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fc01f4673b71c0b833c59c21e8c4478a9c4bcf21
mozjpeg/java/org/libjpegturbo/turbojpeg/TJ.java
DRC fc01f4673b TurboJPEG 3 API overhaul 
(ChangeLog update forthcoming)

- Prefix all function names with "tj3" and remove version suffixes from
  function names.  (Future API overhauls will increment the prefix to
  "tj4", etc., thus retaining backward API/ABI compatibility without
  versioning each individual function.)

- Replace stateless boolean flags (including TJ*FLAG_ARITHMETIC and
  TJ*FLAG_LOSSLESS, which were never released) with stateful integer
  parameters, the value of which persists between function calls.
  * Use parameters for the JPEG quality and subsampling as well, in
    order to eliminate the awkwardness of specifying function arguments
    that weren't relevant for lossless compression.
  * tj3DecompressHeader() now stores all relevant information about the
    JPEG image, including the width, height, subsampling type, entropy
    coding type, etc. in parameters rather than returning that
    information in its arguments.
  * TJ*FLAG_LIMITSCANS has been reimplemented as an integer parameter
    (TJ*PARAM_SCANLIMIT) that allows the number of scans to be
    specified.

- Use the const keyword for all pointer arguments to unmodified
  buffers, as well as for both dimensions of 2D pointers.  Addresses
  #395.

- Use size_t rather than unsigned long to represent buffer sizes, since
  unsigned long is a 32-bit type on Windows.  Addresses #24.

- Return 0 from all buffer size functions if an error occurs, rather
  than awkwardly trying to return -1 in an unsigned data type.

- Implement 12-bit and 16-bit data precision using dedicated
  compression, decompression, and image I/O functions/methods.
  * Suffix the names of all data-precision-specific functions with 8,
    12, or 16.
  * Because the YUV functions are intended to be used for video, they
    are currently only implemented with 8-bit data precision, but they
    can be expanded to 12-bit data precision in the future, if
    necessary.
  * Extend TJUnitTest and TJBench to test 12-bit and 16-bit data
    precision, using a new -precision option.
  * Add appropriate regression tests for all of the above to the 'test'
    target.
  * Extend tjbenchtest to test 12-bit and 16-bit data precision, and
    add separate 'tjtest12' and 'tjtest16' targets.
  * BufferedImage I/O in the Java API is currently limited to 8-bit
    data precision, since the BufferedImage class does not
    straightforwardly support higher data precisions.
  * Extend the PPM reader to convert 12-bit and 16-bit PBMPLUS files
    to grayscale or CMYK pixels, as it already does for 8-bit files.

- Properly accommodate lossless JPEG using dedicated parameters
  (TJ*PARAM_LOSSLESS, TJ*PARAM_LOSSLESSPSV, and TJ*PARAM_LOSSLESSPT),
  rather than using a flag and awkwardly repurposing the JPEG quality.
  Update TJBench to properly reflect whether a JPEG image is lossless.

- Re-organize the TJBench usage screen.

- Update the Java docs using Java 11, to improve the formatting and
  eliminate HTML frames.

- Use the accurate integer DCT algorithm by default for both
  compression and decompression, since the "fast" algorithm is a legacy
  feature, it does not pass the ISO compliance tests, and it is not
  actually faster on modern x86 CPUs.
  * Remove the -accuratedct option from TJBench and TJExample.

- Re-implement the 'tjtest' target using a CMake script that enables
  the appropriate tests, depending on the data precision and whether or
  not the Java API is part of the build.

- Consolidate the C and Java versions of tjbenchtest into one script.

- Consolidate the C and Java versions of tjexampletest into one script.

- Combine all initialization functions into a single function
  (tj3Init()) that accepts an integer parameter specifying the
  subsystems to initialize.

- Enable decompression scaling explicitly, using a new function/method
  (tj3SetScalingFactor()/TJDecompressor.setScalingFactor()), rather
  than implicitly using awkward "desired width"/"desired height"
  parameters.

- Introduce a new macro/constant (TJUNSCALED/TJ.UNSCALED) that maps to
  a scaling factor of 1/1.

- Implement partial image decompression, using a new function/method
  (tj3SetCroppingRegion()/TJDecompressor.setCroppingRegion()) and
  TJBench option (-crop).  Extend tjbenchtest to test the new feature.
  Addresses #1.

- Allow the JPEG colorspace to be specified explicitly when
  compressing, using a new parameter (TJ*PARAM_COLORSPACE).  This
  allows JPEG images with the RGB and CMYK colorspaces to be created.

- Remove the error/difference image feature from TJBench.  Identical
  images to the ones that TJBench created can be generated using
  ImageMagick with
  'magick composite <original_image> <output_image> -compose difference <diff_image>'

- Handle JPEG images with unknown subsampling types.  TJ*PARAM_SUBSAMP
  is set to TJ*SAMP_UNKNOWN (== -1) for such images, but they can still
  be decompressed fully into packed-pixel images or losslessly
  transformed (with the exception of lossless cropping.)  They cannot
  be partially decompressed or decompressed into planar YUV images.
  Note also that TJBench, due to its lack of support for imperfect
  transforms, requires that the subsampling type be known when
  rotating, flipping, or transversely transposing an image.  Addresses
  #436

- The Java version of TJBench now has identical functionality to the C
  version.  This was accomplished by (somewhat hackishly) calling the
  TurboJPEG C image I/O functions through JNI and copying the pixels
  between the C heap and the Java heap.

