake switch in order to retain strict API/ABI compatibility with the
shun-iwasawa 82a8f5
libjpeg v6b or v7 API/ABI (or with previous versions of libjpeg-turbo.)  See
shun-iwasawa 82a8f5
[README.md](README.md) for more details.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
13. Added ARMv7s architecture to libjpeg.a and libturbojpeg.a in the official
shun-iwasawa 82a8f5
libjpeg-turbo binary package for OS X, so that those libraries can be used to
shun-iwasawa 82a8f5
build applications that leverage the faster CPUs in the iPhone 5 and iPad 4.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.2.1
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.2.0:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Creating or decoding a JPEG file that uses the RGB colorspace should now
shun-iwasawa 82a8f5
properly work when the input or output colorspace is one of the libjpeg-turbo
shun-iwasawa 82a8f5
colorspace extensions.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. When libjpeg-turbo was built without SIMD support and merged (non-fancy)
shun-iwasawa 82a8f5
upsampling was used along with an alpha-enabled colorspace during
shun-iwasawa 82a8f5
decompression, the unused byte of the decompressed pixels was not being set to
shun-iwasawa 82a8f5
0xFF.  This has been fixed.  TJUnitTest has also been extended to test for the
shun-iwasawa 82a8f5
correct behavior of the colorspace extensions when merged upsampling is used.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Fixed a bug whereby the libjpeg-turbo SSE2 SIMD code would not preserve the
shun-iwasawa 82a8f5
upper 64 bits of xmm6 and xmm7 on Win64 platforms, which violated the Win64
shun-iwasawa 82a8f5
calling conventions.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed a regression (CVE-2012-2806) caused by 1.2.0[6] whereby decompressing
shun-iwasawa 82a8f5
corrupt JPEG images (specifically, images in which the component count was
shun-iwasawa 82a8f5
erroneously set to a large value) would cause libjpeg-turbo to segfault.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Worked around a severe performance issue with "Bobcat" (AMD Embedded APU)
shun-iwasawa 82a8f5
processors.  The `MASKMOVDQU` instruction, which was used by the libjpeg-turbo
shun-iwasawa 82a8f5
SSE2 SIMD code, is apparently implemented in microcode on AMD processors, and
shun-iwasawa 82a8f5
it is painfully slow on Bobcat processors in particular.  Eliminating the use
shun-iwasawa 82a8f5
of this instruction improved performance by an order of magnitude on Bobcat
shun-iwasawa 82a8f5
processors and by a small amount (typically 5%) on AMD desktop processors.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Added SIMD acceleration for performing 4:2:2 upsampling on NEON-capable ARM
shun-iwasawa 82a8f5
platforms.  This speeds up the decompression of 4:2:2 JPEGs by 20-25% on such
shun-iwasawa 82a8f5
platforms.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Fixed a regression caused by 1.2.0[2] whereby, on Linux/x86 platforms
shun-iwasawa 82a8f5
running the 32-bit SSE2 SIMD code in libjpeg-turbo, decompressing a 4:2:0 or
shun-iwasawa 82a8f5
4:2:2 JPEG image into a 32-bit (RGBX, BGRX, etc.) buffer without using fancy
shun-iwasawa 82a8f5
upsampling would produce several incorrect columns of pixels at the right-hand
shun-iwasawa 82a8f5
side of the output image if each row in the output image was not evenly
shun-iwasawa 82a8f5
divisible by 16 bytes.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Fixed an issue whereby attempting to build the SIMD extensions with Xcode
shun-iwasawa 82a8f5
4.3 on OS X platforms would cause NASM to return numerous errors of the form
shun-iwasawa 82a8f5
"'%define' expects a macro identifier".
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Added flags to the TurboJPEG API that allow the caller to force the use of
shun-iwasawa 82a8f5
either the fast or the accurate DCT/IDCT algorithms in the underlying codec.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.2.0
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.2 beta1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed build issue with YASM on Unix systems (the libjpeg-turbo build system
shun-iwasawa 82a8f5
was not adding the current directory to the assembler include path, so YASM
shun-iwasawa 82a8f5
was not able to find jsimdcfg.inc.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Fixed out-of-bounds read in SSE2 SIMD code that occurred when decompressing
shun-iwasawa 82a8f5
a JPEG image to a bitmap buffer whose size was not a multiple of 16 bytes.
