e8b40f3c2b
The Gordian knot that 7fec5074f9 attempted
to unravel was caused by the fact that there are several
data-precision-dependent (JSAMPLE-dependent) fields and methods in the
exposed libjpeg API structures, and if you change the exposed libjpeg
API structures, then you have to change the whole API. If you change
the whole API, then you have to provide a whole new library to support
the new API, and that makes it difficult to support multiple data
precisions in the same application. (It is not impossible, as example.c
demonstrated, but using data-precision-dependent libjpeg API structures
would have made the cjpeg, djpeg, and jpegtran source code hard to read,
so it made more sense to build, install, and package 12-bit-specific
versions of those applications.)
Unfortunately, the result of that initial integration effort was an
unreadable and unmaintainable mess, which is a problem for a library
that is an ISO/ITU-T reference implementation. Also, as I dug into the
problem of lossless JPEG support, I realized that 16-bit lossless JPEG
images are a thing, and supporting yet another version of the libjpeg
API just for those images is untenable.
In fact, however, the touch points for JSAMPLE in the exposed libjpeg
API structures are minimal:
- The colormap and sample_range_limit fields in jpeg_decompress_struct
- The alloc_sarray() and access_virt_sarray() methods in
jpeg_memory_mgr
- jpeg_write_scanlines() and jpeg_write_raw_data()
- jpeg_read_scanlines() and jpeg_read_raw_data()
- jpeg_skip_scanlines() and jpeg_crop_scanline()
(This is subtle, but both of those functions use JSAMPLE-dependent
opaque structures behind the scenes.)
It is much more readable and maintainable to provide 12-bit-specific
versions of those six top-level API functions and to document that the
aforementioned methods and fields must be type-cast when using 12-bit
samples. Since that eliminates the need to provide a 12-bit-specific
version of the exposed libjpeg API structures, we can:
- Compile only the precision-dependent libjpeg modules (the
coefficient buffer controllers, the colorspace converters, the
DCT/IDCT managers, the main buffer controllers, the preprocessing
and postprocessing controller, the downsampler and upsamplers, the
quantizers, the integer DCT methods, and the IDCT methods) for
multiple data precisions.
- Introduce 12-bit-specific methods into the various internal
structures defined in jpegint.h.
- Create precision-independent data type, macro, method, field, and
function names that are prefixed by an underscore, and use an
internal header to convert those into precision-dependent data
type, macro, method, field, and function names, based on the value
of BITS_IN_JSAMPLE, when compiling the precision-dependent libjpeg
modules.
- Expose precision-dependent jinit*() functions for each of the
precision-dependent libjpeg modules.
- Abstract the precision-dependent libjpeg modules by calling the
appropriate precision-dependent jinit*() function, based on the
value of cinfo->data_precision, from top-level libjpeg API
functions.
465 lines
20 KiB
C
465 lines
20 KiB
C
/*
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* jdmainct.c
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*
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* This file was part of the Independent JPEG Group's software:
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* Copyright (C) 1994-1996, Thomas G. Lane.
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* libjpeg-turbo Modifications:
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* Copyright (C) 2010, 2016, 2022, D. R. Commander.
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* For conditions of distribution and use, see the accompanying README.ijg
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* file.
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*
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* This file contains the main buffer controller for decompression.
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* The main buffer lies between the JPEG decompressor proper and the
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* post-processor; it holds downsampled data in the JPEG colorspace.
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*
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* Note that this code is bypassed in raw-data mode, since the application
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* supplies the equivalent of the main buffer in that case.
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*/
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#include "jinclude.h"
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#include "jdmainct.h"
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/*
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* In the current system design, the main buffer need never be a full-image
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* buffer; any full-height buffers will be found inside the coefficient or
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* postprocessing controllers. Nonetheless, the main controller is not
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* trivial. Its responsibility is to provide context rows for upsampling/
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* rescaling, and doing this in an efficient fashion is a bit tricky.
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*
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* Postprocessor input data is counted in "row groups". A row group
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* is defined to be (v_samp_factor * DCT_scaled_size / min_DCT_scaled_size)
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* sample rows of each component. (We require DCT_scaled_size values to be
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* chosen such that these numbers are integers. In practice DCT_scaled_size
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* values will likely be powers of two, so we actually have the stronger
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* condition that DCT_scaled_size / min_DCT_scaled_size is an integer.)
