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|
/* Copyright (C) 2001-2020 Artifex Software, Inc.
All Rights Reserved.
This software is provided AS-IS with no warranty, either express or
implied.
This software is distributed under license and may not be copied,
modified or distributed except as expressly authorized under the terms
of the license contained in the file LICENSE in this distribution.
Refer to licensing information at http://www.artifex.com or contact
Artifex Software, Inc., 1305 Grant Avenue - Suite 200, Novato,
CA 94945, U.S.A., +1(415)492-9861, for further information.
*/
/* Image setup procedures for Ghostscript library */
#include "memory_.h"
#include "math_.h"
#include "gx.h"
#include "gserrors.h"
#include "gsstruct.h"
#include "gscspace.h"
#include "gsmatrix.h" /* for gsiparam.h */
#include "gsimage.h"
#include "gxarith.h" /* for igcd */
#include "gxdevice.h"
#include "gxiparam.h"
#include "gxpath.h" /* for gx_effective_clip_path */
#include "gximask.h"
#include "gzstate.h"
#include "gsutil.h"
#include "gxdevsop.h"
#include "gximage.h"
/*
The main internal invariant for the gs_image machinery is
straightforward. The state consists primarily of N plane buffers
(planes[]).
*/
typedef struct image_enum_plane_s {
/*
The state of each plane consists of:
- A row buffer, aligned and (logically) large enough to hold one scan line
for that plane. (It may have to be reallocated if the plane width or
depth changes.) A row buffer is "full" if it holds exactly a full scan
line.
*/
gs_string row;
/*
- A position within the row buffer, indicating how many initial bytes are
occupied.
*/
uint pos;
/*
- A (retained) source string, which may be empty (size = 0).
*/
gs_const_string source;
} image_enum_plane_t;
/*
The possible states for each plane do not depend on the state of any other
plane. Either:
- pos = 0, source.size = 0.
- If the underlying image processor says the plane is currently wanted,
either:
- pos = 0, source.size >= one full row of data for this plane. This
case allows us to avoid copying the data from the source string to the
row buffer if the client is providing data in blocks of at least one
scan line.
- pos = full, source.size may have any value.
- pos > 0, pos < full, source.size = 0;
- If the underlying image processor says the plane is not currently
wanted:
- pos = 0, source.size may have any value.
This invariant holds at the beginning and end of each call on
gs_image_next_planes. Note that for each plane, the "plane wanted" status
and size of a full row may change after each call of plane_data. As
documented in gxiparam.h, we assume that a call of plane_data can only
change a plane's status from "wanted" to "not wanted", or change the width
or depth of a wanted plane, if data for that plane was actually supplied
(and used).
*/
/* Define the enumeration state for this interface layer. */
/*typedef struct gs_image_enum_s gs_image_enum; *//* in gsimage.h */
struct gs_image_enum_s {
/* The following are set at initialization time. */
gs_memory_t *memory;
gx_device *dev; /* if 0, just skip over the data */
gx_image_enum_common_t *info; /* driver bookkeeping structure */
int num_planes;
int height;
bool wanted_varies;
/* The following are updated dynamically. */
int plane_index; /* index of next plane of data, */
/* only needed for gs_image_next */
int y;
bool error;
byte wanted[GS_IMAGE_MAX_COMPONENTS]; /* cache gx_image_planes_wanted */
byte client_wanted[GS_IMAGE_MAX_COMPONENTS]; /* see gsimage.h */
image_enum_plane_t planes[GS_IMAGE_MAX_COMPONENTS]; /* see above */
/*
* To reduce setup for transferring complete rows, we maintain a
* partially initialized parameter array for gx_image_plane_data_rows.
* The data member is always set just before calling
* gx_image_plane_data_rows; the data_x and raster members are reset
* when needed.
