/* Copyright (C) 2001-2012 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.,  7 Mt. Lassen Drive - Suite A-134, San Rafael,
   CA  94903, U.S.A., +1(415)492-9861, for further information.
*/


/* PhotoShop (PSD) export device, supporting DeviceN color models. */

#include "math_.h"
#include "gdevprn.h"
#include "gsparam.h"
#include "gscrd.h"
#include "gscrdp.h"
#include "gxlum.h"
#include "gdevdcrd.h"
#include "gstypes.h"
#include "gxdcconv.h"
#include "gdevdevn.h"
#include "gsequivc.h"
#include "gscms.h"
#include "gsicc_cache.h"
#include "gsicc_manage.h"
#include "gxgetbit.h"
#include "gdevppla.h"
#include "gxdownscale.h"

#ifndef cmm_gcmmhlink_DEFINED
    #define cmm_gcmmhlink_DEFINED
    typedef void* gcmmhlink_t;
#endif

#ifndef cmm_gcmmhprofile_DEFINED
    #define cmm_gcmmhprofile_DEFINED
    typedef void* gcmmhprofile_t;
#endif

#ifndef MAX_CHAN
#   define MAX_CHAN 15
#endif

/* Enable logic for a local ICC output profile. */
#define ENABLE_ICC_PROFILE 0

/* Define the device parameters. */
#ifndef X_DPI
#  define X_DPI 72
#endif
#ifndef Y_DPI
#  define Y_DPI 72
#endif

/* The device descriptor */
static dev_proc_open_device(psd_prn_open);
static dev_proc_close_device(psd_prn_close);
static dev_proc_get_params(psd_get_params);
static dev_proc_put_params(psd_put_params);
static dev_proc_print_page(psd_print_page);
static dev_proc_map_color_rgb(psd_map_color_rgb);
static dev_proc_get_color_mapping_procs(get_psdrgb_color_mapping_procs);
static dev_proc_get_color_mapping_procs(get_psd_color_mapping_procs);
static dev_proc_get_color_comp_index(psd_get_color_comp_index);
static dev_proc_encode_color(psd_encode_color);
static dev_proc_decode_color(psd_decode_color);
static dev_proc_update_spot_equivalent_colors(psd_update_spot_equivalent_colors);
static dev_proc_ret_devn_params(psd_ret_devn_params);

/* This is redundant with color_info.cm_name. We may eliminate this
   typedef and use the latter string for everything. */
typedef enum {
    psd_DEVICE_GRAY,
    psd_DEVICE_RGB,
    psd_DEVICE_CMYK,
    psd_DEVICE_N
} psd_color_model;

/*
 * A structure definition for a DeviceN type device
 */
typedef struct psd_device_s {
    gx_device_common;
    gx_prn_device_common;

    /*        ... device-specific parameters ... */

    gs_devn_params devn_params;		/* DeviceN generated parameters */

    equivalent_cmyk_color_params equiv_cmyk_colors;

    psd_color_model color_model;

    long downscale_factor;
    int max_spots;

    /* ICC color profile objects, for color conversion.
       These are all device link profiles.  At least that
       is how it appears looking at how this code
       was written to work with the old icclib.  Just
       doing minimal updates here so that it works
       with the new CMM API.  I would be interested
       to hear how people are using this. */

    char profile_rgb_fn[256];
    cmm_profile_t *rgb_profile;
    gcmmhlink_t rgb_icc_link;

    char profile_cmyk_fn[256];
    cmm_profile_t *cmyk_profile;
    gcmmhlink_t cmyk_icc_link;

    char profile_out_fn[256];
    cmm_profile_t *output_profile;
    gcmmhlink_t output_icc_link;

    bool warning_given;  /* Used to notify the user that max colorants reached */

} psd_device;

/* GC procedures */
static
ENUM_PTRS_WITH(psd_device_enum_ptrs, psd_device *pdev)
{
    if (index == 0)
        ENUM_RETURN(pdev->devn_params.compressed_color_list);
    index--;
    if (index == 0)
        ENUM_RETURN(pdev->devn_params.pdf14_compressed_color_list);
    index--;
    if (index < pdev->devn_params.separations.num_separations)
        ENUM_RETURN(pdev->devn_params.separations.names[index].data);
    ENUM_PREFIX(st_device_printer,
                    pdev->devn_params.separations.num_separations);
    return 0;
}
ENUM_PTRS_END

static RELOC_PTRS_WITH(psd_device_reloc_ptrs, psd_device *pdev)
{
    RELOC_PREFIX(st_device_printer);
    {
        int i;

        for (i = 0; i < pdev->devn_params.separations.num_separations; ++i) {
            RELOC_PTR(psd_device, devn_params.separations.names[i].data);
        }
    }
    RELOC_PTR(psd_device, devn_params.compressed_color_list);
    RELOC_PTR(psd_device, devn_params.pdf14_compressed_color_list);
}
RELOC_PTRS_END

/* Even though psd_device_finalize is the same as gx_device_finalize, */
/* we need to implement it separately because st_composite_final */
/* declares all 3 procedures as private. */
static void
psd_device_finalize(const gs_memory_t *cmem, void *vpdev)
{
    /* We need to deallocate the compressed_color_list.
       and the names. */
    devn_free_params((gx_device*) vpdev);
    gx_device_finalize(cmem, vpdev);
}

gs_private_st_composite_final(st_psd_device, psd_device,
    "psd_device", psd_device_enum_ptrs, psd_device_reloc_ptrs,
    psd_device_finalize);