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* Upsampling will typically produce max_v_samp_factor pixel rows from each
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* row group (times any additional scale factor that the upsampler is
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* applying).
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*
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* The coefficient controller will deliver data to us one iMCU row at a time;
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* each iMCU row contains v_samp_factor * DCT_scaled_size sample rows, or
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* exactly min_DCT_scaled_size row groups. (This amount of data corresponds
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* to one row of MCUs when the image is fully interleaved.) Note that the
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* number of sample rows varies across components, but the number of row
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* groups does not. Some garbage sample rows may be included in the last iMCU
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* row at the bottom of the image.
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*
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* Depending on the vertical scaling algorithm used, the upsampler may need
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* access to the sample row(s) above and below its current input row group.
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* The upsampler is required to set need_context_rows TRUE at global selection
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* time if so. When need_context_rows is FALSE, this controller can simply
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* obtain one iMCU row at a time from the coefficient controller and dole it
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* out as row groups to the postprocessor.
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*
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* When need_context_rows is TRUE, this controller guarantees that the buffer
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* passed to postprocessing contains at least one row group's worth of samples
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* above and below the row group(s) being processed. Note that the context
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* rows "above" the first passed row group appear at negative row offsets in
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* the passed buffer. At the top and bottom of the image, the required
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* context rows are manufactured by duplicating the first or last real sample
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* row; this avoids having special cases in the upsampling inner loops.
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*
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* The amount of context is fixed at one row group just because that's a
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* convenient number for this controller to work with. The existing
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* upsamplers really only need one sample row of context. An upsampler
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* supporting arbitrary output rescaling might wish for more than one row
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* group of context when shrinking the image; tough, we don't handle that.
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* (This is justified by the assumption that downsizing will be handled mostly
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* by adjusting the DCT_scaled_size values, so that the actual scale factor at
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* the upsample step needn't be much less than one.)
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*
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* To provide the desired context, we have to retain the last two row groups
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* of one iMCU row while reading in the next iMCU row. (The last row group
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* can't be processed until we have another row group for its below-context,
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* and so we have to save the next-to-last group too for its above-context.)
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* We could do this most simply by copying data around in our buffer, but
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* that'd be very slow. We can avoid copying any data by creating a rather
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* strange pointer structure. Here's how it works. We allocate a workspace
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* consisting of M+2 row groups (where M = min_DCT_scaled_size is the number
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* of row groups per iMCU row). We create two sets of redundant pointers to
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* the workspace. Labeling the physical row groups 0 to M+1, the synthesized
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* pointer lists look like this:
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* M+1 M-1
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* master pointer --> 0 master pointer --> 0
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* 1 1
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* ... ...
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* M-3 M-3
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* M-2 M
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* M-1 M+1
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* M M-2
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* M+1 M-1
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* 0 0
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* We read alternate iMCU rows using each master pointer; thus the last two
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* row groups of the previous iMCU row remain un-overwritten in the workspace.
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* The pointer lists are set up so that the required context rows appear to
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* be adjacent to the proper places when we pass the pointer lists to the
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* upsampler.
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*
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* The above pictures describe the normal state of the pointer lists.
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* At top and bottom of the image, we diddle the pointer lists to duplicate
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* the first or last sample row as necessary (this is cheaper than copying
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* sample rows around).
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*
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* This scheme breaks down if M < 2, ie, min_DCT_scaled_size is 1. In that
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* situation each iMCU row provides only one row group so the buffering logic
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* must be different (eg, we must read two iMCU rows before we can emit the
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* first row group). For now, we simply do not support providing context
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* rows when min_DCT_scaled_size is 1. That combination seems unlikely to
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* be worth providing --- if someone wants a 1/8th-size preview, they probably
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* want it quick and dirty, so a context-free upsampler is sufficient.