shun-iwasawa 82a8f5
This was more of an annoyance than an actual bug, since it did not cause any
shun-iwasawa 82a8f5
actual run-time problems, but the issue showed up when running libjpeg-turbo in
shun-iwasawa 82a8f5
valgrind.  See <http: 72399="" crbug.com=""> for more information.</http:>
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Added a compile-time macro (`LIBJPEG_TURBO_VERSION`) that can be used to
shun-iwasawa 82a8f5
check the version of libjpeg-turbo against which an application was compiled.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Added new RGBA/BGRA/ABGR/ARGB colorspace extension constants (libjpeg API)
shun-iwasawa 82a8f5
and pixel formats (TurboJPEG API), which allow applications to specify that,
shun-iwasawa 82a8f5
when decompressing to a 4-component RGB buffer, the unused byte should be set
shun-iwasawa 82a8f5
to 0xFF so that it can be interpreted as an opaque alpha channel.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed regression issue whereby DevIL failed to build against libjpeg-turbo
shun-iwasawa 82a8f5
because libjpeg-turbo's distributed version of jconfig.h contained an `INLINE`
shun-iwasawa 82a8f5
macro, which conflicted with a similar macro in DevIL.  This macro is used only
shun-iwasawa 82a8f5
internally when building libjpeg-turbo, so it was moved into config.h.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. libjpeg-turbo will now correctly decompress erroneous CMYK/YCCK JPEGs whose
shun-iwasawa 82a8f5
K component is assigned a component ID of 1 instead of 4.  Although these files
shun-iwasawa 82a8f5
are in violation of the spec, other JPEG implementations handle them
shun-iwasawa 82a8f5
correctly.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Added ARMv6 and ARMv7 architectures to libjpeg.a and libturbojpeg.a in
shun-iwasawa 82a8f5
the official libjpeg-turbo binary package for OS X, so that those libraries can
shun-iwasawa 82a8f5
be used to build both OS X and iOS applications.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.1.90 (1.2 beta1)
shun-iwasawa 82a8f5
==================
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.1.1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Added a Java wrapper for the TurboJPEG API.  See [java/README](java/README)
shun-iwasawa 82a8f5
for more details.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. The TurboJPEG API can now be used to scale down images during
shun-iwasawa 82a8f5
decompression.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Added SIMD routines for RGB-to-grayscale color conversion, which
shun-iwasawa 82a8f5
significantly improves the performance of grayscale JPEG compression from an
shun-iwasawa 82a8f5
RGB source image.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Improved the performance of the C color conversion routines, which are used
shun-iwasawa 82a8f5
on platforms for which SIMD acceleration is not available.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Added a function to the TurboJPEG API that performs lossless transforms.
shun-iwasawa 82a8f5
This function is implemented using the same back end as jpegtran, but it
shun-iwasawa 82a8f5
performs transcoding entirely in memory and allows multiple transforms and/or
shun-iwasawa 82a8f5
crop operations to be batched together, so the source coefficients only need to
shun-iwasawa 82a8f5
be read once.  This is useful when generating image tiles from a single source
shun-iwasawa 82a8f5
JPEG.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Added tests for the new TurboJPEG scaled decompression and lossless
shun-iwasawa 82a8f5
transform features to tjbench (the TurboJPEG benchmark, formerly called
shun-iwasawa 82a8f5
"jpgtest".)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Added support for 4:4:0 (transposed 4:2:2) subsampling in TurboJPEG, which
shun-iwasawa 82a8f5
was necessary in order for it to read 4:2:2 JPEG files that had been losslessly
shun-iwasawa 82a8f5
transposed or rotated 90 degrees.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. All legacy VirtualGL code has been re-factored, and this has allowed
shun-iwasawa 82a8f5
libjpeg-turbo, in its entirety, to be re-licensed under a BSD-style license.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. libjpeg-turbo can now be built with YASM.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. Added SIMD acceleration for ARM Linux and iOS platforms that support
shun-iwasawa 82a8f5
NEON instructions.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
11. Refactored the TurboJPEG C API and documented it using Doxygen.  The
shun-iwasawa 82a8f5
TurboJPEG 1.2 API uses pixel formats to define the size and component order of
shun-iwasawa 82a8f5
the uncompressed source/destination images, and it includes a more efficient
shun-iwasawa 82a8f5
version of `TJBUFSIZE()` that computes a worst-case JPEG size based on the
shun-iwasawa 82a8f5
level of chrominance subsampling.  The refactored implementation of the
shun-iwasawa 82a8f5
TurboJPEG API now uses the libjpeg memory source and destination managers,
shun-iwasawa 82a8f5
which allows the TurboJPEG compressor to grow the JPEG buffer as necessary.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
12. Eliminated errors in the output of jpegtran on Windows that occurred when
shun-iwasawa 82a8f5
the application was invoked using I/O redirection
shun-iwasawa 82a8f5
(`jpegtran <input.jpg>output.jpg`.)</input.jpg>
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
13. The inclusion of libjpeg v7 and v8 emulation as well as arithmetic coding
shun-iwasawa 82a8f5
support in libjpeg-turbo v1.1.0 introduced several new error constants in
shun-iwasawa 82a8f5
jerror.h, and these were mistakenly enabled for all emulation modes, causing
shun-iwasawa 82a8f5
the error enum in libjpeg-turbo to sometimes have different values than the
shun-iwasawa 82a8f5
same enum in libjpeg.  This represents an ABI incompatibility, and it caused
shun-iwasawa 82a8f5
problems with rare applications that took specific action based on a particular
shun-iwasawa 82a8f5
error value.  The fix was to include the new error constants conditionally
shun-iwasawa 82a8f5
based on whether libjpeg v7 or v8 emulation was enabled.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
14. Fixed an issue whereby Windows applications that used libjpeg-turbo would
shun-iwasawa 82a8f5
fail to compile if the Windows system headers were included before jpeglib.h.
