path: root/gs/src/gxidata.c

/* Copyright (C) 1995, 1996, 1997, 1998, 1999, 2000 Aladdin Enterprises.  All rights reserved.

   This software is licensed to a single customer by Artifex Software Inc.
   under the terms of a specific OEM agreement.
 */

/*$RCSfile$ $Revision$ */
/* Generic image enumeration and cleanup */
#include "gx.h"
#include "memory_.h"
#include "gserrors.h"
#include "gxdevice.h"
#include "gxcpath.h"
#include "gximage.h"

/* Forward declarations */
private void update_strip(P1(gx_image_enum *penum));
private void repack_bit_planes(P7(const gx_image_plane_t *src_planes,
				  const ulong *offsets, int num_planes,
				  byte *buffer, int width,
				  const sample_lookup_t * ptab, int spread));
private gx_device *setup_image_device(P1(const gx_image_enum *penum));

/* Process the next piece of an ImageType 1 image. */
int
gx_image1_plane_data(gx_image_enum_common_t * info,
		     const gx_image_plane_t * planes, int height,
		     int *rows_used)
{
    gx_image_enum *penum = (gx_image_enum *) info;
    gx_device *dev;
    const int y = penum->y;
    int y_end = min(y + height, penum->rect.h);
    int width_spp = penum->rect.w * penum->spp;
    int num_planes = penum->num_planes;

#define BCOUNT(plane)		/* bytes per data row */\
  (((penum->rect.w + (plane).data_x) * penum->spp * penum->bps / num_planes\
    + 7) >> 3)

    fixed adjust = penum->adjust;
    ulong offsets[gs_image_max_planes];
    int ignore_data_x;
    bool bit_planar = penum->num_planes > penum->spp;
    int code;

    if (height == 0) {
	*rows_used = 0;
	return 0;
    }
    dev = setup_image_device(penum);

    /* Now render complete rows. */

    if (penum->used.y) {
	/*
	 * Processing was interrupted by an error.  Skip over rows
	 * already processed.
	 */
	int px;

	for (px = 0; px < num_planes; ++px)
	    offsets[px] = planes[px].raster * penum->used.y;
	penum->used.y = 0;
    } else
	memset(offsets, 0, num_planes * sizeof(offsets[0]));
    for (; penum->y < y_end; penum->y++) {
	int px;
	const byte *buffer;
	int sourcex;
	int x_used = penum->used.x;

	if (bit_planar) {
	    /* Repack the bit planes into byte-wide samples. */
	    
	    buffer = penum->buffer;
	    sourcex = 0;
	    for (px = 0; px < num_planes; px += penum->bps)
		repack_bit_planes(planes, offsets, penum->bps, penum->buffer,
				  penum->rect.w, &penum->map[0].table,
				  penum->spread);
	    for (px = 0; px < num_planes; ++px)
		offsets[px] += planes[px].raster;
	} else {
	    /*
	     * Normally, we unpack the data into the buffer, but if
	     * there is only one plane and we don't need to expand the
	     * input samples, we may use the data directly.
	     */
	    sourcex = planes[0].data_x;
	    buffer =
		(*penum->unpack)(penum->buffer, &sourcex,
				 planes[0].data + offsets[0],
				 planes[0].data_x, BCOUNT(planes[0]),
				 &penum->map[0].table, penum->spread);

	    offsets[0] += planes[0].raster;
	    for (px = 1; px < num_planes; ++px) {
		(*penum->unpack)(penum->buffer + (px << penum->log2_xbytes),
				 &ignore_data_x,
				 planes[px].data + offsets[px],
				 planes[px].data_x, BCOUNT(planes[px]),
				 &penum->map[px].table, penum->spread);
		offsets[px] += planes[px].raster;
	    }
	}
#ifdef DEBUG
	if (gs_debug_c('B')) {
	    int i, n = width_spp;

	    if (penum->bps > 8)
		n *= 2;
	    else if (penum->bps == 1 && penum->unpack_bps == 8)
		n = (n + 7) / 8;
	    dlputs("[B]row:");
	    for (i = 0; i < n; i++)
		dprintf1(" %02x", buffer[i]);
	    dputs("\n");
	}
#endif
	penum->cur.x = dda_current(penum->dda.row.x);
	dda_next(penum->dda.row.x);
	penum->cur.y = dda_current(penum->dda.row.y);
	dda_next(penum->dda.row.y);
	if (!penum->interpolate)
	    switch (penum->posture) {
		case image_portrait:
		    {		/* Precompute integer y and height, */
			/* and check for clipping. */
			fixed yc = penum->cur.y,
			    yn = dda_current(penum->dda.row.y);

			if (yn < yc) {
			    fixed temp = yn;