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*/
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/* Forward declarations */
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METHODDEF(void) process_data_simple_main(j_decompress_ptr cinfo,
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_JSAMPARRAY output_buf,
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JDIMENSION *out_row_ctr,
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JDIMENSION out_rows_avail);
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METHODDEF(void) process_data_context_main(j_decompress_ptr cinfo,
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_JSAMPARRAY output_buf,
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JDIMENSION *out_row_ctr,
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JDIMENSION out_rows_avail);
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#ifdef QUANT_2PASS_SUPPORTED
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METHODDEF(void) process_data_crank_post(j_decompress_ptr cinfo,
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_JSAMPARRAY output_buf,
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JDIMENSION *out_row_ctr,
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JDIMENSION out_rows_avail);
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#endif
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LOCAL(void)
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alloc_funny_pointers(j_decompress_ptr cinfo)
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/* Allocate space for the funny pointer lists.
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* This is done only once, not once per pass.
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*/
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{
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my_main_ptr main_ptr = (my_main_ptr)cinfo->main;
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int ci, rgroup;
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int M = cinfo->_min_DCT_scaled_size;
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jpeg_component_info *compptr;
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_JSAMPARRAY xbuf;
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/* Get top-level space for component array pointers.
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* We alloc both arrays with one call to save a few cycles.
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*/
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main_ptr->xbuffer[0] = (_JSAMPIMAGE)
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(*cinfo->mem->alloc_small) ((j_common_ptr)cinfo, JPOOL_IMAGE,
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cinfo->num_components * 2 *
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sizeof(_JSAMPARRAY));
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main_ptr->xbuffer[1] = main_ptr->xbuffer[0] + cinfo->num_components;
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for (ci = 0, compptr = cinfo->comp_info; ci < cinfo->num_components;
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ci++, compptr++) {
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rgroup = (compptr->v_samp_factor * compptr->_DCT_scaled_size) /
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cinfo->_min_DCT_scaled_size; /* height of a row group of component */
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/* Get space for pointer lists --- M+4 row groups in each list.
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* We alloc both pointer lists with one call to save a few cycles.
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*/
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xbuf = (_JSAMPARRAY)
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(*cinfo->mem->alloc_small) ((j_common_ptr)cinfo, JPOOL_IMAGE,
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2 * (rgroup * (M + 4)) * sizeof(_JSAMPROW));
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xbuf += rgroup; /* want one row group at negative offsets */
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main_ptr->xbuffer[0][ci] = xbuf;
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xbuf += rgroup * (M + 4);
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main_ptr->xbuffer[1][ci] = xbuf;
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}
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}
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LOCAL(void)
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make_funny_pointers(j_decompress_ptr cinfo)
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/* Create the funny pointer lists discussed in the comments above.
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* The actual workspace is already allocated (in main_ptr->buffer),
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* and the space for the pointer lists is allocated too.
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* This routine just fills in the curiously ordered lists.
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* This will be repeated at the beginning of each pass.
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*/
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{
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my_main_ptr main_ptr = (my_main_ptr)cinfo->main;
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int ci, i, rgroup;
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int M = cinfo->_min_DCT_scaled_size;
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jpeg_component_info *compptr;
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_JSAMPARRAY buf, xbuf0, xbuf1;
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for (ci = 0, compptr = cinfo->comp_info; ci < cinfo->num_components;
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ci++, compptr++) {
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rgroup = (compptr->v_samp_factor * compptr->_DCT_scaled_size) /
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cinfo->_min_DCT_scaled_size; /* height of a row group of component */
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xbuf0 = main_ptr->xbuffer[0][ci];
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xbuf1 = main_ptr->xbuffer[1][ci];
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/* First copy the workspace pointers as-is */
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buf = main_ptr->buffer[ci];
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for (i = 0; i < rgroup * (M + 2); i++) {
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xbuf0[i] = xbuf1[i] = buf[i];
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}
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/* In the second list, put the last four row groups in swapped order */
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for (i = 0; i < rgroup * 2; i++) {
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xbuf1[rgroup * (M - 2) + i] = buf[rgroup * M + i];
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xbuf1[rgroup * M + i] = buf[rgroup * (M - 2) + i];
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}
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/* The wraparound pointers at top and bottom will be filled later
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* (see set_wraparound_pointers, below). Initially we want the "above"
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* pointers to duplicate the first actual data line. This only needs
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* to happen in xbuffer[0].
