/* Copyright (C) 2001-2023 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., 39 Mesa Street, Suite 108A, San Francisco, CA 94129, USA, for further information. */ /* PhotoShop (PSD) export device, supporting DeviceN color models. */ #include "math_.h" #include "gxiodev.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 "gsicc_cache.h" #include "gsicc_manage.h" #include "gxgetbit.h" #include "gdevppla.h" #include "gxdownscale.h" #include "gdevdevnprn.h" #include "gdevpsd.h" #include "gxdevsop.h" #include "gsicc_cms.h" #ifndef MAX_CHAN # define MAX_CHAN 15 #endif /* Define the device parameters. */ #ifndef X_DPI # define X_DPI 72 #endif #ifndef Y_DPI # define Y_DPI 72 #endif #define ENABLE_COLOR_REPLACE 0 /* 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_get_params(psd_get_params_cmyk); static dev_proc_put_params(psd_put_params_cmyk); static dev_proc_put_params(psd_put_params_cmyktag); 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); /* 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_CMYKT, psd_DEVICE_N } psd_color_model; fixed_colorant_name DevCMYKTComponents[] = { "Cyan", "Magenta", "Yellow", "Black", "Tags", 0 /* List terminator */ }; /* * A structure definition for a DeviceN type device */ typedef struct psd_device_s { gx_devn_prn_device_common; psd_color_model color_model; int max_spots; bool lock_colorants; gx_downscaler_params downscale; /* 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 */ #if ENABLE_COLOR_REPLACE bool color_replace_warning_given; #endif } psd_device; /* GC procedures */ static ENUM_PTRS_WITH(psd_device_enum_ptrs, psd_device *pdev) { ENUM_PREFIX(st_gx_devn_prn_device, 0); (void)pdev; /* Stop unused var warning */ return 0; } ENUM_PTRS_END static RELOC_PTRS_WITH(psd_device_reloc_ptrs, psd_device *pdev) { RELOC_PREFIX(st_gx_devn_prn_device); (void)pdev; /* Stop unused var warning */ } RELOC_PTRS_END static int psd_spec_op(gx_device *dev_, int op, void *data, int datasize) { if (op == gxdso_supports_devn || op == gxdso_skip_icc_component_validation) { return true; } #if ENABLE_COLOR_REPLACE /* Demo of doing color replacement in the device in place of standard ICC color management. Only works for CMYK psd devices */ if (op == gxdso_replacecolor && dev_->color_info.num_components >= 4) { color_replace_t *replace_data = (color_replace_t *)data; gx_device_color *pdc = replace_data->pdc; const gs_color_space *pcs = replace_data->pcs; const gs_client_color *pcc = replace_data->pcc; const gs_gstate *pgs = replace_data->pgs; /* Perhaps needed for named color profile information */ psd_device* pdev_psd = (psd_device*)dev_; /* Just a warning here for now. When pdf14_profile is set, the user may need to do some extra work to get a desired color replacement. Note that the pdf14 color space can be completely different than the target device color space, which is what this will indicate. If the color space is gray or rgb we don't fool with any remap in this example. */ if (replace_data->pdf14_iccprofile != NULL && !(pdev_psd->color_replace_warning_given)) { dmlprintf(pdev_psd->memory, "Warning. Doing color replacement for PDF14 device!\n"); pdev_psd->color_replace_warning_given = true; if (replace_data->pdf14_iccprofile->num_comps == 3 || replace_data->pdf14_iccprofile->num_comps == 1) { return false; } } /* CMYK or CIELAB source colors that are vector fills. */ if ((pcs->cmm_icc_profile_data->data_cs == gsCMYK || pcs->cmm_icc_profile_data->data_cs == gsCIELAB || pcs->cmm_icc_profile_data->data_cs == gsRGB ) && dev_->graphics_type_tag == GS_VECTOR_TAG) { int jj, ii; int values[4]; int replace = 0; /* Zero out all the device values including any spots */ for (ii = 0; ii < dev_->color_info.num_components; ii++) { pdc->colors.devn.values[ii] = 0; } if (pcs->cmm_icc_profile_data->data_cs == gsCMYK) { for (jj = 0; jj < 4; jj++) { values[jj] = 65535 * pcc->paint.values[jj]; } if (values[0] == 40959 && values[1] == 0 && values[2] == 11730 && values[3] == 0) { replace = 1; pdc->colors.devn.values[1] = 32000; } else if (values[0] == 0 && values[1] == 49741 && values[2] == 65535 && values[3] == 0) { replace = 1; pdc->colors.devn.values[0] = 48000; } else { /* Test of shading.... */ replace = 1; for (ii = 0; ii < 3; ii++) { pdc->colors.devn.values[ii] = 65535 - values[ii]; } } } else if (pcs->cmm_icc_profile_data->data_cs == gsCIELAB) { /* CIELAB case. Lets make color K only based upon luminance */ int luminance = 65535 * pcc->paint.values[0] / 100.0; replace = 1; if (luminance > 65535) luminance = 65535; pdc->colors.devn.values[3] = luminance; } else { /* Source is RGB case */ /* Lets invert these as C = R, M = G, Y = B, K = 0 */ replace = 1; for (ii = 0; ii < 3; ii++) { pdc->colors.devn.values[ii] = 65535 * pcc->paint.values[ii]; } } if (replace) { /* This is only for devn type devices. */ pdc->type = gx_dc_type_devn; /* Save original color space and color info into dev color */ ii = pcs->cmm_icc_profile_data->num_comps; for (ii--; ii >= 0; ii--) pdc->ccolor.paint.values[ii] = pcc->paint.values[ii]; pdc->ccolor_valid = true; return true; } else return false; /* No replacement */ } else return false; } #endif return gdev_prn_dev_spec_op(dev_, op, data, datasize); } /* Even though psd_device_finalize is the same as gx_devn_prn_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) { gx_devn_prn_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); static void psd_initialize_device_procs(gx_device *dev) { gdev_prn_initialize_device_procs_bg(dev); set_dev_proc(dev, open_device, psd_prn_open); set_dev_proc(dev, close_device, psd_prn_close); set_dev_proc(dev, map_color_rgb, psd_map_color_rgb); set_dev_proc(dev, get_params, psd_get_params); set_dev_proc(dev, put_params, psd_put_params); set_dev_proc(dev, get_color_mapping_procs, get_psdrgb_color_mapping_procs); set_dev_proc(dev, get_color_comp_index, psd_get_color_comp_index); set_dev_proc(dev, encode_color, gx_devn_prn_encode_color); set_dev_proc(dev, decode_color, gx_devn_prn_decode_color); set_dev_proc(dev, update_spot_equivalent_colors, gx_devn_prn_update_spot_equivalent_colors); set_dev_proc(dev, ret_devn_params, gx_devn_prn_ret_devn_params); set_dev_proc(dev, dev_spec_op, psd_spec_op); } #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. */ const psd_device gs_psdrgb_device = { psd_device_body(psd_initialize_device_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 */ GS_SOFT_MAX_SPOTS, /* max_spots */ false, /* colorants not locked */ GX_DOWNSCALER_PARAMS_DEFAULTS }; const psd_device gs_psdrgb16_device = { psd_device_body(psd_initialize_device_procs, "psdrgb16", 3, GX_CINFO_POLARITY_ADDITIVE, 48, 65535, 65535, GX_CINFO_SEP_LIN, "DeviceRGB"), /* devn_params specific parameters */ { 16, /* 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 */ GS_SOFT_MAX_SPOTS, /* max_spots */ false, /* colorants not locked */ GX_DOWNSCALER_PARAMS_DEFAULTS }; /* * PSD device with CMYK process color model and spot color support. */ static void psdcmyk_initialize_device_procs(gx_device *dev) { psd_initialize_device_procs(dev); set_dev_proc(dev, get_params, psd_get_params_cmyk); set_dev_proc(dev, put_params, psd_put_params_cmyk); set_dev_proc(dev, get_color_mapping_procs, get_psd_color_mapping_procs); } /* * PSD device with CMYK process color model, spot color support, and tags. */ static void psdcmyktag_initialize_device_procs(gx_device *dev) { psd_initialize_device_procs(dev); set_dev_proc(dev, get_params, psd_get_params_cmyk); set_dev_proc(dev, put_params, psd_put_params_cmyktag); set_dev_proc(dev, get_color_mapping_procs, get_psd_color_mapping_procs); } const psd_device gs_psdcmyk_device = { psd_device_body(psdcmyk_initialize_device_procs, "psdcmyk", ARCH_SIZEOF_GX_COLOR_INDEX, /* Number of components - need a nominal 1 bit for each */ GX_CINFO_POLARITY_SUBTRACTIVE, ARCH_SIZEOF_GX_COLOR_INDEX * 8, /* 8 bits per component (albeit in planes) */ 255, 255, GX_CINFO_SEP_LIN, "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 */ GS_SOFT_MAX_SPOTS, /* max_spots */ false, /* colorants not locked */ GX_DOWNSCALER_PARAMS_DEFAULTS }; const psd_device gs_psdcmyktags_device = { psd_device_body(psdcmyktag_initialize_device_procs, "psdcmyktags", ARCH_SIZEOF_GX_COLOR_INDEX, /* Number of components - need a nominal 1 bit for each */ GX_CINFO_POLARITY_SUBTRACTIVE, ARCH_SIZEOF_GX_COLOR_INDEX * 8, /* 8 bits per component (albeit in planes) */ 255, 255, GX_CINFO_SEP_LIN, "DeviceCMYK"), /* devn_params specific parameters */ { 8, /* Bits per color - must match ncomp, depth, etc. above */ DevCMYKTComponents, /* Names of color model colorants */ 4, /* Number colorants for CMYK. Tags added to extra in DevCMYKTComponents */ 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_CMYKT, /* Color model */ GS_SOFT_MAX_SPOTS, /* max_spots */ false, /* colorants not locked */ GX_DOWNSCALER_PARAMS_DEFAULTS }; const psd_device gs_psdcmyk16_device = { psd_device_body(psdcmyk_initialize_device_procs, "psdcmyk16", ARCH_SIZEOF_GX_COLOR_INDEX, /* Number of components - need a nominal 1 bit for each */ GX_CINFO_POLARITY_SUBTRACTIVE, ARCH_SIZEOF_GX_COLOR_INDEX * 16, /* 8 bits per component (albeit in planes) */ 65535, 65535, GX_CINFO_SEP_LIN, "DeviceCMYK"), /* devn_params specific parameters */ { 16, /* 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 */ GS_SOFT_MAX_SPOTS, /* max_spots */ false, /* colorants not locked */ GX_DOWNSCALER_PARAMS_DEFAULTS }; const psd_device gs_psdcmyktags16_device = { psd_device_body(psdcmyktag_initialize_device_procs, "psdcmyktags16", ARCH_SIZEOF_GX_COLOR_INDEX, /* Number of components - need a nominal 1 bit for each */ GX_CINFO_POLARITY_SUBTRACTIVE, ARCH_SIZEOF_GX_COLOR_INDEX * 16, /* 8 bits per component (albeit in planes) */ 65535, 65535, GX_CINFO_SEP_LIN, "DeviceCMYK"), /* devn_params specific parameters */ { 16, /* Bits per color - must match ncomp, depth, etc. above */ DevCMYKTComponents, /* Names of color model colorants */ 4, /* Number colorants for CMYK. Tags added to extra in DevCMYKTComponents */ 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_CMYKT, /* Color model */ GS_SOFT_MAX_SPOTS, /* max_spots */ false, /* colorants not locked */ GX_DOWNSCALER_PARAMS_DEFAULTS }; /* Open the psd devices */ int psd_prn_open(gx_device * pdev) { psd_device *pdev_psd = (psd_device *) pdev; int code; int k; cmm_dev_profile_t *profile_struct; bool has_tags = (pdev_psd->color_model == psd_DEVICE_CMYKT); #ifdef TEST_PAD_AND_ALIGN pdev->pad = 5; pdev->log2_align_mod = 6; #endif code = dev_proc(pdev, get_profile)((gx_device *)pdev, &profile_struct); pdev_psd->warning_given = false; #if ENABLE_COLOR_REPLACE pdev_psd->color_replace_warning_given = false; #endif /* For the planar device we need to set up the bit depth of each plane. For other devices this is handled in check_device_separable where we compute the bit shift for the components etc. */ for (k = 0; k < GS_CLIENT_COLOR_MAX_COMPONENTS; k++) { pdev->color_info.comp_bits[k] = 8; } /* 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->color_info.polarity == GX_CINFO_POLARITY_SUBTRACTIVE) { if (pdev_psd->devn_params.page_spot_colors >= 0) { /* PDF case, as the page spot colors are known. */ if (profile_struct->spotnames != NULL) { /* PDF case, NCLR ICC profile with spot names. The ICC spots will use up some of the max_spots values. If max_spots is too small to accomodate even the ICC spots, throw an error */ if (profile_struct->spotnames->count - 4 > pdev_psd->max_spots || profile_struct->spotnames->count < 4 || profile_struct->spotnames->count < profile_struct->device_profile[0]->num_comps) { gs_warn("ICC profile colorant names count error"); return_error(gs_error_rangecheck); } pdev->color_info.num_components = (profile_struct->spotnames->count + pdev_psd->devn_params.page_spot_colors + has_tags); if (pdev->color_info.num_components > pdev->color_info.max_components) pdev->color_info.num_components = pdev->color_info.max_components; } else { /* Use the information that is in the page spot color. We should be here if we are processing a PDF and we do not have a DeviceN ICC profile specified for output */ if (!