/*
 * Macro definition for psd device procedures
 */
#define device_procs(get_color_mapping_procs, encode_color, decode_color)\
{	psd_prn_open,\
        gx_default_get_initial_matrix,\
        NULL,				/* sync_output */\
        gdev_prn_output_page,		/* output_page */\
        psd_prn_close,			/* close */\
        NULL,				/* map_rgb_color - not used */\
        psd_map_color_rgb,		/* map_color_rgb */\
        NULL,				/* fill_rectangle */\
        NULL,				/* tile_rectangle */\
        NULL,				/* copy_mono */\
        NULL,				/* copy_color */\
        NULL,				/* draw_line */\
        NULL,				/* get_bits */\
        psd_get_params,			/* get_params */\
        psd_put_params,			/* put_params */\
        NULL,				/* map_cmyk_color - not used */\
        NULL,				/* get_xfont_procs */\
        NULL,				/* get_xfont_device */\
        NULL,				/* map_rgb_alpha_color */\
        gx_page_device_get_page_device,	/* get_page_device */\
        NULL,				/* get_alpha_bits */\
        NULL,				/* copy_alpha */\
        NULL,				/* get_band */\
        NULL,				/* copy_rop */\
        NULL,				/* fill_path */\
        NULL,				/* stroke_path */\
        NULL,				/* fill_mask */\
        NULL,				/* fill_trapezoid */\
        NULL,				/* fill_parallelogram */\
        NULL,				/* fill_triangle */\
        NULL,				/* draw_thin_line */\
        NULL,				/* begin_image */\
        NULL,				/* image_data */\
        NULL,				/* end_image */\
        NULL,				/* strip_tile_rectangle */\
        NULL,				/* strip_copy_rop */\
        NULL,				/* get_clipping_box */\
        NULL,				/* begin_typed_image */\
        NULL,				/* get_bits_rectangle */\
        NULL,				/* map_color_rgb_alpha */\
        NULL,				/* create_compositor */\
        NULL,				/* get_hardware_params */\
        NULL,				/* text_begin */\
        NULL,				/* finish_copydevice */\
        NULL,				/* begin_transparency_group */\
        NULL,				/* end_transparency_group */\
        NULL,				/* begin_transparency_mask */\
        NULL,				/* end_transparency_mask */\
        NULL,				/* discard_transparency_layer */\
        get_color_mapping_procs,	/* get_color_mapping_procs */\
        psd_get_color_comp_index,	/* get_color_comp_index */\
        encode_color,			/* encode_color */\
        decode_color,			/* decode_color */\
        NULL,				/* pattern_manage */\
        NULL,				/* fill_rectangle_hl_color */\
        NULL,				/* include_color_space */\
        NULL,				/* fill_linear_color_scanline */\
        NULL,				/* fill_linear_color_trapezoid */\
        NULL,				/* fill_linear_color_triangle */\
        psd_update_spot_equivalent_colors, /* update_spot_equivalent_colors */\
        psd_ret_devn_params		/* ret_devn_params */\
}

static fixed_colorant_name DeviceGrayComponents[] = {
        "Gray",
        0		/* List terminator */
};

static fixed_colorant_name DeviceRGBComponents[] = {
        "Red",
        "Green",
        "Blue",
        0		/* List terminator */
};

#define psd_device_body(procs, dname, ncomp, pol, depth, mg, mc, sl, cn)\
    std_device_full_body_type_extended(psd_device, &procs, dname,\
          &st_psd_device,\
          (int)((long)(DEFAULT_WIDTH_10THS) * (X_DPI) / 10),\
          (int)((long)(DEFAULT_HEIGHT_10THS) * (Y_DPI) / 10),\
          X_DPI, Y_DPI,\
          GX_DEVICE_COLOR_MAX_COMPONENTS,	/* MaxComponents */\
          ncomp,		/* NumComp */\
          pol,			/* Polarity */\
          depth, 0,		/* Depth, GrayIndex */\
          mg, mc,		/* MaxGray, MaxColor */\
          mg + 1, mc + 1,	/* DitherGray, DitherColor */\
          sl,			/* Linear & Separable? */\
          cn,			/* Process color model name */\
          0, 0,			/* offsets */\
          0, 0, 0, 0		/* margins */\
        ),\
        prn_device_body_rest_(psd_print_page)

/*
 * PSD device with RGB process color model.
 */
static const gx_device_procs spot_rgb_procs =
    device_procs(get_psdrgb_color_mapping_procs, psd_encode_color, psd_decode_color);

const psd_device gs_psdrgb_device =
{
    psd_device_body(spot_rgb_procs, "psdrgb", 3, GX_CINFO_POLARITY_ADDITIVE, 24, 255, 255, GX_CINFO_SEP_LIN, "DeviceRGB"),
    /* devn_params specific parameters */
    { 8,	/* Bits per color - must match ncomp, depth, etc. above */
      DeviceRGBComponents,	/* Names of color model colorants */
      3,			/* Number colorants for RGB */
      0,			/* MaxSeparations has not been specified */
      -1,			/* PageSpotColors has not been specified */
      {0},			/* SeparationNames */
      0,			/* SeparationOrder names */
      {0, 1, 2, 3, 4, 5, 6, 7 }	/* Initial component SeparationOrder */
    },
    { true },			/* equivalent CMYK colors for spot colors */
    /* PSD device specific parameters */
    psd_DEVICE_RGB,		/* Color model */
    1,                          /* downscale_factor */
    GS_SOFT_MAX_SPOTS           /* max_spots */
};

/*
 * Select the default number of components based upon the number of bits
 * that we have in a gx_color_index.  If we have 64 bits then we can compress
 * the colorant data.  This allows us to handle more colorants.  However the
 * compressed encoding is not separable.  If we do not have 64 bits then we
 * use a simple non-compressable encoding.
 */
#define NC ARCH_SIZEOF_GX_COLOR_INDEX
#define SL GX_CINFO_SEP_LIN
#define ENCODE_COLOR psd_encode_color
#define DECODE_COLOR psd_decode_color
#define GCIB (ARCH_SIZEOF_GX_COLOR_INDEX * 8)

/*
 * PSD device with CMYK process color model and spot color support.
 */
static const gx_device_procs spot_cmyk_procs
        = device_procs(get_psd_color_mapping_procs, ENCODE_COLOR, DECODE_COLOR);

const psd_device gs_psdcmyk_device =
{
    psd_device_body(spot_cmyk_procs, "psdcmyk", NC, GX_CINFO_POLARITY_SUBTRACTIVE, GCIB, 255, 255, SL, "DeviceCMYK"),
    /* devn_params specific parameters */
    { 8,	/* Bits per color - must match ncomp, depth, etc. above */
      DeviceCMYKComponents,	/* Names of color model colorants */
      4,			/* Number colorants for CMYK */
      0,			/* MaxSeparations has not been specified */
      -1,			/* PageSpotColors has not been specified */
      {0},			/* SeparationNames */
      0,			/* SeparationOrder names */
      {0, 1, 2, 3, 4, 5, 6, 7 }	/* Initial component SeparationOrder */
    },
    { true },			/* equivalent CMYK colors for spot colors */
    /* PSD device specific parameters */
    psd_DEVICE_CMYK,		/* Color model */
    1,                          /* downscale_factor */
    GS_SOFT_MAX_SPOTS           /* max_spots */
};