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*/
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for (i = 0; i < rgroup; i++) {
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xbuf0[i - rgroup] = xbuf0[0];
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}
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}
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}
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LOCAL(void)
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set_bottom_pointers(j_decompress_ptr cinfo)
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/* Change the pointer lists to duplicate the last sample row at the bottom
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* of the image. whichptr indicates which xbuffer holds the final iMCU row.
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* Also sets rowgroups_avail to indicate number of nondummy row groups in row.
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*/
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{
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my_main_ptr main_ptr = (my_main_ptr)cinfo->main;
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int ci, i, rgroup, iMCUheight, rows_left;
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jpeg_component_info *compptr;
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_JSAMPARRAY xbuf;
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for (ci = 0, compptr = cinfo->comp_info; ci < cinfo->num_components;
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ci++, compptr++) {
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/* Count sample rows in one iMCU row and in one row group */
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iMCUheight = compptr->v_samp_factor * compptr->_DCT_scaled_size;
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rgroup = iMCUheight / cinfo->_min_DCT_scaled_size;
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/* Count nondummy sample rows remaining for this component */
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rows_left = (int)(compptr->downsampled_height % (JDIMENSION)iMCUheight);
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if (rows_left == 0) rows_left = iMCUheight;
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/* Count nondummy row groups. Should get same answer for each component,
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* so we need only do it once.
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*/
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if (ci == 0) {
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main_ptr->rowgroups_avail = (JDIMENSION)((rows_left - 1) / rgroup + 1);
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}
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/* Duplicate the last real sample row rgroup*2 times; this pads out the
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* last partial rowgroup and ensures at least one full rowgroup of context.
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*/
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xbuf = main_ptr->xbuffer[main_ptr->whichptr][ci];
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for (i = 0; i < rgroup * 2; i++) {
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xbuf[rows_left + i] = xbuf[rows_left - 1];
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}
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}
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}
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/*
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* Initialize for a processing pass.
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*/
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METHODDEF(void)
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start_pass_main(j_decompress_ptr cinfo, J_BUF_MODE pass_mode)
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{
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my_main_ptr main_ptr = (my_main_ptr)cinfo->main;
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switch (pass_mode) {
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case JBUF_PASS_THRU:
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if (cinfo->upsample->need_context_rows) {
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main_ptr->pub._process_data = process_data_context_main;
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make_funny_pointers(cinfo); /* Create the xbuffer[] lists */
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main_ptr->whichptr = 0; /* Read first iMCU row into xbuffer[0] */
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main_ptr->context_state = CTX_PREPARE_FOR_IMCU;
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main_ptr->iMCU_row_ctr = 0;
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} else {
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/* Simple case with no context needed */
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main_ptr->pub._process_data = process_data_simple_main;
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}
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main_ptr->buffer_full = FALSE; /* Mark buffer empty */
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main_ptr->rowgroup_ctr = 0;
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break;
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#ifdef QUANT_2PASS_SUPPORTED
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case JBUF_CRANK_DEST:
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/* For last pass of 2-pass quantization, just crank the postprocessor */
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main_ptr->pub._process_data = process_data_crank_post;
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break;
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#endif
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default:
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ERREXIT(cinfo, JERR_BAD_BUFFER_MODE);
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break;
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}
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}
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/*
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* Process some data.
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* This handles the simple case where no context is required.
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*/
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METHODDEF(void)
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process_data_simple_main(j_decompress_ptr cinfo, _JSAMPARRAY output_buf,
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JDIMENSION *out_row_ctr, JDIMENSION out_rows_avail)
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{
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my_main_ptr main_ptr = (my_main_ptr)cinfo->main;
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JDIMENSION rowgroups_avail;
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/* Read input data if we haven't filled the main buffer yet */
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if (!main_ptr->buffer_full) {
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if (!(*cinfo->coef->_decompress_data) (cinfo, main_ptr->buffer))
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return; /* suspension forced, can do nothing more */
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main_ptr->buffer_full = TRUE; /* OK, we have an iMCU row to work with */
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}
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/* There are always min_DCT_scaled_size row groups in an iMCU row. */
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rowgroups_avail = (JDIMENSION)cinfo->_min_DCT_scaled_size;
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/* Note: at the bottom of the image, we may pass extra garbage row groups
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* to the postprocessor. The postprocessor has to check for bottom
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* of image anyway (at row resolution), so no point in us doing it too.