- Add parameters (TJ*PARAM_RESTARTROWS and TJ*PARAM_RESTARTBLOCKS) and
  a TJBench option (-restart) to allow the restart marker interval to
  be specified when compressing.  Eliminate the undocumented TJ_RESTART
  environment variable.

- Add a parameter (TJ*PARAM_OPTIMIZE), a transform option
  (TJ*OPT_OPTIMIZE), and a TJBench option (-optimize) to allow
  optimized baseline Huffman coding to be specified when compressing.
  Eliminate the undocumented TJ_OPTIMIZE environment variable.

- Add parameters (TJ*PARAM_XDENSITY, TJ*PARAM_DENSITY, and
  TJ*DENSITYUNITS) to allow the pixel density to be specified when
  compressing or saving a Windows BMP image and to be queried when
  decompressing or loading a Windows BMP image.  Addresses #77.

- Refactor the fuzz targets to use the new API.
  * Extend decompression coverage to 12-bit and 16-bit data precision.
  * Replace the awkward cjpeg12 and cjpeg16 targets with proper
    TurboJPEG-based compress12, compress12-lossless, and
    compress16-lossless targets

- Fix innocuous UBSan warnings uncovered by the new fuzzers.

- Implement previous versions of the TurboJPEG API by wrapping the new
  functions (tested by running the 2.1.x versions of TJBench, via
  tjbenchtest, and TJUnitTest against the new implementation.)
  * Remove all JNI functions for deprecated Java methods and implement
    the deprecated methods using pure Java wrappers.  It should be
    understood that backward API compatibility in Java applies only to
    the Java classes and that one cannot mix and match a JAR file from
    one version of libjpeg-turbo with a JNI library from another
    version.

- tj3Destroy() now silently accepts a NULL handle.

- tj3Alloc() and tj3Free() now return/accept void pointers, as malloc()
  and free() do.

- The image I/O functions now accept a TurboJPEG instance handle, which
  is used to transmit/receive parameters and to receive error
  information.