#undef NC
#undef SL
#undef ENCODE_COLOR
#undef DECODE_COLOR

/* Open the psd devices */
int
psd_prn_open(gx_device * pdev)
{
    psd_device *pdev_psd = (psd_device *) pdev;
    int code;
    int k;

    pdev_psd->warning_given = false;
    /* With planar the depth can be more than 64.  Update the color
       info to reflect the proper depth and number of planes.  Also note
       that the number of spot colors can change from page to page.  
       Update things so that we only output separations for the
       inks on that page. */
    if (pdev_psd->devn_params.page_spot_colors >= 0) {
        pdev->color_info.num_components = 
            (pdev_psd->devn_params.page_spot_colors 
                                 + pdev_psd->devn_params.num_std_colorant_names);
        if (pdev->color_info.num_components > pdev->color_info.max_components)
            pdev->color_info.num_components = pdev->color_info.max_components;
    } else {
        /* We do not know how many spots may occur on the page. 
           For this reason we go ahead and allocate the maximum that we
           have available.  Note, lack of knowledge only occurs in the case
           of PS files.  With PDF we know a priori the number of spot
           colorants.  */
        int num_comp = pdev_psd->max_spots + 4; /* Spots + CMYK */
        if (num_comp > GS_CLIENT_COLOR_MAX_COMPONENTS)
            num_comp = GS_CLIENT_COLOR_MAX_COMPONENTS;
        pdev->color_info.num_components = num_comp;
        pdev->color_info.max_components = num_comp;
    }
    /* Push this to the max amount as a default if someone has not set it */
    if (pdev_psd->devn_params.num_separation_order_names == 0)
        for (k = 0; k < GS_CLIENT_COLOR_MAX_COMPONENTS; k++) {
            pdev_psd->devn_params.separation_order_map[k] = k;
        }
    pdev->color_info.depth = pdev->color_info.num_components * 
                             pdev_psd->devn_params.bitspercomponent;
    pdev->color_info.separable_and_linear = GX_CINFO_SEP_LIN;
    pdev->icc_struct->supports_devn = true;
    code = gdev_prn_open_planar(pdev, true);
    return code;
}

/* 2007/05/04
psdgray device
*/
static void
gray_cs_to_psdgray_cm(gx_device * dev, frac gray, frac out[])
{
    out[0] = gray;
}

static void
rgb_cs_to_psdgray_cm(gx_device * dev, const gs_imager_state *pis,
                                   frac r, frac g, frac b, frac out[])
{
    out[0] = color_rgb_to_gray(r, g, b, NULL);
}

static void
cmyk_cs_to_psdgray_cm(gx_device * dev, frac c, frac m, frac y, frac k, frac out[])
{
    out[0] = color_cmyk_to_gray(c, m, y, k, NULL);
}

/*
 * The following procedures are used to map the standard color spaces into
 * the color components for the psdrgb device.
 */
static void
gray_cs_to_psdrgb_cm(gx_device * dev, frac gray, frac out[])
{
    int i = ((psd_device *)dev)->devn_params.separations.num_separations;

    out[0] = out[1] = out[2] = gray;
    for(; i>0; i--)			/* Clear spot colors */
        out[2 + i] = 0;
}

static void
rgb_cs_to_psdrgb_cm(gx_device * dev, const gs_imager_state *pis,
                                  frac r, frac g, frac b, frac out[])
{
    int i = ((psd_device *)dev)->devn_params.separations.num_separations;

    out[0] = r;
    out[1] = g;
    out[2] = b;
    for(; i>0; i--)			/* Clear spot colors */
        out[2 + i] = 0;
}

static void
cmyk_cs_to_psdrgb_cm(gx_device * dev,
                        frac c, frac m, frac y, frac k, frac out[])
{
    int i = ((psd_device *)dev)->devn_params.separations.num_separations;

    color_cmyk_to_rgb(c, m, y, k, NULL, out, dev->memory);
    for(; i>0; i--)			/* Clear spot colors */
        out[2 + i] = 0;
}

/* Color mapping routines for the psdcmyk device */

static void
gray_cs_to_psdcmyk_cm(gx_device * dev, frac gray, frac out[])
{
    int * map = ((psd_device *) dev)->devn_params.separation_order_map;

    gray_cs_to_devn_cm(dev, map, gray, out);
}

static void
rgb_cs_to_psdcmyk_cm(gx_device * dev, const gs_imager_state *pis,
                           frac r, frac g, frac b, frac out[])
{
    int * map = ((psd_device *) dev)->devn_params.separation_order_map;

    rgb_cs_to_devn_cm(dev, map, pis, r, g, b, out);
}

static void
cmyk_cs_to_psdcmyk_cm(gx_device * dev,
                        frac c, frac m, frac y, frac k, frac out[])
{
    const gs_devn_params *devn = psd_ret_devn_params(dev);
    const int *map = devn->separation_order_map;
    int j;
    
    if (devn->num_separation_order_names > 0) {
        /* This is to set only those that we are using */
        for (j = 0; j < devn->num_separation_order_names; j++) {
            switch (map[j]) {
                case 0 : 
                    out[0] = c;
                    break;
                case 1:
                    out[1] = m;
                    break;
                case 2:
                    out[2] = y;
                    break;
                case 3:
                    out[3] = k;
                    break;
                default:
                    break;
            }
        }
    } else {
        cmyk_cs_to_devn_cm(dev, map, c, m, y, k, out);
    }
}

static void
cmyk_cs_to_spotn_cm(gx_device * dev, frac c, frac m, frac y, frac k, frac out[])
{
    psd_device *xdev = (psd_device *)dev;
    int n = xdev->devn_params.separations.num_separations;

    gcmmhlink_t link = xdev->cmyk_icc_link;
    int i;

    if (link != NULL) {

        unsigned short in[4];
        unsigned short tmp[MAX_CHAN];
        int outn = xdev->cmyk_profile->num_comps_out;

        in[0] = frac2ushort(c);
        in[1] = frac2ushort(m);
        in[2] = frac2ushort(y);
        in[3] = frac2ushort(k);

        gscms_transform_color(dev, link, &(in[0]),
                        &(tmp[0]), 2);

        for (i = 0; i < outn; i++)
            out[i] = ushort2frac(tmp[i]);
        for (; i < n + 4; i++)
            out[i] = 0;