*/
gx_image_plane_t image_planes[GS_IMAGE_MAX_COMPONENTS];
};
gs_private_st_composite(st_gs_image_enum, gs_image_enum, "gs_image_enum",
gs_image_enum_enum_ptrs, gs_image_enum_reloc_ptrs);
#define gs_image_enum_num_ptrs 2
/* GC procedures */
static
ENUM_PTRS_WITH(gs_image_enum_enum_ptrs, gs_image_enum *eptr)
{
/* Enumerate the data planes. */
index -= gs_image_enum_num_ptrs;
if (index < eptr->num_planes)
ENUM_RETURN_STRING_PTR(gs_image_enum, planes[index].source);
index -= eptr->num_planes;
if (index < eptr->num_planes)
ENUM_RETURN_STRING_PTR(gs_image_enum, planes[index].row);
return 0;
}
ENUM_PTR(0, gs_image_enum, dev);
ENUM_PTR(1, gs_image_enum, info);
ENUM_PTRS_END
static RELOC_PTRS_WITH(gs_image_enum_reloc_ptrs, gs_image_enum *eptr)
{
int i;
RELOC_PTR(gs_image_enum, dev);
RELOC_PTR(gs_image_enum, info);
for (i = 0; i < eptr->num_planes; i++)
RELOC_CONST_STRING_PTR(gs_image_enum, planes[i].source);
for (i = 0; i < eptr->num_planes; i++)
RELOC_STRING_PTR(gs_image_enum, planes[i].row);
}
RELOC_PTRS_END
static int
is_image_visible(const gs_image_common_t * pic, gs_gstate * pgs, gx_clip_path *pcpath)
{
/* HACK : We need the source image size here,
but gs_image_common_t doesn't pass it.
We would like to move Width, Height to gs_image_common,
but gs_image2_t appears to have those fields of double type.
*/
if (pic->type->begin_typed_image == gx_begin_image1) {
gs_image1_t *pim = (gs_image1_t *) pic;
gs_rect image_rect = {{0, 0}, {0, 0}};
gs_rect device_rect;
gs_int_rect device_int_rect;
gs_matrix mat;
int code;
image_rect.q.x = pim->Width;
image_rect.q.y = pim->Height;
if (pic->ImageMatrix.xx == ctm_only(pgs).xx &&
pic->ImageMatrix.xy == ctm_only(pgs).xy &&
pic->ImageMatrix.yx == ctm_only(pgs).yx &&
pic->ImageMatrix.yy == ctm_only(pgs).yy) {
/* Handle common special case separately to accept singular matrix */
mat.xx = mat.yy = 1.;
mat.yx = mat.xy = 0.;
mat.tx = ctm_only(pgs).tx - pic->ImageMatrix.tx;
mat.ty = ctm_only(pgs).ty - pic->ImageMatrix.ty;
} else {
code = gs_matrix_invert(&pic->ImageMatrix, &mat);
if (code < 0)
return code;
code = gs_matrix_multiply(&mat, &ctm_only(pgs), &mat);
if (code < 0)
return code;
}
code = gs_bbox_transform(&image_rect, &mat, &device_rect);
if (code < 0)
return code;
device_int_rect.p.x = (int)floor(device_rect.p.x);
device_int_rect.p.y = (int)floor(device_rect.p.y);
device_int_rect.q.x = (int)ceil(device_rect.q.x);
device_int_rect.q.y = (int)ceil(device_rect.q.y);
if (!gx_cpath_rect_visible(pcpath, &device_int_rect))
return 0;
}
return 1;
}
/* Create an image enumerator given image parameters and a graphics state. */
int
gs_image_begin_typed(const gs_image_common_t * pic, gs_gstate * pgs,
bool uses_color, bool image_is_text, gx_image_enum_common_t ** ppie)
{
gx_device *dev = gs_currentdevice(pgs);
gx_clip_path *pcpath;
int code = gx_effective_clip_path(pgs, &pcpath);
gx_device *dev2 = dev;
gx_device_color dc_temp, *pdevc = gs_currentdevicecolor_inline(pgs);
if (code < 0)
return code;
/* Processing an image object operation, but this may be for a text object */
ensure_tag_is_set(pgs, pgs->device, image_is_text ? GS_TEXT_TAG : GS_IMAGE_TAG); /* NB: may unset_dev_color */
if (uses_color) {
code = gx_set_dev_color(pgs);
if (code != 0)
return code;
code = gs_gstate_color_load(pgs);
if (code < 0)
return code;
}
if (pgs->overprint || (!pgs->overprint && dev_proc(pgs->device, dev_spec_op)(pgs->device,
gxdso_overprint_active, NULL, 0))) {
gs_overprint_params_t op_params = { 0 };
if_debug0m(gs_debug_flag_overprint, pgs->memory,
"[overprint] Image Overprint\n");
code = gs_do_set_overprint(pgs);
if (code < 0)
return code;
op_params.op_state = OP_STATE_FILL;
gs_gstate_update_overprint(pgs, &op_params);
dev = gs_currentdevice(pgs);
dev2 = dev;
}
/* Imagemask with shading color needs a special optimization
with converting the image into a clipping.