Closes #517
2023-01-25 19:09:34 -06:00

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/*
* Copyright (C)2011-2013, 2017-2018, 2020-2023 D. R. Commander.
* All Rights Reserved.
* Copyright (C)2015 Viktor Szathmáry. All Rights Reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* - Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
* - Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
* - Neither the name of the libjpeg-turbo Project nor the names of its
* contributors may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS",
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
package org.libjpegturbo.turbojpeg;
import java.awt.Rectangle;
/**
* TurboJPEG utility class (cannot be instantiated)
*/
public final class TJ {
private TJ() {}
/**
* The number of chrominance subsampling options
*/
public static final int NUMSAMP = 6;
/**
* 4:4:4 chrominance subsampling (no chrominance subsampling). The JPEG
* or YUV image will contain one chrominance component for every pixel in the
* source image.
*/
public static final int SAMP_444 = 0;
/**
* 4:2:2 chrominance subsampling. The JPEG or YUV image will contain one
* chrominance component for every 2x1 block of pixels in the source image.
*/
public static final int SAMP_422 = 1;
/**
* 4:2:0 chrominance subsampling. The JPEG or YUV image will contain one
* chrominance component for every 2x2 block of pixels in the source image.
*/
public static final int SAMP_420 = 2;
/**
* Grayscale. The JPEG or YUV image will contain no chrominance components.
*/
public static final int SAMP_GRAY = 3;
/**
* 4:4:0 chrominance subsampling. The JPEG or YUV image will contain one
* chrominance component for every 1x2 block of pixels in the source image.
* Note that 4:4:0 subsampling is not fully accelerated in libjpeg-turbo.
*/
public static final int SAMP_440 = 4;
/**
* 4:1:1 chrominance subsampling. The JPEG or YUV image will contain one
* chrominance component for every 4x1 block of pixels in the source image.
* JPEG images compressed with 4:1:1 subsampling will be almost exactly the
* same size as those compressed with 4:2:0 subsampling, and in the
* aggregate, both subsampling methods produce approximately the same
* perceptual quality. However, 4:1:1 is better able to reproduce sharp
* horizontal features. Note that 4:1:1 subsampling is not fully accelerated
* in libjpeg-turbo.
*/
public static final int SAMP_411 = 5;
/**
* Unknown subsampling. The JPEG image uses an unusual type of chrominance
* subsampling. Such images can be decompressed into packed-pixel images,
* but they cannot be
* <ul>
* <li> decompressed into planar YUV images,
* <li> losslessly transformed if {@link TJTransform#OPT_CROP} is specified,
* or
* <li> partially decompressed using a cropping region.
* </ul>
*/
public static final int SAMP_UNKNOWN = -1;
/**
* Returns the MCU block width for the given level of chrominance
* subsampling.
*
* @param subsamp the level of chrominance subsampling (one of
* {@link #SAMP_444 SAMP_*})
*
* @return the MCU block width for the given level of chrominance
* subsampling.
*/
public static int getMCUWidth(int subsamp) {
checkSubsampling(subsamp);
return MCU_WIDTH[subsamp];
}
private static final int[] MCU_WIDTH = {
8, 16, 16, 8, 8, 32
};
/**
* Returns the MCU block height for the given level of chrominance
* subsampling.
*
* @param subsamp the level of chrominance subsampling (one of
* {@link #SAMP_444 SAMP_*})
*
* @return the MCU block height for the given level of chrominance
* subsampling.
*/
public static int getMCUHeight(int subsamp) {
checkSubsampling(subsamp);
return MCU_HEIGHT[subsamp];
}
private static final int[] MCU_HEIGHT = {
8, 8, 16, 8, 16, 8
};
/**
* The number of pixel formats
*/
public static final int NUMPF = 12;
/**
* RGB pixel format. The red, green, and blue components in the image are
* stored in 3-sample pixels in the order R, G, B from lowest to highest
* memory address within each pixel.
*/
public static final int PF_RGB = 0;
/**
* BGR pixel format. The red, green, and blue components in the image are
* stored in 3-sample pixels in the order B, G, R from lowest to highest
* memory address within each pixel.
*/
public static final int PF_BGR = 1;
/**
* RGBX pixel format. The red, green, and blue components in the image are
* stored in 4-sample pixels in the order R, G, B from lowest to highest
* memory address within each pixel. The X component is ignored when
* compressing and undefined when decompressing.
*/
public static final int PF_RGBX = 2;
/**
* BGRX pixel format. The red, green, and blue components in the image are
* stored in 4-sample pixels in the order B, G, R from lowest to highest
* memory address within each pixel. The X component is ignored when
* compressing and undefined when decompressing.
*/
public static final int PF_BGRX = 3;
/**
* XBGR pixel format. The red, green, and blue components in the image are
* stored in 4-sample pixels in the order R, G, B from highest to lowest
* memory address within each pixel. The X component is ignored when
* compressing and undefined when decompressing.
*/
public static final int PF_XBGR = 4;
/**
* XRGB pixel format. The red, green, and blue components in the image are
* stored in 4-sample pixels in the order B, G, R from highest to lowest
* memory address within each pixel. The X component is ignored when
* compressing and undefined when decompressing.
*/
public static final int PF_XRGB = 5;
/**
* Grayscale pixel format. Each 1-sample pixel represents a luminance