    } else {
        /* If no profile given, assume CMYK */
        out[0] = c;
        out[1] = m;
        out[2] = y;
        out[3] = k;
        for(i = 0; i < n; i++)			/* Clear spot colors */
            out[4 + i] = 0;
    }
}

static void
gray_cs_to_spotn_cm(gx_device * dev, frac gray, frac out[])
{
    cmyk_cs_to_spotn_cm(dev, 0, 0, 0, (frac)(frac_1 - gray), out);
}

static void
rgb_cs_to_spotn_cm(gx_device * dev, const gs_imager_state *pis,
                                   frac r, frac g, frac b, frac out[])
{
    psd_device *xdev = (psd_device *)dev;
    int n = xdev->devn_params.separations.num_separations;
    gcmmhlink_t link = xdev->rgb_icc_link;
    int i;

    if (link != NULL) {

        unsigned short in[3];
        unsigned short tmp[MAX_CHAN];
        int outn = xdev->rgb_profile->num_comps_out;

        in[0] = frac2ushort(r);
        in[1] = frac2ushort(g);
        in[2] = frac2ushort(b);

        gscms_transform_color(dev, link, &(in[0]),
                        &(tmp[0]), 2);

        for (i = 0; i < outn; i++)
            out[i] = ushort2frac(tmp[i]);
        for (; i < n + 4; i++)
            out[i] = 0;

    } else {
        frac cmyk[4];

        color_rgb_to_cmyk(r, g, b, pis, cmyk, dev->memory);
        cmyk_cs_to_spotn_cm(dev, cmyk[0], cmyk[1], cmyk[2], cmyk[3],
                            out);
    }
}

static const gx_cm_color_map_procs psdGray_procs = {/* 2007/05/04 Test */
    gray_cs_to_psdgray_cm, rgb_cs_to_psdgray_cm, cmyk_cs_to_psdgray_cm
};

static const gx_cm_color_map_procs psdRGB_procs = {
    gray_cs_to_psdrgb_cm, rgb_cs_to_psdrgb_cm, cmyk_cs_to_psdrgb_cm
};

static const gx_cm_color_map_procs psdCMYK_procs = {
    gray_cs_to_psdcmyk_cm, rgb_cs_to_psdcmyk_cm, cmyk_cs_to_psdcmyk_cm
};

static const gx_cm_color_map_procs psdN_procs = {
    gray_cs_to_spotn_cm, rgb_cs_to_spotn_cm, cmyk_cs_to_spotn_cm
};

/*
 * These are the handlers for returning the list of color space
 * to color model conversion routines.
 */
static const gx_cm_color_map_procs *
get_psdrgb_color_mapping_procs(const gx_device * dev)
{
    return &psdRGB_procs;
}

static const gx_cm_color_map_procs *
get_psd_color_mapping_procs(const gx_device * dev)
{
    const psd_device *xdev = (const psd_device *)dev;

    if (xdev->color_model == psd_DEVICE_RGB)
        return &psdRGB_procs;
    else if (xdev->color_model == psd_DEVICE_CMYK)
        return &psdCMYK_procs;
    else if (xdev->color_model == psd_DEVICE_N)
        return &psdN_procs;
    else if (xdev->color_model == psd_DEVICE_GRAY)
        return &psdGray_procs;
    else
        return NULL;
}

/*
 * Encode a list of colorant values into a gx_color_index_value.
 */
static gx_color_index
psd_encode_color(gx_device *dev, const gx_color_value colors[])
{
    int bpc = ((psd_device *)dev)->devn_params.bitspercomponent;
    gx_color_index color = 0;
    int i = 0;
    int ncomp = dev->color_info.num_components;
    COLROUND_VARS;

    COLROUND_SETUP(bpc);
    for (; i<ncomp; i++) {
        color <<= bpc;
        color |= COLROUND_ROUND(colors[ncomp-1-i]);
    }
    return (color == gx_no_color_index ? color ^ 1 : color);
}

/*
 * Decode a gx_color_index value back to a list of colorant values.
 */
static int
psd_decode_color(gx_device * dev, gx_color_index color, gx_color_value * out)
{
    int bpc = ((psd_device *)dev)->devn_params.bitspercomponent;
    int mask = (1 << bpc) - 1;
    int i = 0;
    int ncomp = dev->color_info.num_components;
    COLDUP_VARS;

    COLDUP_SETUP(bpc);
    for (; i<ncomp; i++) {
        out[i] = COLDUP_DUP(color & mask);
        color >>= bpc;
    }
    return 0;
}

/*
 * Convert a gx_color_index to RGB.
 */
static int
psd_map_color_rgb(gx_device *dev, gx_color_index color, gx_color_value rgb[3])
{
    psd_device *xdev = (psd_device *)dev;

    if (xdev->color_model == psd_DEVICE_RGB)
        return psd_decode_color(dev, color, rgb);
    /* TODO: return reasonable values. */
    rgb[0] = 0;
    rgb[1] = 0;
    rgb[2] = 0;
    return 0;
}

/*
 *  Device proc for updating the equivalent CMYK color for spot colors.
 */
static int
psd_update_spot_equivalent_colors(gx_device *pdev, const gs_state * pgs)
{
    psd_device * psdev = (psd_device *)pdev;

    update_spot_equivalent_cmyk_colors(pdev, pgs,
                    &psdev->devn_params, &psdev->equiv_cmyk_colors);
    return 0;
}

/*
 *  Device proc for returning a pointer to DeviceN parameter structure
 */
static gs_devn_params *
psd_ret_devn_params(gx_device * dev)
{
    psd_device * pdev = (psd_device *)dev;

    return &pdev->devn_params;
}

#if ENABLE_ICC_PROFILE
static int
psd_open_profile(const char *profile_out_fn, cmm_profile_t *icc_profile, gcmmhlink_t icc_link, gs_memory_t *memory)
{

    gsicc_rendering_param_t rendering_params;

    icc_profile = gsicc_get_profile_handle_file(profile_out_fn,
                    strlen(profile_out_fn), memory);

    if (icc_profile == NULL)
        return gs_throw(-1, "Could not create profile for psd device");

    /* Set up the rendering parameters */

    rendering_params.black_point_comp = false;
    rendering_params.graphics_type_tag = GS_UNKNOWN_TAG;  /* Already rendered */
    rendering_params.rendering_intent = gsPERCEPTUAL;

    /* Call with a NULL destination profile since we are using a device link profile here */
    icc_link = gscms_get_link(icc_profile,
                    NULL, &rendering_params);

    if (icc_link == NULL)
        return gs_throw(-1, "Could not create link handle for psd device");

    return(0);