Check for such case after gs_gstate_color_load is done,
because it can cause interpreter callout.
*/
if (pic->type->begin_typed_image == &gx_begin_image1) {
gs_image_t *image = (gs_image_t *)pic;
if(image->ImageMask) {
bool transpose = false;
gs_matrix_double mat;
if((code = gx_image_compute_mat(pgs, NULL, &(image->ImageMatrix), &mat)) < 0)
return code;
if ((any_abs(mat.xy) > any_abs(mat.xx)) && (any_abs(mat.yx) > any_abs(mat.yy)))
transpose = true; /* pure landscape */
code = gx_image_fill_masked_start(dev, gs_currentdevicecolor_inline(pgs), transpose,
pcpath, pgs->memory, pgs->log_op, &dev2);
if (code < 0)
return code;
}
if (dev->interpolate_control < 0) { /* Force interpolation before begin_typed_image */
((gs_data_image_t *)pic)->Interpolate = true;
}
else if (dev->interpolate_control == 0) {
((gs_data_image_t *)pic)->Interpolate = false; /* Suppress interpolation */
}
if (dev2 != dev) {
set_nonclient_dev_color(&dc_temp, 1);
pdevc = &dc_temp;
}
}
code = gx_device_begin_typed_image(dev2, (const gs_gstate *)pgs,
NULL, pic, NULL, pdevc, pcpath, pgs->memory, ppie);
if (code < 0)
return code;
code = is_image_visible(pic, pgs, pcpath);
if (code < 0)
return code;
if (!code)
(*ppie)->skipping = true;
return 0;
}
/* Allocate an image enumerator. */
static void
image_enum_init(gs_image_enum * penum)
{
/* Clean pointers for GC. */
penum->info = 0;
penum->dev = 0;
penum->plane_index = 0;
penum->num_planes = 0;
}
gs_image_enum *
gs_image_enum_alloc(gs_memory_t * mem, client_name_t cname)
{
gs_image_enum *penum =
gs_alloc_struct(mem, gs_image_enum, &st_gs_image_enum, cname);
if (penum != 0) {
penum->memory = mem;
image_enum_init(penum);
}
return penum;
}
/* Start processing an ImageType 1 image. */
int
gs_image_init(gs_image_enum * penum, const gs_image_t * pim, bool multi,
bool image_is_text, gs_gstate * pgs)
{
gs_image_t image;
gx_image_enum_common_t *pie;
int code;
image = *pim;
if (image.ImageMask) {
image.ColorSpace = NULL;
if (pgs->in_cachedevice <= 1)
image.adjust = false;
} else {
if (pgs->in_cachedevice)
return_error(gs_error_undefined);
if (image.ColorSpace == NULL) {
/*
* Use of a non-current color space is potentially
* incorrect, but it appears this case doesn't arise.