shun-iwasawa 82a8f5
This issue was caused by a conflict in the definition of the INT32 type.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
15. Fixed 32-bit supplementary package for amd64 Debian systems, which was
shun-iwasawa 82a8f5
broken by enhancements to the packaging system in 1.1.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
16. When decompressing a JPEG image using an output colorspace of
shun-iwasawa 82a8f5
`JCS_EXT_RGBX`, `JCS_EXT_BGRX`, `JCS_EXT_XBGR`, or `JCS_EXT_XRGB`,
shun-iwasawa 82a8f5
libjpeg-turbo will now set the unused byte to 0xFF, which allows applications
shun-iwasawa 82a8f5
to interpret that byte as an alpha channel (0xFF = opaque).
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.1.1
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.1.0:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Fixed a 1-pixel error in row 0, column 21 of the luminance plane generated
shun-iwasawa 82a8f5
by `tjEncodeYUV()`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. libjpeg-turbo's accelerated Huffman decoder previously ignored unexpected
shun-iwasawa 82a8f5
markers found in the middle of the JPEG data stream during decompression.  It
shun-iwasawa 82a8f5
will now hand off decoding of a particular block to the unaccelerated Huffman
shun-iwasawa 82a8f5
decoder if an unexpected marker is found, so that the unaccelerated Huffman
shun-iwasawa 82a8f5
decoder can generate an appropriate warning.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Older versions of MinGW64 prefixed symbol names with underscores by
shun-iwasawa 82a8f5
default, which differed from the behavior of 64-bit Visual C++.  MinGW64 1.0
shun-iwasawa 82a8f5
has adopted the behavior of 64-bit Visual C++ as the default, so to accommodate
shun-iwasawa 82a8f5
this, the libjpeg-turbo SIMD function names are no longer prefixed with an
shun-iwasawa 82a8f5
underscore when building with MinGW64.  This means that, when building
shun-iwasawa 82a8f5
libjpeg-turbo with older versions of MinGW64, you will now have to add
shun-iwasawa 82a8f5
`-fno-leading-underscore` to the `CFLAGS`.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed a regression bug in the NSIS script that caused the Windows installer
shun-iwasawa 82a8f5
build to fail when using the Visual Studio IDE.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. Fixed a bug in `jpeg_read_coefficients()` whereby it would not initialize
shun-iwasawa 82a8f5
`cinfo->image_width` and `cinfo->image_height` if libjpeg v7 or v8 emulation
shun-iwasawa 82a8f5
was enabled.  This specifically caused the jpegoptim program to fail if it was
shun-iwasawa 82a8f5
linked against a version of libjpeg-turbo that was built with libjpeg v7 or v8
shun-iwasawa 82a8f5
emulation.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. Eliminated excessive I/O overhead that occurred when reading BMP files in
shun-iwasawa 82a8f5
cjpeg.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Eliminated errors in the output of cjpeg on Windows that occurred when the
shun-iwasawa 82a8f5
application was invoked using I/O redirection (`cjpeg <inputfile>output.jpg`.)</inputfile>
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.1.0
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.1 beta1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. The algorithm used by the SIMD quantization function cannot produce correct
shun-iwasawa 82a8f5
results when the JPEG quality is >= 98 and the fast integer forward DCT is
shun-iwasawa 82a8f5
used.  Thus, the non-SIMD quantization function is now used for those cases,
shun-iwasawa 82a8f5
and libjpeg-turbo should now produce identical output to libjpeg v6b in all
shun-iwasawa 82a8f5
cases.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Despite the above, the fast integer forward DCT still degrades somewhat for
shun-iwasawa 82a8f5
JPEG qualities greater than 95, so the TurboJPEG wrapper will now automatically
shun-iwasawa 82a8f5
use the accurate integer forward DCT when generating JPEG images of quality 96
shun-iwasawa 82a8f5
or greater.  This reduces compression performance by as much as 15% for these
shun-iwasawa 82a8f5
high-quality images but is necessary to ensure that the images are perceptually
shun-iwasawa 82a8f5
lossless.  It also ensures that the library can avoid the performance pitfall
shun-iwasawa 82a8f5
created by [1].