}

static int
psd_open_profiles(psd_device *xdev)
{
    int code = 0;

    if (xdev->output_icc_link == NULL && xdev->profile_out_fn[0]) {

        code = psd_open_profile(xdev->profile_out_fn, xdev->output_profile,
            xdev->output_icc_link, xdev->memory);

    }

    if (code >= 0 && xdev->rgb_icc_link == NULL && xdev->profile_rgb_fn[0]) {

        code = psd_open_profile(xdev->profile_rgb_fn, xdev->rgb_profile,
            xdev->rgb_icc_link, xdev->memory);

    }

    if (code >= 0 && xdev->cmyk_icc_link == NULL && xdev->profile_cmyk_fn[0]) {

        code = psd_open_profile(xdev->profile_cmyk_fn, xdev->cmyk_profile,
            xdev->cmyk_icc_link, xdev->memory);

    }

    return code;

}
#endif

/* Get parameters.  We provide a default CRD. */
static int
psd_get_params(gx_device * pdev, gs_param_list * plist)
{
    psd_device *xdev = (psd_device *)pdev;
    int code;
#if ENABLE_ICC_PROFILE
    gs_param_string pos;
    gs_param_string prgbs;
    gs_param_string pcmyks;
#endif

    code = gdev_prn_get_params(pdev, plist);
    if (code < 0)
        return code;
    code = devn_get_params(pdev, plist,
        &(xdev->devn_params), &(xdev->equiv_cmyk_colors));
    if (code < 0)
        return code;

#if ENABLE_ICC_PROFILE
    pos.data = (const byte *)xdev->profile_out_fn,
        pos.size = strlen(xdev->profile_out_fn),
        pos.persistent = false;
    code = param_write_string(plist, "ProfileOut", &pos);
    if (code < 0)
        return code;

    prgbs.data = (const byte *)xdev->profile_rgb_fn,
        prgbs.size = strlen(xdev->profile_rgb_fn),
        prgbs.persistent = false;
    code = param_write_string(plist, "ProfileRgb", &prgbs);
    if (code < 0)
        return code;

    pcmyks.data = (const byte *)xdev->profile_cmyk_fn,
        pcmyks.size = strlen(xdev->profile_cmyk_fn),
        pcmyks.persistent = false;
    code = param_write_string(plist, "ProfileCmyk", &prgbs);
    if (code < 0)
        return code;
#endif
    code = param_write_long(plist, "DownScaleFactor", &xdev->downscale_factor);
    if (code < 0)
        return code;
    code = param_write_int(plist, "MaxSpots", &xdev->max_spots);
    if (code < 0)
        return code;

    return code;
}

#if ENABLE_ICC_PROFILE
static int
psd_param_read_fn(gs_param_list *plist, const char *name,
                  gs_param_string *pstr, uint max_len)
{
    int code = param_read_string(plist, name, pstr);

    if (code == 0) {
        if (pstr->size >= max_len)
            param_signal_error(plist, name, code = gs_error_rangecheck);
    } else {
        pstr->data = 0;
    }
    return code;
}
#endif

/* Compare a C string and a gs_param_string. */
static bool
param_string_eq(const gs_param_string *pcs, const char *str)
{
    return (strlen(str) == pcs->size &&
            !strncmp(str, (const char *)pcs->data, pcs->size));
}

static int
psd_set_color_model(psd_device *xdev, psd_color_model color_model)
{
    xdev->color_model = color_model;
    if (color_model == psd_DEVICE_GRAY) {
        xdev->devn_params.std_colorant_names = DeviceGrayComponents;
        xdev->devn_params.num_std_colorant_names = 1;
        xdev->color_info.cm_name = "DeviceGray";
        xdev->color_info.polarity = GX_CINFO_POLARITY_ADDITIVE;
    } else if (color_model == psd_DEVICE_RGB) {
        xdev->devn_params.std_colorant_names = DeviceRGBComponents;
        xdev->devn_params.num_std_colorant_names = 3;
        xdev->color_info.cm_name = "DeviceRGB";
        xdev->color_info.polarity = GX_CINFO_POLARITY_ADDITIVE;
    } else if (color_model == psd_DEVICE_CMYK) {
        xdev->devn_params.std_colorant_names = DeviceCMYKComponents;
        xdev->devn_params.num_std_colorant_names = 4;
        xdev->color_info.cm_name = "DeviceCMYK";
        xdev->color_info.polarity = GX_CINFO_POLARITY_SUBTRACTIVE;
    } else if (color_model == psd_DEVICE_N) {
        xdev->devn_params.std_colorant_names = DeviceCMYKComponents;
        xdev->devn_params.num_std_colorant_names = 4;
        xdev->color_info.cm_name = "DeviceN";
        xdev->color_info.polarity = GX_CINFO_POLARITY_SUBTRACTIVE;
    } else {
        return -1;
    }

    return 0;
}

/* Set parameters.  We allow setting the number of bits per component. */
static int
psd_put_params(gx_device * pdev, gs_param_list * plist)
{
    psd_device * const pdevn = (psd_device *) pdev;
    int code = 0;
#if ENABLE_ICC_PROFILE
    gs_param_string po;
    gs_param_string prgb;
    gs_param_string pcmyk;
#endif
    gs_param_string pcm;
    psd_color_model color_model = pdevn->color_model;
    gx_device_color_info save_info = pdevn->color_info;

    switch (code = param_read_long(plist,
                                   "DownScaleFactor",
                                   &pdevn->downscale_factor)) {
        case 0:
            if (pdevn->downscale_factor <= 0)
                pdevn->downscale_factor = 1;
            break;
        case 1:
            break;
        default:
            param_signal_error(plist, "DownScaleFactor", code);
            return code;
    }

    switch (code = param_read_int(plist,
                                  "MaxSpots",
                                  &pdevn->max_spots)) {
        case 0:
            if (pdevn->max_spots >= 0 && pdevn->max_spots <= GS_CLIENT_COLOR_MAX_COMPONENTS-4)
                break;
            emprintf1(pdevn->memory, "MaxSpots must be between 0 and %d\n",
                      GS_CLIENT_COLOR_MAX_COMPONENTS-4);
            code = gs_error_rangecheck;
            /* fall through */
        default:
            param_signal_error(plist, "MaxSpots", code);
            return code;
        case 1:
            break;
    }