*/
image.ColorSpace = gs_cspace_new_DeviceGray(pgs->memory);
if (image.ColorSpace == NULL)
return_error(gs_error_VMerror);
}
}
code = gs_image_begin_typed((const gs_image_common_t *)&image, pgs,
image.ImageMask | image.CombineWithColor,
image_is_text, &pie);
if (code < 0)
return code;
return gs_image_enum_init(penum, pie, (const gs_data_image_t *)&image,
pgs);
}
/*
* Return the number of bytes of data per row for a given plane.
*/
inline uint
gs_image_bytes_per_plane_row(const gs_image_enum * penum, int plane)
{
const gx_image_enum_common_t *pie = penum->info;
return (pie->plane_widths[plane] * pie->plane_depths[plane] + 7) >> 3;
}
/* Cache information when initializing, or after transferring plane data. */
static void
cache_planes(gs_image_enum *penum)
{
int i;
if (penum->wanted_varies) {
penum->wanted_varies =
!gx_image_planes_wanted(penum->info, penum->wanted);
for (i = 0; i < penum->num_planes; ++i)
if (penum->wanted[i])
penum->image_planes[i].raster =
gs_image_bytes_per_plane_row(penum, i);
else
penum->image_planes[i].data = 0;
}
}
/* Advance to the next wanted plane. */
static void
next_plane(gs_image_enum *penum)
{
int px = penum->plane_index;
do {
if (++px == penum->num_planes)
px = 0;
} while (!penum->wanted[px]);
penum->plane_index = px;
}
/*
* Initialize plane_index and (if appropriate) wanted and
* wanted_varies at the beginning of a group of planes.
*/
static void
begin_planes(gs_image_enum *penum)
{
cache_planes(penum);
penum->plane_index = -1;
next_plane(penum);
}
int
gs_image_common_init(gs_image_enum * penum, gx_image_enum_common_t * pie,
const gs_data_image_t * pim, gx_device * dev)
{
/*
* HACK : For a compatibility with gs_image_cleanup_and_free_enum,
* penum->memory must be initialized in advance
* with the memory heap that owns *penum.
*/
int i;
if (pim->Width == 0 || pim->Height == 0) {
gx_image_end(pie, false);
return 1;
}
image_enum_init(penum);
penum->dev = dev;
penum->info = pie;
penum->num_planes = pie->num_planes;
/*
* Note that for ImageType 3 InterleaveType 2, penum->height (the
* expected number of data rows) differs from pim->Height (the height
* of the source image in scan lines). This doesn't normally cause
* any problems, because penum->height is not used to determine when
* all the data has been processed: that is up to the plane_data
* procedure for the specific image type.
*/
penum->height = pim->Height;
for (i = 0; i < pie->num_planes; ++i) {
penum->planes[i].pos = 0;
penum->planes[i].source.size = 0; /* for gs_image_next_planes */
penum->planes[i].source.data = 0; /* for GC */
penum->planes[i].row.data = 0; /* for GC */
penum->planes[i].row.size = 0; /* ditto */
penum->image_planes[i].data_x = 0; /* just init once, never changes */
}
/* Initialize the dynamic part of the state. */
penum->y = 0;
penum->error = false;
penum->wanted_varies = true;
begin_planes(penum);
return 0;
}
/* Initialize an enumerator for a general image.
penum->memory must be initialized in advance.
*/
int
gs_image_enum_init(gs_image_enum * penum, gx_image_enum_common_t * pie,
const gs_data_image_t * pim, gs_gstate *pgs)
{
pgs->device->sgr.stroke_stored = false;
return gs_image_common_init(penum, pie, pim,
(pgs->in_charpath ? NULL :
gs_currentdevice_inline(pgs)));
}
/* Return the set of planes wanted. */
const byte *
gs_image_planes_wanted(gs_image_enum *penum)
{
int i;
/*
* A plane is wanted at this interface if it is wanted by the
* underlying machinery and has no buffered or retained data.