* (brightness) level from 0 to the maximum sample value (255 for 8-bit
* samples, 4095 for 12-bit samples, and 65535 for 16-bit samples.)
*/
public static final int PF_GRAY = 6;
/**
* RGBA pixel format. This is the same as {@link #PF_RGBX}, except that when
* decompressing, the X component is guaranteed to be equal to the maximum
* sample value, which can be interpreted as an opaque alpha channel.
*/
public static final int PF_RGBA = 7;
/**
* BGRA pixel format. This is the same as {@link #PF_BGRX}, except that when
* decompressing, the X component is guaranteed to be equal to the maximum
* sample value, which can be interpreted as an opaque alpha channel.
*/
public static final int PF_BGRA = 8;
/**
* ABGR pixel format. This is the same as {@link #PF_XBGR}, except that when
* decompressing, the X component is guaranteed to be equal to the maximum
* sample value, which can be interpreted as an opaque alpha channel.
*/
public static final int PF_ABGR = 9;
/**
* ARGB pixel format. This is the same as {@link #PF_XRGB}, except that when
* decompressing, the X component is guaranteed to be equal to the maximum
* sample value, which can be interpreted as an opaque alpha channel.
*/
public static final int PF_ARGB = 10;
/**
* CMYK pixel format. Unlike RGB, which is an additive color model used
* primarily for display, CMYK (Cyan/Magenta/Yellow/Key) is a subtractive
* color model used primarily for printing. In the CMYK color model, the
* value of each color component typically corresponds to an amount of cyan,
* magenta, yellow, or black ink that is applied to a white background. In
* order to convert between CMYK and RGB, it is necessary to use a color
* management system (CMS.) A CMS will attempt to map colors within the
* printer's gamut to perceptually similar colors in the display's gamut and
* vice versa, but the mapping is typically not 1:1 or reversible, nor can it
* be defined with a simple formula. Thus, such a conversion is out of scope
* for a codec library. However, the TurboJPEG API allows for compressing
* packed-pixel CMYK images into YCCK JPEG images (see {@link #CS_YCCK}) and
* decompressing YCCK JPEG images into packed-pixel CMYK images.
*/
public static final int PF_CMYK = 11;
/**
* Returns the pixel size (in samples) for the given pixel format.
*
* @param pixelFormat the pixel format (one of {@link #PF_RGB PF_*})
*
* @return the pixel size (in samples) for the given pixel format.
*/
public static int getPixelSize(int pixelFormat) {
checkPixelFormat(pixelFormat);
return PIXEL_SIZE[pixelFormat];
}
private static final int[] PIXEL_SIZE = {
3, 3, 4, 4, 4, 4, 1, 4, 4, 4, 4, 4
};
/**
* For the given pixel format, returns the number of samples that the red
* component is offset from the start of the pixel. For instance, if an
* 8-bit-per-sample pixel of format <code>TJ.PF_BGRX</code> is stored in
* <code>char pixel[]</code>, then the red component will be
* <code>pixel[TJ.getRedOffset(TJ.PF_BGRX)]</code>.
*
* @param pixelFormat the pixel format (one of {@link #PF_RGB PF_*})
*
* @return the red offset for the given pixel format, or -1 if the pixel
* format does not have a red component.
*/
public static int getRedOffset(int pixelFormat) {
checkPixelFormat(pixelFormat);
return RED_OFFSET[pixelFormat];
}
private static final int[] RED_OFFSET = {
0, 2, 0, 2, 3, 1, -1, 0, 2, 3, 1, -1
};
/**
* For the given pixel format, returns the number of samples that the green
* component is offset from the start of the pixel. For instance, if an
* 8-bit-per-sample pixel of format <code>TJ.PF_BGRX</code> is stored in
* <code>char pixel[]</code>, then the green component will be
* <code>pixel[TJ.getGreenOffset(TJ.PF_BGRX)]</code>.
*
* @param pixelFormat the pixel format (one of {@link #PF_RGB PF_*})
*
* @return the green offset for the given pixel format, or -1 if the pixel
* format does not have a green component.
*/
public static int getGreenOffset(int pixelFormat) {
checkPixelFormat(pixelFormat);
return GREEN_OFFSET[pixelFormat];
}
private static final int[] GREEN_OFFSET = {
1, 1, 1, 1, 2, 2, -1, 1, 1, 2, 2, -1
};
/**
* For the given pixel format, returns the number of samples that the blue
* component is offset from the start of the pixel. For instance, if an
* 8-bit-per-sample pixel of format <code>TJ.PF_BGRX</code> is stored in
* <code>char pixel[]</code>, then the blue component will be
* <code>pixel[TJ.getBlueOffset(TJ.PF_BGRX)]</code>.
*
* @param pixelFormat the pixel format (one of {@link #PF_RGB PF_*})
*
* @return the blue offset for the given pixel format, or -1 if the pixel
* format does not have a blue component.
*/
public static int getBlueOffset(int pixelFormat) {
checkPixelFormat(pixelFormat);
return BLUE_OFFSET[pixelFormat];
}
private static final int[] BLUE_OFFSET = {
2, 0, 2, 0, 1, 3, -1, 2, 0, 1, 3, -1
};
/**
* For the given pixel format, returns the number of samples that the alpha
* component is offset from the start of the pixel. For instance, if an
* 8-bit-per-sample pixel of format <code>TJ.PF_BGRA</code> is stored in
* <code>char pixel[]</code>, then the alpha component will be
* <code>pixel[TJ.getAlphaOffset(TJ.PF_BGRA)]</code>.
*
* @param pixelFormat the pixel format (one of {@link #PF_RGB PF_*})
*
* @return the alpha offset for the given pixel format, or -1 if the pixel
* format does not have a alpha component.
*/
public static int getAlphaOffset(int pixelFormat) {
checkPixelFormat(pixelFormat);
return ALPHA_OFFSET[pixelFormat];
}
private static final int[] ALPHA_OFFSET = {