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Ported jpgtest.cxx to pure C to avoid the need for a C++ compiler.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. Fixed visual artifacts in grayscale JPEG compression caused by a typo in
shun-iwasawa 82a8f5
the RGB-to-luminance lookup tables.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. The Windows distribution packages now include the libjpeg run-time programs
shun-iwasawa 82a8f5
(cjpeg, etc.)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. All packages now include jpgtest.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. The TurboJPEG dynamic library now uses versioned symbols.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Added two new TurboJPEG API functions, `tjEncodeYUV()` and
shun-iwasawa 82a8f5
`tjDecompressToYUV()`, to replace the somewhat hackish `TJ_YUV` flag.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.0.90 (1.1 beta1)
shun-iwasawa 82a8f5
==================
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.0.1:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. Added emulation of the libjpeg v7 and v8 APIs and ABIs.  See
shun-iwasawa 82a8f5
[README.md](README.md) for more details.  This feature was sponsored by
shun-iwasawa 82a8f5
CamTrace SAS.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Created a new CMake-based build system for the Visual C++ and MinGW builds.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. Grayscale bitmaps can now be compressed from/decompressed to using the
shun-iwasawa 82a8f5
TurboJPEG API.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
4. jpgtest can now be used to test decompression performance with existing
shun-iwasawa 82a8f5
JPEG images.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
5. If the default install prefix (/opt/libjpeg-turbo) is used, then
shun-iwasawa 82a8f5
`make install` now creates /opt/libjpeg-turbo/lib32 and
shun-iwasawa 82a8f5
/opt/libjpeg-turbo/lib64 sym links to duplicate the behavior of the binary
shun-iwasawa 82a8f5
packages.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
6. All symbols in the libjpeg-turbo dynamic library are now versioned, even
shun-iwasawa 82a8f5
when the library is built with libjpeg v6b emulation.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
7. Added arithmetic encoding and decoding support (can be disabled with
shun-iwasawa 82a8f5
configure or CMake options)
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
8. Added a `TJ_YUV` flag to the TurboJPEG API, which causes both the compressor
shun-iwasawa 82a8f5
and decompressor to output planar YUV images.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
9. Added an extended version of `tjDecompressHeader()` to the TurboJPEG API,
shun-iwasawa 82a8f5
which allows the caller to determine the type of subsampling used in a JPEG
shun-iwasawa 82a8f5
image.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
10. Added further protections against invalid Huffman codes.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1.0.1
shun-iwasawa 82a8f5
=====
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
### Significant changes relative to 1.0.0:
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
1. The Huffman decoder will now handle erroneous Huffman codes (for instance,
shun-iwasawa 82a8f5
from a corrupt JPEG image.)  Previously, these would cause libjpeg-turbo to
shun-iwasawa 82a8f5
crash under certain circumstances.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
2. Fixed typo in SIMD dispatch routines that was causing 4:2:2 upsampling to
shun-iwasawa 82a8f5
be used instead of 4:2:0 when decompressing JPEG images using SSE2 code.
shun-iwasawa 82a8f5
shun-iwasawa 82a8f5
3. The configure script will now automatically determine whether the
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`INCOMPLETE_TYPES_BROKEN` macro should be defined.
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1.0.0
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=====
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### Significant changes relative to 0.0.93:
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1. 2983700: Further FreeBSD build tweaks (no longer necessary to specify
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`--host` when configuring on a 64-bit system)
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2. Created symlinks in the Unix/Linux packages so that the TurboJPEG
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include file can always be found in /opt/libjpeg-turbo/include, the 32-bit
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static libraries can always be found in /opt/libjpeg-turbo/lib32, and the
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64-bit static libraries can always be found in /opt/libjpeg-turbo/lib64.
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3. The Unix/Linux distribution packages now include the libjpeg run-time
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programs (cjpeg, etc.) and man pages.
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4. Created a 32-bit supplementary package for amd64 Debian systems, which
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contains just the 32-bit libjpeg-turbo libraries.
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5. Moved the libraries from */lib32 to */lib in the i386 Debian package.
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6. Include distribution package for Cygwin
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7. No longer necessary to specify `--without-simd` on non-x86 architectures,
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and unit tests now work on those architectures.
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0.0.93
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======
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### Significant changes since 0.0.91:
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1. 2982659: Fixed x86-64 build on FreeBSD systems
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2. 2988188: Added support for Windows 64-bit systems
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0.0.91
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======
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### Significant changes relative to 0.0.90:
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1. Added documentation to .deb packages
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2. 2968313: Fixed data corruption issues when decompressing large JPEG images
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and/or using buffered I/O with the libjpeg-turbo decompressor
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0.0.90
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======
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Initial release