*/
for (i = 0; i < penum->num_planes; ++i)
penum->client_wanted[i] =
(penum->wanted[i] &&
penum->planes[i].pos + penum->planes[i].source.size <
penum->image_planes[i].raster);
return penum->client_wanted;
}
/*
* Return the enumerator memory used for allocating the row buffers.
* Because some PostScript files use save/restore within an image data
* reading procedure, this must be a stable allocator.
*/
static gs_memory_t *
gs_image_row_memory(const gs_image_enum *penum)
{
return gs_memory_stable(penum->memory);
}
/* Free the row buffers when cleaning up. */
static void
free_row_buffers(gs_image_enum *penum, int num_planes, client_name_t cname)
{
int i;
for (i = num_planes - 1; i >= 0; --i) {
if_debug3m('b', penum->memory, "[b]free plane %d row ("PRI_INTPTR",%u)\n",
i, (intptr_t)penum->planes[i].row.data,
penum->planes[i].row.size);
gs_free_string(gs_image_row_memory(penum), penum->planes[i].row.data,
penum->planes[i].row.size, cname);
penum->planes[i].row.data = 0;
penum->planes[i].row.size = 0;
}
}
/* Process the next piece of an image. */
int
gs_image_next(gs_image_enum * penum, const byte * dbytes, uint dsize,
uint * pused)
{
int px = penum->plane_index;
int num_planes = penum->num_planes;
int i, code;
uint used[GS_IMAGE_MAX_COMPONENTS];
gs_const_string plane_data[GS_IMAGE_MAX_COMPONENTS];
if (penum->planes[px].source.size != 0)
return_error(gs_error_rangecheck);
for (i = 0; i < num_planes; i++)
plane_data[i].size = 0;
plane_data[px].data = dbytes;
plane_data[px].size = dsize;
penum->error = false;
code = gs_image_next_planes(penum, plane_data, used);
*pused = used[px];
if (code >= 0)
next_plane(penum);
return code;
}
int
gs_image_next_planes(gs_image_enum * penum,
gs_const_string *plane_data /*[num_planes]*/,
uint *used /*[num_planes]*/)
{
const int num_planes = penum->num_planes;
int i;
int code = 0;
#ifdef DEBUG
if (gs_debug_c('b')) {
int pi;
for (pi = 0; pi < num_planes; ++pi)
dmprintf6(penum->memory, "[b]plane %d source="PRI_INTPTR",%u pos=%u data="PRI_INTPTR",%u\n",
pi, (intptr_t)penum->planes[pi].source.data,
penum->planes[pi].source.size, penum->planes[pi].pos,
(intptr_t)plane_data[pi].data, plane_data[pi].size);
}
#endif
for (i = 0; i < num_planes; ++i) {
used[i] = 0;
if (penum->wanted[i] && plane_data[i].size != 0) {
penum->planes[i].source.size = plane_data[i].size;
penum->planes[i].source.data = plane_data[i].data;
}
}
for (;;) {
/* If wanted can vary, only transfer 1 row at a time. */
int h = (penum->wanted_varies ? 1 : max_int);
/* Move partial rows from source[] to row[]. */
for (i = 0; i < num_planes; ++i) {
int pos, size;
uint raster;
if (!penum->wanted[i])
continue; /* skip unwanted planes */
pos = penum->planes[i].pos;
size = penum->planes[i].source.size;
raster = penum->image_planes[i].raster;
if (size > 0) {
if (pos < raster && (pos != 0 || size < raster)) {
/* Buffer a partial row. */
int copy = min(size, raster - pos);
uint old_size = penum->planes[i].row.size;
/* Make sure the row buffer is fully allocated. */
if (raster > old_size) {
gs_memory_t *mem = gs_image_row_memory(penum);
byte *old_data = penum->planes[i].row.data;
byte *row =
(old_data == 0 ?