#if ENABLE_ICC_PROFILE
    code = psd_param_read_fn(plist, "ProfileOut", &po,
                                 sizeof(pdevn->profile_out_fn));
    if (code >= 0)
        code = psd_param_read_fn(plist, "ProfileRgb", &prgb,
                                 sizeof(pdevn->profile_rgb_fn));
    if (code >= 0)
        code = psd_param_read_fn(plist, "ProfileCmyk", &pcmyk,
                                 sizeof(pdevn->profile_cmyk_fn));
#endif

    if (code >= 0)
        code = param_read_name(plist, "ProcessColorModel", &pcm);
    if (code == 0) {
        if (param_string_eq (&pcm, "DeviceGray"))
            color_model = psd_DEVICE_GRAY;
        else if (param_string_eq (&pcm, "DeviceRGB"))
            color_model = psd_DEVICE_RGB;
        else if (param_string_eq (&pcm, "DeviceCMYK"))
            color_model = psd_DEVICE_CMYK;
        else if (param_string_eq (&pcm, "DeviceN"))
            color_model = psd_DEVICE_N;
        else {
            param_signal_error(plist, "ProcessColorModel",
                               code = gs_error_rangecheck);
        }
    }

    if (code >= 0)
        code = psd_set_color_model(pdevn, color_model);

    /* handle the standard DeviceN related parameters */
    if (code == 0)
        code = devn_printer_put_params(pdev, plist,
                &(pdevn->devn_params), &(pdevn->equiv_cmyk_colors));

    if (code < 0) {
        pdev->color_info = save_info;
        return code;
    }

#if ENABLE_ICC_PROFILE
    /* Open any ICC profiles that have been specified. */
    if (po.data != 0) {
        memcpy(pdevn->profile_out_fn, po.data, po.size);
        pdevn->profile_out_fn[po.size] = 0;
    }
    if (prgb.data != 0) {
        memcpy(pdevn->profile_rgb_fn, prgb.data, prgb.size);
        pdevn->profile_rgb_fn[prgb.size] = 0;
    }
    if (pcmyk.data != 0) {
        memcpy(pdevn->profile_cmyk_fn, pcmyk.data, pcmyk.size);
        pdevn->profile_cmyk_fn[pcmyk.size] = 0;
    }
    if (memcmp(&pdevn->color_info, &save_info,
                            size_of(gx_device_color_info)) != 0)
        code = psd_open_profiles(pdevn);
#endif
    return code;
}

/*
 * This routine will check to see if the color component name  match those
 * that are available amoung the current device's color components.
 *
 * Parameters:
 *   dev - pointer to device data structure.
 *   pname - pointer to name (zero termination not required)
 *   nlength - length of the name
 *
 * This routine returns a positive value (0 to n) which is the device colorant
 * number if the name is found.  It returns a negative value if not found.
 */
static int
psd_get_color_comp_index(gx_device * dev, const char * pname,
                                        int name_size, int component_type)
{
    int index;
    psd_device *pdev = (psd_device *)dev;

    if (strncmp(pname, "None", name_size) == 0) return -1;
    index = devn_get_color_comp_index(dev,
                &(((psd_device *)dev)->devn_params),
                &(((psd_device *)dev)->equiv_cmyk_colors),
                pname, name_size, component_type, ENABLE_AUTO_SPOT_COLORS);
    /* This is a one shot deal.  That is it will simply post a notice once that 
       some colorants will be converted due to a limit being reached.  It will
       not list names of colorants since then I would need to keep track of 
       which ones I have already mentioned.  Also, if someone is fooling with
       num_order, then this warning is not given since they should know what
       is going on already */
    if (index < 0 && component_type == SEPARATION_NAME && 
        pdev->warning_given == false && 
        pdev->devn_params.num_separation_order_names == 0) {
        dlprintf("**** Max spot colorants reached.\n");
        dlprintf("**** Some colorants will be converted to equivalent CMYK values.\n");
        dlprintf("**** If this is a Postscript file, try using the -dMaxSpots= option.\n");
        pdev->warning_given = true;
    }
    return index;
}

/* ------ Private definitions ------ */

/* All two-byte quantities are stored MSB-first! */
#if arch_is_big_endian
#  define assign_u16(a,v) a = (v)
#  define assign_u32(a,v) a = (v)
#else
#  define assign_u16(a,v) a = ((v) >> 8) + ((v) << 8)
#  define assign_u32(a,v) a = (((v) >> 24) & 0xff) + (((v) >> 8) & 0xff00) + (((v) & 0xff00) << 8) + (((v) & 0xff) << 24)
#endif

typedef struct {
    FILE *f;

    int width;
    int height;
    int base_bytes_pp;	/* almost always 3 (rgb) or 4 (CMYK) */
    int n_extra_channels;
    int num_channels;	/* base_bytes_pp + any spot colors that are imaged */
    /* Map output channel number to original separation number. */
    int chnl_to_orig_sep[GX_DEVICE_COLOR_MAX_COMPONENTS];
    /* Map output channel number to gx_color_index position. */
    int chnl_to_position[GX_DEVICE_COLOR_MAX_COMPONENTS];

    /* byte offset of image data */
    int image_data_off;
} psd_write_ctx;

static int
psd_setup(psd_write_ctx *xc, psd_device *dev)
{
    int i;
    int spot_count;

#define NUM_CMYK_COMPONENTS 4
    xc->base_bytes_pp = dev->devn_params.num_std_colorant_names;
    xc->num_channels = xc->base_bytes_pp;
    if (dev->devn_params.num_separation_order_names == 0) {
        xc->n_extra_channels = dev->devn_params.separations.num_separations;
    } else {
        /* Have to figure out how many in the order list were not std
           colorants */
        spot_count = 0;
        for (i = 0; i < dev->devn_params.num_separation_order_names; i++) {
            if (dev->devn_params.separation_order_map[i] >= NUM_CMYK_COMPONENTS) {
                spot_count++;
            }
        }
        xc->n_extra_channels = spot_count;
    }
    xc->width = gx_downscaler_scale(dev->width, dev->downscale_factor);
    xc->height = gx_downscaler_scale(dev->height, dev->downscale_factor);
    /*
     * Determine the order of the output components.  This is based upon
     * the SeparationOrder parameter.  This parameter can be used to select
     * which planes are actually imaged.  For the process color model channels
     * we image the channels which are requested.  Non requested process color
     * model channels are simply filled with white.  For spot colors we only
     * image the requested channels. 
     */
    for (i = 0; i < xc->base_bytes_pp + xc->n_extra_channels; i++) {
        xc->chnl_to_position[i] = i;
        xc->chnl_to_orig_sep[i] = i;
    }
    /* If we had a specify order name, then we may need to adjust things */
    if (dev->devn_params.num_separation_order_names > 0) {
        for (i = 0; i < dev->devn_params.num_separation_order_names; i++) {
            int sep_order_num = dev->devn_params.separation_order_map[i];
            if (sep_order_num >= NUM_CMYK_COMPONENTS) {
                xc->chnl_to_position[xc->num_channels] = sep_order_num;
                xc->chnl_to_orig_sep[xc->num_channels++] = sep_order_num;
            }
        }
    } else {
        xc->num_channels += dev->devn_params.separations.num_separations;
    }
    return 0;
}