-1, -1, -1, -1, -1, -1, -1, 3, 3, 0, 0, -1
};
/**
* The number of JPEG colorspaces
*/
public static final int NUMCS = 5;
/**
* RGB colorspace. When compressing the JPEG image, the R, G, and B
* components in the source image are reordered into image planes, but no
* colorspace conversion or subsampling is performed. RGB JPEG images can be
* compressed from and decompressed to packed-pixel images with any of the
* extended RGB or grayscale pixel formats, but they cannot be compressed
* from or decompressed to planar YUV images.
*/
public static final int CS_RGB = 0;
/**
* YCbCr colorspace. YCbCr is not an absolute colorspace but rather a
* mathematical transformation of RGB designed solely for storage and
* transmission. YCbCr images must be converted to RGB before they can
* actually be displayed. In the YCbCr colorspace, the Y (luminance)
* component represents the black &amp; white portion of the original image,
* and the Cb and Cr (chrominance) components represent the color portion of
* the original image. Originally, the analog equivalent of this
* transformation allowed the same signal to drive both black &amp; white and
* color televisions, but JPEG images use YCbCr primarily because it allows
* the color data to be optionally subsampled for the purposes of reducing
* network or disk usage. YCbCr is the most common JPEG colorspace, and
* YCbCr JPEG images can be compressed from and decompressed to packed-pixel
* images with any of the extended RGB or grayscale pixel formats. YCbCr
* JPEG images can also be compressed from and decompressed to planar YUV
* images.
*/
@SuppressWarnings("checkstyle:ConstantName")
public static final int CS_YCbCr = 1;
/**
* Grayscale colorspace. The JPEG image retains only the luminance data (Y
* component), and any color data from the source image is discarded.
* Grayscale JPEG images can be compressed from and decompressed to
* packed-pixel images with any of the extended RGB or grayscale pixel
* formats, or they can be compressed from and decompressed to planar YUV
* images.
*/
public static final int CS_GRAY = 2;
/**
* CMYK colorspace. When compressing the JPEG image, the C, M, Y, and K
* components in the source image are reordered into image planes, but no
* colorspace conversion or subsampling is performed. CMYK JPEG images can
* only be compressed from and decompressed to packed-pixel images with the
* CMYK pixel format.
*/
public static final int CS_CMYK = 3;
/**
* YCCK colorspace. YCCK (AKA "YCbCrK") is not an absolute colorspace but
* rather a mathematical transformation of CMYK designed solely for storage
* and transmission. It is to CMYK as YCbCr is to RGB. CMYK pixels can be
* reversibly transformed into YCCK, and as with YCbCr, the chrominance
* components in the YCCK pixels can be subsampled without incurring major
* perceptual loss. YCCK JPEG images can only be compressed from and
* decompressed to packed-pixel images with the CMYK pixel format.
*/
public static final int CS_YCCK = 4;
/**
* Error handling behavior
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default]</i> Allow the current
* compression/decompression/transform operation to complete unless a fatal
* error is encountered.
* <li> <code>1</code> Immediately discontinue the current
* compression/decompression/transform operation if a warning (non-fatal
* error) occurs.
* </ul>
*/
public static final int PARAM_STOPONWARNING = 0;
/**
* Row order in packed-pixel source/destination images
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default]</i> top-down (X11) order
* <li> <code>1</code> bottom-up (Windows, OpenGL) order
* </ul>
*/
public static final int PARAM_BOTTOMUP = 1;
/**
* Perceptual quality of lossy JPEG images [compression only]
*
* <p><b>Value</b>
* <ul>
* <li> <code>1</code>-<code>100</code> (<code>1</code> = worst quality but
* best compression, <code>100</code> = best quality but worst compression)
* <i>[no default; must be explicitly specified]</i>
* </ul>
*/
public static final int PARAM_QUALITY = 3;
/**
* Chrominance subsampling level
*
* <p>The JPEG or YUV image uses (decompression, decoding) or will use (lossy
* compression, encoding) the specified level of chrominance subsampling.
*
* <p>When pixels are converted from RGB to YCbCr (see {@link #CS_YCbCr}) or
* from CMYK to YCCK (see {@link #CS_YCCK}) as part of the JPEG compression
* process, some of the Cb and Cr (chrominance) components can be discarded
* or averaged together to produce a smaller image with little perceptible
* loss of image clarity. (The human eye is more sensitive to small changes
* in brightness than to small changes in color.) This is called
* "chrominance subsampling".
*
* <p><b>Value</b>
* <ul>
* <li> One of {@link TJ#SAMP_444 TJ.SAMP_*} <i>[no default; must be
* explicitly specified for lossy compression, encoding, and decoding]</i>
* </ul>
*/
public static final int PARAM_SUBSAMP = 4;
/**
* JPEG width (in pixels) [decompression only, read-only]
*/
public static final int PARAM_JPEGWIDTH = 5;
/**
* JPEG height (in pixels) [decompression only, read-only]
*/
public static final int PARAM_JPEGHEIGHT = 6;
/**
* JPEG data precision (bits per sample) [decompression only, read-only]
*
* <p>The JPEG image uses the specified number of bits per sample.
*
* <p><b>Value</b>
* <ul>
* <li> <code>8</code>, <code>12</code>, or <code>16</code>
* </ul>
*
* <p>12-bit data precision implies {@link #PARAM_OPTIMIZE}.
*/
public static final int PARAM_PRECISION = 7;