gs_alloc_string(mem, raster,
"gs_image_next(row)") :
gs_resize_string(mem, old_data, old_size, raster,
"gs_image_next(row)"));
if_debug5m('b', mem, "[b]plane %d row ("PRI_INTPTR",%u) => ("PRI_INTPTR",%u)\n",
i, (intptr_t)old_data, old_size,
(intptr_t)row, raster);
if (row == 0) {
code = gs_note_error(gs_error_VMerror);
free_row_buffers(penum, i, "gs_image_next(row)");
break;
}
penum->planes[i].row.data = row;
penum->planes[i].row.size = raster;
}
memcpy(penum->planes[i].row.data + pos,
penum->planes[i].source.data, copy);
penum->planes[i].source.data += copy;
penum->planes[i].source.size = size -= copy;
penum->planes[i].pos = pos += copy;
used[i] += copy;
}
}
if (h == 0)
continue; /* can't transfer any data this cycle */
if (pos == raster) {
/*
* This plane will be transferred from the row buffer,
* so we can only transfer one row.
*/
h = min(h, 1);
penum->image_planes[i].data = penum->planes[i].row.data;
} else if (pos == 0 && size >= raster) {
/* We can transfer 1 or more planes from the source. */
if (raster) {
h = min(h, size / raster);
penum->image_planes[i].data = penum->planes[i].source.data;
}
else
h = 0;
} else
h = 0; /* not enough data in this plane */
}
if (h == 0 || code != 0)
break;
/* Pass rows to the device. */
if (penum->dev == 0) {
/*
* ****** NOTE: THE FOLLOWING IS NOT CORRECT FOR ImageType 3
* ****** InterleaveType 2, SINCE MASK HEIGHT AND IMAGE HEIGHT
* ****** MAY DIFFER (BY AN INTEGER FACTOR). ALSO, plane_depths[0]
* ****** AND plane_widths[0] ARE NOT UPDATED.
*/
if (penum->y + h < penum->height)
code = 0;
else
h = penum->height - penum->y, code = 1;
} else {
code = gx_image_plane_data_rows(penum->info, penum->image_planes,
h, &h);
if_debug2m('b', penum->memory, "[b]used %d, code=%d\n", h, code);
penum->error = code < 0;
}
penum->y += h;
/* Update positions and sizes. */
if (h == 0)
break;
for (i = 0; i < num_planes; ++i) {
int count;
if (!penum->wanted[i])
continue;
count = penum->image_planes[i].raster * h;
if (penum->planes[i].pos) {
/* We transferred the row from the row buffer. */
penum->planes[i].pos = 0;
} else {
/* We transferred the row(s) from the source. */
penum->planes[i].source.data += count;
penum->planes[i].source.size -= count;
used[i] += count;
}
}
cache_planes(penum);
if (code > 0)
break;
}
/* Return the retained data pointers. */
for (i = 0; i < num_planes; ++i)
plane_data[i] = penum->planes[i].source;
return code;
}
/* Clean up after processing an image. */
/* Public for ghostpcl. */
int
gs_image_cleanup(gs_image_enum * penum, gs_gstate *pgs)
{
int code = 0, code1;
free_row_buffers(penum, penum->num_planes, "gs_image_cleanup(row)");
if (penum->info != 0) {
if (dev_proc(penum->info->dev, dev_spec_op)(penum->info->dev,
gxdso_pattern_is_cpath_accum, NULL, 0)) {
/* Performing a conversion of imagemask into a clipping path. */
gx_device *cdev = penum->info->dev;
code = gx_image_end(penum->info, !penum->error); /* Releases penum->info . */
code1 = gx_image_fill_masked_end(cdev, penum->dev, gs_currentdevicecolor_inline(pgs));
if (code == 0)
code = code1;
} else
code = gx_image_end(penum->info, !penum->error);
}
/* Don't free the local enumerator -- the client does that. */
return code;
}
/* Clean up after processing an image and free the enumerator. */
int
gs_image_cleanup_and_free_enum(gs_image_enum * penum, gs_gstate *pgs)
{
int code = gs_image_cleanup(penum, pgs);
gs_free_object(penum->memory, penum, "gs_image_cleanup_and_free_enum");
return code;
}
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