			    yn = yc;
			    yc = temp;
			}
			yc -= adjust;
			if (yc >= penum->clip_outer.q.y)
			    goto mt;
			yn += adjust;
			if (yn <= penum->clip_outer.p.y)
			    goto mt;
			penum->yci = fixed2int_pixround(yc);
			penum->hci = fixed2int_pixround(yn) - penum->yci;
			if (penum->hci == 0)
			    goto mt;
			if_debug2('b', "[b]yci=%d, hci=%d\n",
				  penum->yci, penum->hci);
		    }
		    break;
		case image_landscape:
		    {		/* Check for no pixel centers in x. */
			fixed xc = penum->cur.x,
			    xn = dda_current(penum->dda.row.x);

			if (xn < xc) {
			    fixed temp = xn;

			    xn = xc;
			    xc = temp;
			}
			xc -= adjust;
			if (xc >= penum->clip_outer.q.x)
			    goto mt;
			xn += adjust;
			if (xn <= penum->clip_outer.p.x)
			    goto mt;
			penum->xci = fixed2int_pixround(xc);
			penum->wci = fixed2int_pixround(xn) - penum->xci;
			if (penum->wci == 0)
			    goto mt;
			if_debug2('b', "[b]xci=%d, wci=%d\n",
				  penum->xci, penum->wci);
		    }
		    break;
		case image_skewed:
		    ;
	    }
	update_strip(penum);
	if (x_used) {
	    /*
	     * Processing was interrupted by an error.  Skip over pixels
	     * already processed.
	     */
	    dda_advance(penum->dda.pixel0.x, x_used);
	    dda_advance(penum->dda.pixel0.y, x_used);
	    penum->used.x = 0;
	}
	if_debug2('b', "[b]pixel0 x=%g, y=%g\n",
		  fixed2float(dda_current(penum->dda.pixel0.x)),
		  fixed2float(dda_current(penum->dda.pixel0.y)));
	code = (*penum->render)(penum, buffer, sourcex + x_used,
				width_spp - x_used * penum->spp, 1, dev);
	if (code < 0) {
	    /* Error or interrupt, restore original state. */
	    penum->used.x += x_used;
	    if (!penum->used.y) {
		dda_previous(penum->dda.row.x);
		dda_previous(penum->dda.row.y);
		dda_translate(penum->dda.strip.x,
			      penum->prev.x - penum->cur.x);
		dda_translate(penum->dda.strip.y,
			      penum->prev.y - penum->cur.y);
	    }
	    goto out;
	}
	penum->prev = penum->cur;
      mt:;
    }
    if (penum->y < penum->rect.h) {
	code = 0;
    } else {
	/* End of input data.  Render any left-over buffered data. */
	code = gx_image1_flush(info);
	if (code >= 0)
	    code = 1;
    }
out:
    /* Note that caller must call end_image */
    /* for both error and normal termination. */
    *rows_used = penum->y - y;
    return code;
}

/* Flush any buffered data. */
int
gx_image1_flush(gx_image_enum_common_t * info)
{
    gx_image_enum *penum = (gx_image_enum *)info;
    int width_spp = penum->rect.w * penum->spp;
    fixed adjust = penum->adjust;

    penum->cur.x = dda_current(penum->dda.row.x);
    penum->cur.y = dda_current(penum->dda.row.y);
    switch (penum->posture) {
	case image_portrait:
	    {
		fixed yc = penum->cur.y;

		penum->yci = fixed2int_rounded(yc - adjust);
		penum->hci = fixed2int_rounded(yc + adjust) - penum->yci;
	    }
	    break;
	case image_landscape:
	    {
		fixed xc = penum->cur.x;

		penum->xci = fixed2int_rounded(xc - adjust);
		penum->wci = fixed2int_rounded(xc + adjust) - penum->xci;
	    }
	    break;
	case image_skewed:	/* pacify compilers */
	    ;
    }
    update_strip(penum);
    penum->prev = penum->cur;
    return (*penum->render)(penum, NULL, 0, width_spp, 0,
			    setup_image_device(penum));
}

/* Update the strip DDA when moving to a new row. */
private void update_strip(gx_image_enum *penum)
{
    dda_translate(penum->dda.strip.x, penum->cur.x - penum->prev.x);
    dda_translate(penum->dda.strip.y, penum->cur.y - penum->prev.y);
    penum->dda.pixel0 = penum->dda.strip;
}

/*
 * Repack 1 to 8 individual bit planes into 8-bit samples.
 * buffer is aligned, and includes padding to an 8-byte boundary.
 * This procedure repacks one row, so the only relevant members of
 * src_planes are data and data_x (not raster).
 */
private void
repack_bit_planes(const gx_image_plane_t *src_planes, const ulong *offsets,
		  int num_planes, byte *buffer, int width,
		  const sample_lookup_t * ptab, int spread)
{
    gx_image_plane_t planes[8];
    byte *zeros = 0;
    byte *dest = buffer;
    int any_data_x = 0;
    bool direct = (spread == 1 && ptab->lookup8[0] == 0 &&
		   ptab->lookup8[255] == 255);
    int pi, x;
    gx_image_plane_t *pp;