/**
* JPEG colorspace
*
* <p>The JPEG image uses (decompression) or will use (lossy compression) the
* specified colorspace.
*
* <p><b>Value</b>
* <ul>
* <li> One of {@link TJ#CS_RGB TJ.CS_*} <i>[default for lossy compression:
* automatically selected based on the subsampling level and pixel
* format]</i>
* </ul>
*/
public static final int PARAM_COLORSPACE = 8;
/**
* Chrominance upsampling algorithm [lossy decompression only]
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default]</i> Use smooth upsampling when
* decompressing a JPEG image that was compressed using chrominance
* subsampling. This creates a smooth transition between neighboring
* chrominance components in order to reduce upsampling artifacts in the
* decompressed image.
* <li> <code>1</code> Use the fastest chrominance upsampling algorithm
* available, which may combine upsampling with color conversion.
* </ul>
*/
public static final int PARAM_FASTUPSAMPLE = 9;
/**
* DCT/IDCT algorithm [lossy compression and decompression]
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default]</i> Use the most accurate DCT/IDCT
* algorithm available.
* <li> <code>1</code> Use the fastest DCT/IDCT algorithm available.
* </ul>
*
* <p>This parameter is provided mainly for backward compatibility with
* libjpeg, which historically implemented several different DCT/IDCT
* algorithms because of performance limitations with 1990s CPUs. In the
* libjpeg-turbo implementation of the TurboJPEG API:
*
* <ul>
* <li> The "fast" and "accurate" DCT/IDCT algorithms perform similarly on
* modern x86/x86-64 CPUs that support AVX2 instructions.
* <li> The "fast" algorithm is generally only about 5-15% faster than the
* "accurate" algorithm on other types of CPUs.
* <li> The difference in accuracy between the "fast" and "accurate"
* algorithms is the most pronounced at JPEG quality levels above 90 and
* tends to be more pronounced with decompression than with compression.
* <li> The "fast" algorithm degrades and is not fully accelerated for JPEG
* quality levels above 97, so it will be slower than the "accurate"
* algorithm.
* </ul>
*/
public static final int PARAM_FASTDCT = 10;
/**
* Optimized baseline entropy coding [lossy compression only]
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default]</i> The JPEG image will use the default
* Huffman tables.
* <li> <code>1</code> Optimal Huffman tables will be computed for the JPEG
* image. For lossless transformation, this can also be specified using
* {@link TJTransform#OPT_OPTIMIZE}.
* </ul>
*
* <p>Optimized baseline entropy coding will improve compression slightly
* (generally 5% or less), but it will reduce compression performance
* considerably.
*/
public static final int PARAM_OPTIMIZE = 11;
/**
* Progressive entropy coding
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default for compression, lossless
* transformation]</i> The lossy JPEG image uses (decompression) or will use
* (compression, lossless transformation) baseline entropy coding.
* <li> <code>1</code> The lossy JPEG image uses (decompression) or will use
* (compression, lossless transformation) progressive entropy coding. For
* lossless transformation, this can also be specified using
* {@link TJTransform#OPT_PROGRESSIVE}.
* </ul>
*
* <p>Progressive entropy coding will generally improve compression relative
* to baseline entropy coding, but it will reduce compression and
* decompression performance considerably. Implies {@link #PARAM_OPTIMIZE}.
* Can be combined with {@link #PARAM_ARITHMETIC}.
*/
public static final int PARAM_PROGRESSIVE = 12;
/**
* Progressive JPEG scan limit for lossy JPEG images [decompression, lossless
* transformation]
*
* <p>Setting this parameter will cause the decompression and transform
* functions to return an error if the number of scans in a progressive JPEG
* image exceeds the specified limit. The primary purpose of this is to
* allow security-critical applications to guard against an exploit of the
* progressive JPEG format described in
* <a href="https://libjpeg-turbo.org/pmwiki/uploads/About/TwoIssueswiththeJPEGStandard.pdf" target="_blank">this report</a>.
*
* <p><b>Value</b>
* <ul>
* <li> maximum number of progressive JPEG scans that the decompression and
* transform functions will process <i>[default: <code>0</code> (no
* limit)]</i>
* </ul>
*
* @see #PARAM_PROGRESSIVE
*/
public static final int PARAM_SCANLIMIT = 13;
/**
* Arithmetic entropy coding
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default for compression, lossless
* transformation]</i> The lossy JPEG image uses (decompression) or will use
* (compression, lossless transformation) Huffman entropy coding.
* <li> <code>1</code> The lossy JPEG image uses (decompression) or will use
* (compression, lossless transformation) arithmetic entropy coding. For
* lossless transformation, this can also be specified using
* {@link TJTransform#OPT_ARITHMETIC}.
* </ul>
*
* <p>Arithmetic entropy coding will generally improve compression relative
* to Huffman entropy coding, but it will reduce compression and
* decompression performance considerably. Can be combined with
* {@link #PARAM_PROGRESSIVE}. Arithmetic entropy coding is currently only
* implemented for 8-bit samples.
*/
public static final int PARAM_ARITHMETIC = 14;
/**
* Lossless JPEG
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default for compression]</i> The JPEG image is
* (decompression) or will be (compression) lossy/DCT-based.
