/* Copyright (C) 1992, 1995, 1996, 1998, 1999, 2000 Aladdin Enterprises. 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. For more information about licensing, please refer to http://www.ghostscript.com/licensing/. For information on commercial licensing, go to http://www.artifex.com/licensing/ or contact Artifex Software, Inc., 101 Lucas Valley Road #110, San Rafael, CA 94903, U.S.A., +1(415)492-9861. */ /* $Id$ */ /* Generic image rendering interface */ /* Requires gsstate.h */ #ifndef gsimage_INCLUDED # define gsimage_INCLUDED #include "gsiparam.h" /* The API defined in this file and implemented in gsimage.c provides a layer of buffering between clients and the underlying image processing interface defined in gxdevcli.h (begin_[typed_]image device procedure) and gxiparam.h (image processing procedures). Two of the underlying image processing procedures defined in gxiparam.h define and process the actual data: - The underlying planes_wanted image processing procedure indicates which data planes are needed (not necessarily all of them, in the case of images with differently scaled planes), and may also change the widths and/or depths of the planes. It may return different results at different times, if the widths, depths, or planes wanted changes in the course of the image. - The underlying plane_data procedure actually processes the image. Each call of plane_data requires an integral number of scan lines for each wanted plane. If the widths, depths, or planes wanted vary from call to call, plane_data may choose to accept fewer scan lines than provided. If this happens, it is the client's responsibility to call planes_wanted to find out which planes are now wanted, and then call plane_data again with data for (only) the wanted planes. Conceptually, the gs_image_next_planes procedure defined here provides the same function as the plane_data procedure, except that: - The data need not consist of complete scan lines, or be aligned in any way; - If a single call passes multiple scan lines for a single plane, each scan line is only padded to a byte boundary, not to an alignment boundary; - Different amounts of data (including none) may be passed for each plane, independent of which planes need data or the amount of data that makes up a complete scan line for a plane; - The amount actually used is returned as a count of bytes used (separately for each plane) rather than a count of scan lines. There is one added complication. To avoid allocating large amounts of storage, gs_image_next_planes may choose to copy only part of the data, retaining the rest of it by reference. Clients must be informed about this, since if the data is in a stream buffer, the data may move. To accommodate this possibility, on subsequent calls, any data passed by the client for a plane with retained data *replaces* the retained data rather than (as one might expect) appending to it; if the client passes no data for that plane, the retained data stays retained if needed. gs_image_next_planes returns information about retained data on each call, so the client need not keep track of it. The gs_image_planes_wanted procedure is analogous to planes_wanted. It identifies a plane as wanted if both of the following are true: - The underlying planes_wanted procedure says the plane is wanted. - Less than a full scan line of data is already buffered for that plane (including retained data if any). This is not sufficient information for the PostScript interpreter for the case where the data sources are procedures, which must be called in a cyclic order even if they return less than a full scan line. For this case, the interpreter must keep track of a plane index itself, cycling through the planes that gs_image_planes_wanted says are wanted (which may vary from cycle to cycle). There is an older, simpler procedure gs_image_next that simply cycles through the planes in order. It does not offer the option of replacing retained data, of passing data for more than one plane at a time, or of passing data for planes in an arbitrary order. Consequently, it is only usable with image types where all planes are always wanted. gs_image_next should also only be used when all planes have the same width and depth and the same amount of data is passed for each plane in a given cycle of calls. This is not currently checked; however, gs_image_next will give an error if an attempt is made to pass data for a plane that has any retained data. */ /* * The image painting interface uses an enumeration style: * the client initializes an enumerator, then supplies data incrementally. */ /* * Create an image enumerator given image parameters and a graphics state. * This calls the device's begin_typed_image procedure with appropriate * parameters. Note that this is an enumerator that requires entire * rows of data, not the buffered enumerator used by the procedures below: * for this reason, we may move the prototype elsewhere in the future. */ #ifndef gx_image_enum_common_t_DEFINED # define gx_image_enum_common_t_DEFINED typedef struct gx_image_enum_common_s gx_image_enum_common_t; #endif int gs_image_begin_typed(const gs_image_common_t * pic, gs_state * pgs, bool uses_color, gx_image_enum_common_t ** ppie); typedef struct gs_image_enum_s gs_image_enum; gs_image_enum *gs_image_enum_alloc(gs_memory_t *, client_name_t); /* * gs_image_init returns 1 for an empty image, 0 normally, <0 on error. * Note that gs_image_init serves for both image and imagemask, * depending on the value of ImageMask in the image structure. */ #ifndef gx_device_DEFINED # define gx_device_DEFINED typedef struct gx_device_s gx_device; #endif /* Initialize an enumerator for an ImageType 1 image. */ int gs_image_init(gs_image_enum * penum, const gs_image_t * pim, bool MultipleDataSources, gs_state * pgs); /* 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_state *pgs); /* * Return the number of bytes of data per row * (per plane, if there are multiple planes). */ uint gs_image_bytes_per_plane_row(const gs_image_enum * penum, int plane); #define gs_image_bytes_per_row(penum)\ gs_image_bytes_per_plane_row(penum, 0) /* * Return a byte vector indicating which planes (still) need data for the * current row. See above for details. */ const byte *gs_image_planes_wanted(gs_image_enum *penum); /* * Pass multiple or selected planes of data for an image. See above for * details. * * plane_data[] is an array of size num_planes of gs_const_string type * which contains the pointer and the length for each. * used[] is also of size num_planes and will be set to the number of * bytes consumed for each plane. * * The amount of data available for a plane (i.e., the size of a * plane_data[] element) can be 0 in order to provide data for a single * plane or only some of the planes. Note that if data is retained, * it is not "consumed": e.g., if all of the data for a given plane is * retained, used[] for that plane will be set to 0. * * Returns 1 if end of image, < 0 error code, otherwise 0. In any case, * stores pointers to the retained strings into plane_data[]. Note that * used[] and plane_data[] are set even in the error or end-of-image case. */ int gs_image_next_planes(gs_image_enum *penum, gs_const_string *plane_data, uint *used); /* Pass the next plane of data for an image. See above for details. */ int gs_image_next(gs_image_enum * penum, const byte * dbytes, uint dsize, uint * pused); /* Clean up after processing an image. */ int gs_image_cleanup(gs_image_enum * penum); /* Clean up after processing an image and free the enumerator. */ int gs_image_cleanup_and_free_enum(gs_image_enum * penum); #endif /* gsimage_INCLUDED */