static int
psd_write(psd_write_ctx *xc, const byte *buf, int size) {
    int code;

    code = fwrite(buf, 1, size, xc->f);
    if (code < 0)
        return code;
    return 0;
}

static int
psd_write_8(psd_write_ctx *xc, byte v)
{
    return psd_write(xc, (byte *)&v, 1);
}

static int
psd_write_16(psd_write_ctx *xc, bits16 v)
{
    bits16 buf;

    assign_u16(buf, v);
    return psd_write(xc, (byte *)&buf, 2);
}

static int
psd_write_32(psd_write_ctx *xc, bits32 v)
{
    bits32 buf;

    assign_u32(buf, v);
    return psd_write(xc, (byte *)&buf, 4);
}

static int
psd_write_header(psd_write_ctx *xc, psd_device *pdev)
{
    int code = 0;
    int bytes_pp = xc->num_channels;
    int chan_idx;
    int chan_names_len = 0;
    int sep_num;
    const devn_separation_name *separation_name;

    psd_write(xc, (const byte *)"8BPS", 4); /* Signature */
    psd_write_16(xc, 1); /* Version - Always equal to 1*/
    /* Reserved 6 Bytes - Must be zero */
    psd_write_32(xc, 0);
    psd_write_16(xc, 0);
    psd_write_16(xc, (bits16) bytes_pp); /* Channels (2 Bytes) - Supported range is 1 to 24 */
    psd_write_32(xc, xc->height); /* Rows */
    psd_write_32(xc, xc->width); /* Columns */
    psd_write_16(xc, 8); /* Depth - 1, 8 and 16 */
    psd_write_16(xc, (bits16) xc->base_bytes_pp); /* Mode - RGB=3, CMYK=4 */

    /* Color Mode Data */
    psd_write_32(xc, 0); 	/* No color mode data */

    /* Image Resources */

    /* Channel Names */
    for (chan_idx = NUM_CMYK_COMPONENTS; chan_idx < xc->num_channels; chan_idx++) {
        sep_num = xc->chnl_to_orig_sep[chan_idx] - NUM_CMYK_COMPONENTS;
        separation_name = &(pdev->devn_params.separations.names[sep_num]);
        chan_names_len += (separation_name->size + 1);
    }
    psd_write_32(xc, 12 + (chan_names_len + (chan_names_len % 2))
                        + (12 + (14 * (xc->num_channels - xc->base_bytes_pp)))
                        + 28);
    psd_write(xc, (const byte *)"8BIM", 4);
    psd_write_16(xc, 1006); /* 0x03EE */
    psd_write_16(xc, 0); /* PString */
    psd_write_32(xc, chan_names_len + (chan_names_len % 2));
    for (chan_idx = NUM_CMYK_COMPONENTS; chan_idx < xc->num_channels; chan_idx++) {
        sep_num = xc->chnl_to_orig_sep[chan_idx] - NUM_CMYK_COMPONENTS;
        separation_name = &(pdev->devn_params.separations.names[sep_num]);
        psd_write_8(xc, (byte) separation_name->size);
        psd_write(xc, separation_name->data, separation_name->size);
    }
    if (chan_names_len % 2)
        psd_write_8(xc, 0); /* pad */

    /* DisplayInfo - Colors for each spot channels */
    psd_write(xc, (const byte *)"8BIM", 4);
    psd_write_16(xc, 1007); /* 0x03EF */
    psd_write_16(xc, 0); /* PString */
    psd_write_32(xc, 14 * (xc->num_channels - xc->base_bytes_pp)); /* Length */
    for (chan_idx = NUM_CMYK_COMPONENTS; chan_idx < xc->num_channels; chan_idx++) {
        sep_num = xc->chnl_to_orig_sep[chan_idx] - NUM_CMYK_COMPONENTS;
        psd_write_16(xc, 02); /* CMYK */
        /* PhotoShop stores all component values as if they were additive. */
        if (pdev->equiv_cmyk_colors.color[sep_num].color_info_valid) {
#define convert_color(component) ((bits16)((65535 * ((double)\
    (frac_1 - pdev->equiv_cmyk_colors.color[sep_num].component)) / frac_1)))
            psd_write_16(xc, convert_color(c)); /* Cyan */
            psd_write_16(xc, convert_color(m)); /* Magenta */
            psd_write_16(xc, convert_color(y)); /* Yellow */
            psd_write_16(xc, convert_color(k)); /* Black */
#undef convert_color
        }
        else {	    /* Else set C = M = Y = 0, K = 1 */
            psd_write_16(xc, 65535); /* Cyan */
            psd_write_16(xc, 65535); /* Magenta */
            psd_write_16(xc, 65535); /* Yellow */
            psd_write_16(xc, 0); /* Black */
        }
        psd_write_16(xc, 0); /* Opacity 0 to 100 */
        psd_write_8(xc, 2); /* Don't know */
        psd_write_8(xc, 0); /* Padding - Always Zero */
    }

    /* Image resolution */
    psd_write(xc, (const byte *)"8BIM", 4);
    psd_write_16(xc, 1005); /* 0x03ED */
    psd_write_16(xc, 0); /* PString */
    psd_write_32(xc, 16); /* Length */
                /* Resolution is specified as a fixed 16.16 bits */
    psd_write_32(xc, (int) (pdev->HWResolution[0] * 0x10000 + 0.5));
    psd_write_16(xc, 1);	/* width:  1 --> resolution is pixels per inch */
    psd_write_16(xc, 1);	/* width:  1 --> resolution is pixels per inch */
    psd_write_32(xc, (int) (pdev->HWResolution[1] * 0x10000 + 0.5));
    psd_write_16(xc, 1);	/* height:  1 --> resolution is pixels per inch */
    psd_write_16(xc, 1);	/* height:  1 --> resolution is pixels per inch */