* <li> <code>1</code> The JPEG image is (decompression) or will be
* (compression) lossless/predictive.
* </ul>
*
* <p>In most cases, compressing and decompressing lossless JPEG images is
* considerably slower than compressing and decompressing lossy JPEG images.
* Also note that the following features are not available with lossless JPEG
* images:
* <ul>
* <li> Colorspace conversion (lossless JPEG images always use
* {@link #CS_RGB}, {@link #CS_GRAY}, or {@link #CS_CMYK}, depending on the
* pixel format of the source image)
* <li> Chrominance subsampling (lossless JPEG images always use
* {@link #SAMP_444})
* <li> JPEG quality selection
* <li> DCT/IDCT algorithm selection
* <li> Progressive entropy coding
* <li> Arithmetic entropy coding
* <li> Compression from/decompression to planar YUV images
* <li> Decompression scaling
* <li> Lossless transformation
* </ul>
*
* @see #PARAM_LOSSLESSPSV
* @see #PARAM_LOSSLESSPT
*/
public static final int PARAM_LOSSLESS = 15;
/**
* Lossless JPEG predictor selection value (PSV)
*
* <p><b>Value</b>
* <ul>
* <li> <code>1</code>-<code>7</code> <i>[default for compression:
* <code>1</code>]</i>
* </ul>
*
* @see #PARAM_LOSSLESS
*/
public static final int PARAM_LOSSLESSPSV = 16;
/**
* Lossless JPEG point transform (Pt)
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> through <i><b>precision</b> - 1</i>, where
* <b><i>precision</i></b> is the JPEG data precision in bits <i>[default for
* compression: <code>0</code>]</i>
* </ul>
*
* <p>A point transform value of <code>0</code> is necessary in order to
* generate a fully lossless JPEG image. (A non-zero point transform value
* right-shifts the input samples by the specified number of bits, which is
* effectively a form of lossy color quantization.)
*
* @see #PARAM_LOSSLESS
* @see #PARAM_PRECISION
*/
public static final int PARAM_LOSSLESSPT = 17;
/**
* JPEG restart marker interval in MCU blocks (lossy) or samples (lossless)
* [compression only]
*
* <p>The nature of entropy coding is such that a corrupt JPEG image cannot
* be decompressed beyond the point of corruption unless it contains restart
* markers. A restart marker stops and restarts the entropy coding algorithm
* so that, if a JPEG image is corrupted, decompression can resume at the
* next marker. Thus, adding more restart markers improves the fault
* tolerance of the JPEG image, but adding too many restart markers can
* adversely affect the compression ratio and performance.
*
* <p><b>Value</b>
* <ul>
* <li> the number of MCU blocks or samples between each restart marker
* <i>[default: <code>0</code> (no restart markers)]</i>
* </ul>
*
* <p> Setting this parameter to a non-zero value sets
* {@link #PARAM_RESTARTROWS} to 0.
*/
public static final int PARAM_RESTARTBLOCKS = 18;
/**
* JPEG restart marker interval in MCU rows (lossy) or sample rows (lossless)
* [compression only]
*
* <p>See {@link #PARAM_RESTARTBLOCKS} for a description of restart markers.
*
* <p><b>Value</b>
* <ul>
* <li> the number of MCU rows or sample rows between each restart marker
* <i>[default: <code>0</code> (no restart markers)]</i>
* </ul>
*
* <p>Setting this parameter to a non-zero value sets
* {@link #PARAM_RESTARTBLOCKS} to 0.
*/
public static final int PARAM_RESTARTROWS = 19;
/**
* JPEG horizontal pixel density
*
* <p><b>Value</b>
* <ul>
* <li> The JPEG image has (decompression) or will have (compression) the
* specified horizontal pixel density <i>[default for compression:
* <code>1</code>]</i>.
* </ul>
*
* <p>This value is stored in or read from the JPEG header. It does not
* affect the contents of the JPEG image.
*
* @see #PARAM_DENSITYUNITS
*/
public static final int PARAM_XDENSITY = 20;
/**
* JPEG vertical pixel density
*
* <p><b>Value</b>
* <ul>
* <li> The JPEG image has (decompression) or will have (compression) the
* specified vertical pixel density <i>[default for compression:
* <code>1</code>]</i>.
* </ul>
*
* <p>This value is stored in or read from the JPEG header. It does not
* affect the contents of the JPEG image.
*
* @see #PARAM_DENSITYUNITS
*/
public static final int PARAM_YDENSITY = 21;
/**
* JPEG pixel density units
*
* <p><b>Value</b>
* <ul>
* <li> <code>0</code> <i>[default for compression]</i> The pixel density of
* the JPEG image is expressed (decompression) or will be expressed
* (compression) in unknown units.
* <li> <code>1</code> The pixel density of the JPEG image is expressed
* (decompression) or will be expressed (compression) in units of
* pixels/inch.
* <li> <code>2</code> The pixel density of the JPEG image is expressed
* (decompression) or will be expressed (compression) in units of pixels/cm.
* </ul>
*
* <p>This value is stored in or read from the JPEG header. It does not
* affect the contents of the JPEG image.
*
* @see #PARAM_XDENSITY
* @see #PARAM_YDENSITY
*/
public static final int PARAM_DENSITYUNITS = 22;
/**
* @deprecated Use {@link #PARAM_BOTTOMUP} instead.
*/
@Deprecated
public static final int FLAG_BOTTOMUP = 2;
/**
* @deprecated Use {@link #PARAM_FASTUPSAMPLE} instead.
*/
@Deprecated
public static final int FLAG_FASTUPSAMPLE = 256;
/**
* @deprecated Use {@link #PARAM_FASTDCT} instead.
*/
@Deprecated
public static final int FLAG_FASTDCT = 2048;
/**
* @deprecated Use {@link #PARAM_FASTDCT} instead.
*/
@Deprecated
public static final int FLAG_ACCURATEDCT = 4096;
/**
* @deprecated Use {@link #PARAM_STOPONWARNING} instead.
*/
@Deprecated
public static final int FLAG_STOPONWARNING = 8192;
/**
* @deprecated Use {@link #PARAM_PROGRESSIVE} instead.