    /*
     * Set up the row pointers, taking data_x and null planes into account.
     * If there are any null rows, we need to create a block of zeros in
     * order to avoid tests in the loop.
     */
    for (pi = 0, pp = planes; pi < num_planes; ++pi, ++pp)
	if (src_planes[pi].data == 0) {
	    if (!zeros) {
		zeros = buffer + width - ((width + 7) >> 3);
	    }
	    pp->data = zeros;
	    pp->data_x = 0;
	} else {
	    int dx = src_planes[pi].data_x;

	    pp->data = src_planes[pi].data + (dx >> 3) + offsets[pi];
	    any_data_x |= (pp->data_x = dx & 7);
	}
    if (zeros)
	memset(zeros, 0, buffer + width - zeros);

    /*
     * Now process the data, in blocks of one input byte column
     * (8 output bytes).
     */
    for (x = 0; x < width; x += 8) {
	bits32 w0 = 0, w1 = 0;
#if arch_is_big_endian
	static const bits32 expand[16] = {
	    0x00000000, 0x00000001, 0x00000100, 0x00000101,
	    0x00010000, 0x00010001, 0x00010100, 0x00010101,
	    0x01000000, 0x01000001, 0x01000100, 0x01000101,
	    0x01010000, 0x01010001, 0x01010100, 0x01010101
	};
#else
	static const bits32 expand[16] = {
	    0x00000000, 0x01000000, 0x00010000, 0x01010000,
	    0x00000100, 0x01000100, 0x00010100, 0x01010100,
	    0x00000001, 0x01000001, 0x00010001, 0x01010001,
	    0x00000101, 0x01000101, 0x00010101, 0x01010101
	};
#endif

	if (any_data_x) {
	    for (pi = 0, pp = planes; pi < num_planes; ++pi, ++pp) {
		uint b = *(pp->data++);
		int dx = pp->data_x;

		if (dx) {
		    b <<= dx;
		    if (x + 8 - dx < width)
			b += *pp->data >> (8 - dx);
		}
		w0 = (w0 << 1) | expand[b >> 4];
		w1 = (w1 << 1) | expand[b & 0xf];
	    }
	} else {
	    for (pi = 0, pp = planes; pi < num_planes; ++pi, ++pp) {
		uint b = *(pp->data++);

		w0 = (w0 << 1) | expand[b >> 4];
		w1 = (w1 << 1) | expand[b & 0xf];
	    }
	}
	/*
	 * We optimize spread == 1 and identity ptab together, although
	 * we could subdivide these 2 cases into 4 if we wanted.
	 */
	if (direct) {
	    ((bits32 *)dest)[0] = w0;
	    ((bits32 *)dest)[1] = w1;
	    dest += 8;
	} else {
#define MAP_BYTE(v) (ptab->lookup8[(byte)(v)])
	    dest[0] = MAP_BYTE(w0 >> 24); dest += spread;
	    dest[1] = MAP_BYTE(w0 >> 16); dest += spread;
	    dest[2] = MAP_BYTE(w0 >> 8); dest += spread;
	    dest[3] = MAP_BYTE(w0); dest += spread;
	    dest[4] = MAP_BYTE(w1 >> 24); dest += spread;
	    dest[5] = MAP_BYTE(w1 >> 16); dest += spread;
	    dest[6] = MAP_BYTE(w1 >> 8); dest += spread;
	    dest[7] = MAP_BYTE(w1); dest += spread;
#undef MAP_BYTE
	}
    }
}

/* Set up the device for drawing an image. */
private gx_device *
setup_image_device(const gx_image_enum *penum)
{
    gx_device *dev = penum->dev;

    if (penum->clip_dev) {
	gx_device_clip *cdev = penum->clip_dev;

	gx_device_set_target((gx_device_forward *)cdev, dev);
	dev = (gx_device *) cdev;
    }
    if (penum->rop_dev) {
	gx_device_rop_texture *rtdev = penum->rop_dev;

	gx_device_set_target((gx_device_forward *)rtdev, dev);
	dev = (gx_device *) rtdev;
    }
    return dev;
}

/* Clean up by releasing the buffers. */
/* Currently we ignore draw_last. */
int
gx_image1_end_image(gx_image_enum_common_t * info, bool draw_last)
{
    gx_image_enum *penum = (gx_image_enum *) info;
    gs_memory_t *mem = penum->memory;
    stream_image_scale_state *scaler = penum->scaler;

    if_debug2('b', "[b]%send_image, y=%d\n",
	      (penum->y < penum->rect.h ? "premature " : ""), penum->y);
    if (draw_last) {
	int code = gx_image_flush(info);

	if (code < 0)
	    return code;
    }
    gs_free_object(mem, penum->rop_dev, "image RasterOp");
    gs_free_object(mem, penum->clip_dev, "image clipper");
    if (scaler != 0) {
	(*scaler->template->release) ((stream_state *) scaler);
	gs_free_object(mem, scaler, "image scaler state");
    }
    gs_free_object(mem, penum->line, "image line");
    gs_free_object(mem, penum->buffer, "image buffer");
    gs_free_object(mem, penum, "gx_default_end_image");
    return 0;
}