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*/
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/* Feed the postprocessor */
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(*cinfo->post->_post_process_data) (cinfo, main_ptr->buffer,
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&main_ptr->rowgroup_ctr, rowgroups_avail,
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output_buf, out_row_ctr, out_rows_avail);
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/* Has postprocessor consumed all the data yet? If so, mark buffer empty */
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if (main_ptr->rowgroup_ctr >= rowgroups_avail) {
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main_ptr->buffer_full = FALSE;
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main_ptr->rowgroup_ctr = 0;
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}
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}
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/*
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* Process some data.
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* This handles the case where context rows must be provided.
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*/
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METHODDEF(void)
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process_data_context_main(j_decompress_ptr cinfo, _JSAMPARRAY output_buf,
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JDIMENSION *out_row_ctr, JDIMENSION out_rows_avail)
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{
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my_main_ptr main_ptr = (my_main_ptr)cinfo->main;
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/* Read input data if we haven't filled the main buffer yet */
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if (!main_ptr->buffer_full) {
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if (!(*cinfo->coef->_decompress_data) (cinfo,
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main_ptr->xbuffer[main_ptr->whichptr]))
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return; /* suspension forced, can do nothing more */
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main_ptr->buffer_full = TRUE; /* OK, we have an iMCU row to work with */
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main_ptr->iMCU_row_ctr++; /* count rows received */
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}
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/* Postprocessor typically will not swallow all the input data it is handed
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* in one call (due to filling the output buffer first). Must be prepared
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* to exit and restart. This switch lets us keep track of how far we got.
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* Note that each case falls through to the next on successful completion.
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*/
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switch (main_ptr->context_state) {
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case CTX_POSTPONED_ROW:
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/* Call postprocessor using previously set pointers for postponed row */
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(*cinfo->post->_post_process_data) (cinfo,
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main_ptr->xbuffer[main_ptr->whichptr],
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&main_ptr->rowgroup_ctr,
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main_ptr->rowgroups_avail, output_buf,
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out_row_ctr, out_rows_avail);
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if (main_ptr->rowgroup_ctr < main_ptr->rowgroups_avail)
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return; /* Need to suspend */
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main_ptr->context_state = CTX_PREPARE_FOR_IMCU;
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if (*out_row_ctr >= out_rows_avail)
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return; /* Postprocessor exactly filled output buf */
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FALLTHROUGH /*FALLTHROUGH*/
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case CTX_PREPARE_FOR_IMCU:
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/* Prepare to process first M-1 row groups of this iMCU row */
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main_ptr->rowgroup_ctr = 0;
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main_ptr->rowgroups_avail = (JDIMENSION)(cinfo->_min_DCT_scaled_size - 1);
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/* Check for bottom of image: if so, tweak pointers to "duplicate"
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* the last sample row, and adjust rowgroups_avail to ignore padding rows.
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*/
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if (main_ptr->iMCU_row_ctr == cinfo->total_iMCU_rows)
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set_bottom_pointers(cinfo);
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main_ptr->context_state = CTX_PROCESS_IMCU;
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FALLTHROUGH /*FALLTHROUGH*/
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case CTX_PROCESS_IMCU:
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/* Call postprocessor using previously set pointers */
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(*cinfo->post->_post_process_data) (cinfo,
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main_ptr->xbuffer[main_ptr->whichptr],
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&main_ptr->rowgroup_ctr,
|
|
main_ptr->rowgroups_avail, output_buf,
|
|
out_row_ctr, out_rows_avail);
|
|
if (main_ptr->rowgroup_ctr < main_ptr->rowgroups_avail)
|
|
return; /* Need to suspend */
|
|
/* After the first iMCU, change wraparound pointers to normal state */
|
|
if (main_ptr->iMCU_row_ctr == 1)
|
|
set_wraparound_pointers(cinfo);
|
|
/* Prepare to load new iMCU row using other xbuffer list */
|
|
main_ptr->whichptr ^= 1; /* 0=>1 or 1=>0 */
|
|
main_ptr->buffer_full = FALSE;
|
|
/* Still need to process last row group of this iMCU row, */
|
|
/* which is saved at index M+1 of the other xbuffer */
|
|
main_ptr->rowgroup_ctr = (JDIMENSION)(cinfo->_min_DCT_scaled_size + 1);
|
|
main_ptr->rowgroups_avail = (JDIMENSION)(cinfo->_min_DCT_scaled_size + 2);
|
|
main_ptr->context_state = CTX_POSTPONED_ROW;
|
|
}
|
|
}
|
|
|
|
|
|
/*
|
|
* Process some data.