    /* Layer and Mask information */
    psd_write_32(xc, 0); 	/* No layer or mask information */

    return code;
}

/*
 * Close device and clean up ICC structures.
 */
static int
psd_prn_close(gx_device *dev)
{
    psd_device * const xdev = (psd_device *) dev;

    if (xdev->cmyk_icc_link != NULL) {
        gscms_release_link(xdev->cmyk_icc_link);
        rc_decrement(xdev->cmyk_profile, "psd_prn_close");
    }

    if (xdev->rgb_icc_link != NULL) {
        gscms_release_link(xdev->rgb_icc_link);
        rc_decrement(xdev->rgb_profile, "psd_prn_close");
    }

    if (xdev->output_icc_link != NULL) {
        gscms_release_link(xdev->output_icc_link);
        rc_decrement(xdev->output_profile, "psd_prn_close");
    }

    return gdev_prn_close(dev);
}

/*
 * Output the image data for the PSD device.  The data for the PSD is
 * written in separate planes.  If the device is psdrgb then we simply
 * write three planes of RGB data.  The DeviceN parameters (SeparationOrder,
 * SeparationCOlorNames, and MaxSeparations) are not applied to the psdrgb
 * device.
 *
 * The DeviceN parameters are applied to the psdcmyk device.  If the
 * SeparationOrder parameter is not specified then first we write out the data
 * for the CMYK planes and then any separation planes.  If the SeparationOrder
 * parameter is specified, then things are more complicated.  Logically we
 * would simply write the planes specified by the SeparationOrder data.
 * However Photoshop expects there to be CMYK data.  First we will write out
 * four planes of data for CMYK.  If any of these colors are present in the
 * SeparationOrder data then the plane data will contain the color information.
 * If a color is not present then the plane data will be zero.  After the CMYK
 * data, we will write out any separation data which is specified in the
 * SeparationOrder data.
 */

static int
psd_write_image_data(psd_write_ctx *xc, gx_device_printer *pdev)
{
    int raster_plane = bitmap_raster(pdev->width * 8);
    byte *planes[GS_CLIENT_COLOR_MAX_COMPONENTS];
    int code = 0;
    int i, j;
    byte *sep_line;
    int base_bytes_pp = xc->base_bytes_pp;
    int chan_idx;
/*  psd_device *xdev = (psd_device *)pdev;
    gcmmhlink_t link = xdev->output_icc_link; */
    byte * unpacked;
    int num_comp = xc->num_channels;
    gs_int_rect rect;
    gs_get_bits_params_t params;
    gx_downscaler_t ds = { NULL };
    psd_device *psd_dev = (psd_device *)pdev;

    rect.q.x = pdev->width;
    rect.p.x = 0;
    /* Return planar data */
    params.options = (GB_RETURN_POINTER | GB_RETURN_COPY |
         GB_ALIGN_STANDARD | GB_OFFSET_0 | GB_RASTER_STANDARD |
         GB_PACKING_PLANAR | GB_COLORS_NATIVE | GB_ALPHA_NONE);
    params.x_offset = 0;
    params.raster = bitmap_raster(pdev->width * pdev->color_info.depth);
    psd_write_16(xc, 0); /* Compression */

    sep_line = gs_alloc_bytes(pdev->memory, xc->width, "psd_write_sep_line");

    for (chan_idx = 0; chan_idx < num_comp; chan_idx++) {
        planes[chan_idx] = gs_alloc_bytes(pdev->memory, raster_plane, 
                                        "psd_write_sep_line");
        params.data[chan_idx] = planes[chan_idx];
        if (params.data[chan_idx] == NULL)
            return_error(gs_error_VMerror);
    }

    if (sep_line == NULL)
        return_error(gs_error_VMerror);

    code = gx_downscaler_init_planar(&ds, (gx_device *)pdev, &params, num_comp,
                                     psd_dev->downscale_factor, 0, 8, 8);
    if (code < 0)
        goto cleanup;

    /* Print the output planes */
    for (chan_idx = 0; chan_idx < num_comp; chan_idx++) {
        int data_pos = xc->chnl_to_position[chan_idx];
        if (data_pos >= 0) {
            for (j = 0; j < xc->height; ++j) {
                rect.p.y = j;   
                rect.q.y = j + 1;
                code = gx_downscaler_get_bits_rectangle(&ds, &params, j);
                if (code < 0)
                    goto cleanup;

                unpacked = params.data[data_pos];
                /* To do, get ICC stuff in place for planar device */
               // if (link == NULL) {
                    if (base_bytes_pp == 3) {
                        /* RGB */
                        memcpy(sep_line, unpacked, xc->width);
                    } else {
                        for (i = 0; i < xc->width; ++i) {
                            /* CMYK + spots*/
                            sep_line[i] = 255 - unpacked[i];
                        }
                    }
              /*  } else {
                    psd_calib_row((gx_device*) xdev, xc, &sep_line, unpacked, data_pos,
                        link, xdev->output_profile->num_comps,
                        xdev->output_profile->num_comps_out);
                } */
                psd_write(xc, sep_line, xc->width);
            }
        } else {
            if (chan_idx < NUM_CMYK_COMPONENTS) {
                /* Write empty process color in the area */
                memset(sep_line,255,xc->width);
                psd_write(xc, sep_line, xc->width);
            }
        }
    }

cleanup:
    gx_downscaler_fin(&ds);
    gs_free_object(pdev->memory, sep_line, "psd_write_sep_line");
    for (chan_idx = 0; chan_idx < num_comp; chan_idx++) {
        gs_free_object(pdev->memory, planes[chan_idx], 
                                        "psd_write_image_data");
    }
    return code;
}

static int
psd_print_page(gx_device_printer *pdev, FILE *file)
{
    psd_write_ctx xc;
    psd_device *psd_dev = (psd_device *)pdev;

    xc.f = file;

    psd_setup(&xc, psd_dev);
    psd_write_header(&xc, psd_dev);
    psd_write_image_data(&xc, pdev);
    /* Free up the list of spot names as they were only relevent to that page */
    free_separation_names(pdev->memory, &(psd_dev->devn_params.separations));
    psd_dev->devn_params.num_separation_order_names = 0;
    return 0;
}