*/
@Deprecated
public static final int FLAG_PROGRESSIVE = 16384;
/**
* @deprecated Use {@link #PARAM_SCANLIMIT} instead.
*/
@Deprecated
public static final int FLAG_LIMITSCANS = 32768;
/**
* The number of error codes
*/
public static final int NUMERR = 2;
/**
* The error was non-fatal and recoverable, but the destination image may
* still be corrupt.
* <p>
* NOTE: due to the design of the TurboJPEG Java API, only certain methods
* (specifically, {@link TJDecompressor TJDecompressor.decompress*()} methods
* with a void return type) will complete and leave the destination image in
* a fully recoverable state after a non-fatal error occurs.
*/
public static final int ERR_WARNING = 0;
/**
* The error was fatal and non-recoverable.
*/
public static final int ERR_FATAL = 1;
/**
* Returns the maximum size of the buffer (in bytes) required to hold a JPEG
* image with the given width, height, and level of chrominance subsampling.
*
* @param width the width (in pixels) of the JPEG image
*
* @param height the height (in pixels) of the JPEG image
*
* @param jpegSubsamp the level of chrominance subsampling to be used when
* generating the JPEG image (one of {@link #SAMP_444 TJ.SAMP_*}.)
* {@link #SAMP_UNKNOWN} is treated like {@link #SAMP_444}, since a buffer
* large enough to hold a JPEG image with no subsampling should also be large
* enough to hold a JPEG image with an arbitrary level of subsampling. Note
* that lossless JPEG images always use {@link #SAMP_444}.
*
* @return the maximum size of the buffer (in bytes) required to hold a JPEG
* image with the given width, height, and level of chrominance subsampling.
*/
public static native int bufSize(int width, int height, int jpegSubsamp);
/**
* Returns the size of the buffer (in bytes) required to hold a unified
* planar YUV image with the given width, height, and level of chrominance
* subsampling.
*
* @param width the width (in pixels) of the YUV image
*
* @param align row alignment (in bytes) of the YUV image (must be a power of
* 2.) Setting this parameter to n specifies that each row in each plane of
* the YUV image will be padded to the nearest multiple of n bytes
* (1 = unpadded.)
*
* @param height the height (in pixels) of the YUV image
*
* @param subsamp the level of chrominance subsampling used in the YUV
* image (one of {@link #SAMP_444 TJ.SAMP_*})
*
* @return the size of the buffer (in bytes) required to hold a unified
* planar YUV image with the given width, height, and level of chrominance
* subsampling.
*/
public static native int bufSizeYUV(int width, int align, int height,
int subsamp);
/**
* Returns the size of the buffer (in bytes) required to hold a YUV image
* plane with the given parameters.
*
* @param componentID ID number of the image plane (0 = Y, 1 = U/Cb,
* 2 = V/Cr)
*
* @param width width (in pixels) of the YUV image. NOTE: this is the width
* of the whole image, not the plane width.
*
* @param stride bytes per row in the image plane.
*
* @param height height (in pixels) of the YUV image. NOTE: this is the
* height of the whole image, not the plane height.
*
* @param subsamp the level of chrominance subsampling used in the YUV
* image (one of {@link #SAMP_444 TJ.SAMP_*})
*
* @return the size of the buffer (in bytes) required to hold a YUV image
* plane with the given parameters.
*/
public static native int planeSizeYUV(int componentID, int width, int stride,
int height, int subsamp);
/**
* Returns the plane width of a YUV image plane with the given parameters.
* Refer to {@link YUVImage} for a description of plane width.
*
* @param componentID ID number of the image plane (0 = Y, 1 = U/Cb,
* 2 = V/Cr)
*
* @param width width (in pixels) of the YUV image
*
* @param subsamp the level of chrominance subsampling used in the YUV image
* (one of {@link #SAMP_444 TJ.SAMP_*})
*
* @return the plane width of a YUV image plane with the given parameters.
*/
public static native int planeWidth(int componentID, int width, int subsamp);
/**
* Returns the plane height of a YUV image plane with the given parameters.
* Refer to {@link YUVImage} for a description of plane height.
*
* @param componentID ID number of the image plane (0 = Y, 1 = U/Cb,
* 2 = V/Cr)
*
* @param height height (in pixels) of the YUV image
*
* @param subsamp the level of chrominance subsampling used in the YUV image
* (one of {@link #SAMP_444 TJ.SAMP_*})
*
* @return the plane height of a YUV image plane with the given parameters.
*/
public static native int planeHeight(int componentID, int height,
int subsamp);
/**
* Returns a list of fractional scaling factors that the JPEG decompressor
* supports.
*
* @return a list of fractional scaling factors that the JPEG decompressor
* supports.
*/
public static native TJScalingFactor[] getScalingFactors();
/**
* A {@link TJScalingFactor} instance that specifies a scaling factor of 1/1
* (no scaling)
*/
public static final TJScalingFactor UNSCALED = new TJScalingFactor(1, 1);
/**
* A <code>java.awt.Rectangle</code> instance that specifies no cropping
*/
public static final Rectangle UNCROPPED = new Rectangle(0, 0, 0, 0);
static {
TJLoader.load();
}
private static void checkPixelFormat(int pixelFormat) {
if (pixelFormat < 0 || pixelFormat >= NUMPF)
throw new IllegalArgumentException("Invalid pixel format");
}
private static void checkSubsampling(int subsamp) {
if (subsamp < 0 || subsamp >= NUMSAMP)
throw new IllegalArgumentException("Invalid subsampling type");
}
}
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