|
|
* Final pass of two-pass quantization: just call the postprocessor.
|
|
* Source data will be the postprocessor controller's internal buffer.
|
|
*/
|
|
|
|
#ifdef QUANT_2PASS_SUPPORTED
|
|
|
|
METHODDEF(void)
|
|
process_data_crank_post(j_decompress_ptr cinfo, _JSAMPARRAY output_buf,
|
|
JDIMENSION *out_row_ctr, JDIMENSION out_rows_avail)
|
|
{
|
|
(*cinfo->post->_post_process_data) (cinfo, (_JSAMPIMAGE)NULL,
|
|
(JDIMENSION *)NULL, (JDIMENSION)0,
|
|
output_buf, out_row_ctr, out_rows_avail);
|
|
}
|
|
|
|
#endif /* QUANT_2PASS_SUPPORTED */
|
|
|
|
|
|
/*
|
|
* Initialize main buffer controller.
|
|
*/
|
|
|
|
GLOBAL(void)
|
|
_jinit_d_main_controller(j_decompress_ptr cinfo, boolean need_full_buffer)
|
|
{
|
|
my_main_ptr main_ptr;
|
|
int ci, rgroup, ngroups;
|
|
jpeg_component_info *compptr;
|
|
|
|
if (cinfo->data_precision != BITS_IN_JSAMPLE)
|
|
ERREXIT1(cinfo, JERR_BAD_PRECISION, cinfo->data_precision);
|
|
|
|
main_ptr = (my_main_ptr)
|
|
(*cinfo->mem->alloc_small) ((j_common_ptr)cinfo, JPOOL_IMAGE,
|
|
sizeof(my_main_controller));
|
|
cinfo->main = (struct jpeg_d_main_controller *)main_ptr;
|
|
main_ptr->pub.start_pass = start_pass_main;
|
|
|
|
if (need_full_buffer) /* shouldn't happen */
|
|
ERREXIT(cinfo, JERR_BAD_BUFFER_MODE);
|
|
|
|
/* Allocate the workspace.
|
|
* ngroups is the number of row groups we need.
|
|
*/
|
|
if (cinfo->upsample->need_context_rows) {
|
|
if (cinfo->_min_DCT_scaled_size < 2) /* unsupported, see comments above */
|
|
ERREXIT(cinfo, JERR_NOTIMPL);
|
|
alloc_funny_pointers(cinfo); /* Alloc space for xbuffer[] lists */
|
|
ngroups = cinfo->_min_DCT_scaled_size + 2;
|
|
} else {
|
|
ngroups = cinfo->_min_DCT_scaled_size;
|
|
}
|
|
|
|
for (ci = 0, compptr = cinfo->comp_info; ci < cinfo->num_components;
|
|
ci++, compptr++) {
|
|
rgroup = (compptr->v_samp_factor * compptr->_DCT_scaled_size) /
|
|
cinfo->_min_DCT_scaled_size; /* height of a row group of component */
|
|
main_ptr->buffer[ci] = (_JSAMPARRAY)(*cinfo->mem->alloc_sarray)
|
|
((j_common_ptr)cinfo, JPOOL_IMAGE,
|
|
compptr->width_in_blocks * compptr->_DCT_scaled_size,
|
|
(JDIMENSION)(rgroup * ngroups));
|
|
}
|
|
}
|