(pdev_psd->lock_colorants)) { pdev->color_info.num_components = (pdev_psd->devn_params.page_spot_colors + pdev_psd->devn_params.num_std_colorant_names + has_tags); 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. However, the first time the device is opened, pdev_psd->devn_params.page_spot_colors is -1 even if we are dealing with a PDF file, so we will first find ourselves here, which will set num_comp based upon max_spots + 4. If -dMaxSpots was set (Default is GS_SOFT_MAX_SPOTS which is 10), it is made use of here. */ if (!(pdev_psd->lock_colorants)) { int num_comp = pdev_psd->max_spots + 4 + has_tags; /* 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; set_linear_color_bits_mask_shift(pdev); if (pdev->color_info.polarity == GX_CINFO_POLARITY_ADDITIVE) pdev->icc_struct->supports_devn = false; else 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(const gx_device * dev, frac gray, frac out[]) { out[0] = gray; } static void rgb_cs_to_psdgray_cm(const gx_device * dev, const gs_gstate *pgs, 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(const 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(const 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(const gx_device * dev, const gs_gstate *pgs, 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(const 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(const 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(const gx_device * dev, const gs_gstate *pgs, 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, pgs, r, g, b, out); } static void cmyk_cs_to_psdcmyktags_cm(const gx_device *dev, frac c, frac m, frac y, frac k, frac out[]) { const gs_devn_params *devn = gx_devn_prn_ret_devn_params_const(dev); const int *map = devn->separation_order_map; int j; int ncomps = dev->color_info.num_components; if (devn->num_separation_order_names > 0) { /* This is to set only those that we are using */ for (j = 0; j < ncomps; j++) out[j] = 0; 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); } /* And set the tags. At this point, the color values are frac representation for the range [0.0 1.0]. We need to encode the graphics type, which is 0 to 255 accordingly, as it goes through the same mappings on its way to devn and then eventually to 8 or 16 bit values */ if (map[ncomps - 1] != GX_DEVICE_COLOR_MAX_COMPONENTS) out[ncomps - 1] = byte2frac(dev->graphics_type_tag & ~GS_DEVICE_ENCODES_TAGS); } static void cmyk_cs_to_psdcmyk_cm(const gx_device * dev, frac c, frac m, frac y, frac k, frac out[]) { const gs_devn_params *devn = gx_devn_prn_ret_devn_params_const(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 */ int ncomps = dev->color_info.num_components; for (j = 0; j < ncomps; j++) out[j] = 0; 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(const 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_const(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(const 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(const gx_device * dev, const gs_gstate *pgs, 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_const(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, pgs, 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 psdCMYKtags_procs = { gray_cs_to_psdcmyk_cm, rgb_cs_to_psdcmyk_cm, cmyk_cs_to_psdcmyktags_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, const gx_device **map_dev) { *map_dev = dev; return &psdRGB_procs; } static const gx_cm_color_map_procs * get_psd_color_mapping_procs(const gx_device * dev, const gx_device **map_dev) { const psd_device *xdev = (const psd_device *)dev; *map_dev = 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_CMYKT) return &psdCMYKtags_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; } /* * 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 gx_devn_prn_decode_color(dev, color, rgb); /* TODO: return reasonable values. */ rgb[0] = 0; rgb[1] = 0; rgb[2] = 0; return 0; } /* Get parameters. We provide a default CRD. */ static int psd_get_params_generic(gx_device * pdev, gs_param_list * plist, int cmyk) { psd_device *xdev = (psd_device *)pdev; int code; code = gx_devn_prn_get_params(pdev, plist); if (code < 0) return code; code = gx_downscaler_write_params(plist, &xdev->downscale, cmyk ? GX_DOWNSCALER_PARAMS_TRAP : 0); if (code < 0) return code; code = param_write_int(plist, "MaxSpots", &xdev->max_spots); if (code < 0) return code; code = param_write_bool(plist, "LockColorants", &xdev->lock_colorants); return code; } static int psd_get_params(gx_device * pdev, gs_param_list * plist) { return psd_get_params_generic(pdev, plist, 0); } static int psd_get_params_cmyk(gx_device * pdev, gs_param_list * plist) { return psd_get_params_generic(pdev, plist, 1); } /* Set parameters. We allow setting the number of bits per component. */ static int psd_put_params_generic(gx_device * pdev, gs_param_list * plist, int cmyk) { psd_device * const pdevn = (psd_device *) pdev; int code = 0; code = gx_downscaler_read_params(plist, &pdevn->downscale, cmyk ? GX_DOWNSCALER_PARAMS_TRAP : 0); if (code < 0) return code; switch (code = param_read_bool(plist, "LockColorants", &(pdevn->lock_colorants))) { case 0: break; case 1: break; default: param_signal_error(plist, "LockColorants", 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_note_error(gs_error_rangecheck); /* fall through */ default: param_signal_error(plist, "MaxSpots", code); return code; case 1: break; } /* handle the standard DeviceN related parameters */ if (code >= 0) code = gx_devn_prn_put_params(pdev, plist); return code; } static int psd_put_params(gx_device * pdev, gs_param_list * plist) { return psd_put_params_generic(pdev, plist, 0); } static int psd_put_params_cmyk(gx_device * pdev, gs_param_list * plist) { return psd_put_params_generic(pdev, plist, 1); } static int psd_put_params_cmyktag(gx_device *pdev, gs_param_list* plist) { pdev->graphics_type_tag |= GS_DEVICE_ENCODES_TAGS; return psd_put_params_generic(pdev, plist, 1); } /* * 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 = gx_devn_prn_get_color_comp_index(dev, pname, name_size, component_type); /* 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) { dmlprintf(dev->memory, "**** Max spot colorants reached.\n"); dmlprintf(dev->memory, "**** Some colorants will be converted to equivalent CMYK values.\n"); dmlprintf(dev->memory, "**** 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 int psd_setup(psd_write_ctx *xc, gx_devn_prn_device *dev, gp_file *file, int w, int h) { int i; int spot_count; xc->f = file; #define NUM_CMYK_COMPONENTS 4 for (i = 0; i < GX_DEVICE_COLOR_MAX_COMPONENTS; i++) { if (dev->devn_params.std_colorant_names[i] == NULL) break; } xc->base_num_channels = dev->devn_params.num_std_colorant_names; xc->num_channels = i; if (dev->color_info.polarity == GX_CINFO_POLARITY_SUBTRACTIVE && strcmp(dev->dname, "psdcmykog") != 0) { /* Note: num_separation_order_names is only set if SeparationColorNames was setup. If this was not set, we need may need to make use of the ICCOutputColors and page spot colors for our setup. */ if (dev->devn_params.num_separation_order_names == 0) { /* Page spot colors has been truncated to ensure max colorants of the target device is not exceeded. This is set if PDF file was encountered and should be used. Also make sure PS file does not exceed limit of device. However, if ICCOutputColors was specified, that should take precedence. */ if (dev->devn_params.page_spot_colors > 0 && dev->icc_struct->spotnames == NULL) xc->n_extra_channels = dev->devn_params.page_spot_colors; else { if (dev->devn_params.separations.num_separations <= (dev->color_info.max_components - NUM_CMYK_COMPONENTS)) xc->n_extra_channels = dev->devn_params.separations.num_separations; else xc->n_extra_channels = dev->color_info.max_components - NUM_CMYK_COMPONENTS; } } 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; } } else { xc->n_extra_channels = 0; } xc->width = w; xc->height = h; /* * 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->num_channels + 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->color_info.polarity == GX_CINFO_POLARITY_SUBTRACTIVE && strcmp(dev->dname, "psdcmykog") != 0) { 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 { /* If ICCOutputColors specified then just use that ordering, which has already been set. */ cmm_dev_profile_t *profile_struct; int code; code = dev_proc(dev, get_profile)((gx_device *)dev, &profile_struct); if (code == 0 && profile_struct->spotnames != NULL) xc->num_channels += dev->devn_params.separations.num_separations; else { /* No order specified, map them alpabetically */ /* This isn't at all speed critical -- only runs once per page and */ /* there are never very many spot colors, so just search in a loop */ /* If the device has tags, then that goes at the end, after all the spot colors */ const char *prev = " "; int prev_size = 1; psd_device *pdev_psd = (psd_device*)dev; bool has_tags = (pdev_psd->color_model == psd_DEVICE_CMYKT); xc->num_channels += xc->n_extra_channels; for (i=xc->base_num_channels + has_tags; i < xc->num_channels; i++) { int j; const char *curr = "\377"; int curr_size = 1; bool compare; for (j=xc->base_num_channels + has_tags; j < xc->num_channels; j++) { devn_separation_name *separation_name; separation_name = &(dev->devn_params.separations.names[j - xc->base_num_channels]); compare = strncmp((const char*) separation_name->data, curr, min(curr_size, separation_name->size)); if (compare < 0 || (compare == 0 && separation_name->size < curr_size)) { compare = strncmp((const char*) separation_name->data, prev, min(prev_size, separation_name->size)); if (compare > 0 || (compare == 0 && separation_name->size > prev_size)) { xc->chnl_to_position[i] = j; xc->chnl_to_orig_sep[i] = j; curr = (const char*) separation_name->data; curr_size = separation_name->size; } } } prev = curr; /* next color has to sort after this one */ prev_size = curr_size; } } } } return 0; } int psd_write(psd_write_ctx *xc, const byte *buf, int size) { int code; code = gp_fwrite(buf, 1, size, xc->f); if (code < 0) return code; return 0; } int psd_write_8(psd_write_ctx *xc, byte v) { return psd_write(xc, (byte *)&v, 1); } int psd_write_16(psd_write_ctx *xc, bits16 v) { bits16 buf; assign_u16(buf, v); return psd_write(xc, (byte *)&buf, 2); } int psd_write_32(psd_write_ctx *xc, bits32 v) { bits32 buf; assign_u32(buf, v); return psd_write(xc, (byte *)&buf, 4); } static fixed_colorant_name get_sep_name(gx_devn_prn_device *pdev, int n) { fixed_colorant_name p = NULL; int i; for (i = 0; i <= n; i++) { p = pdev->devn_params.std_colorant_names[i]; if (p == NULL) break; } return p; } static inline void psd_write_src_spot_names(psd_write_ctx *xc, gx_devn_prn_device *pdev, int chan_idx, bool has_tags) { int sep_num; const devn_separation_name *separation_name; for (; chan_idx < xc->num_channels; chan_idx++) { sep_num = xc->chnl_to_orig_sep[chan_idx] - NUM_CMYK_COMPONENTS - has_tags; 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); } } static inline void psd_write_std_extra_names(psd_write_ctx *xc, gx_devn_prn_device *pdev, int chan_idx) { for (; chan_idx < xc->num_channels; chan_idx++) { int len; fixed_colorant_name n = pdev->devn_params.std_colorant_names[chan_idx]; if (n == NULL) break; len = strlen(n); psd_write_8(xc, (byte)len); psd_write(xc, (const byte*)n, len); } } int psd_write_header(psd_write_ctx* xc, gx_devn_prn_device* pdev) { int code = 0; int num_channels = xc->num_channels; int bpc = pdev->devn_params.bitspercomponent; int chan_idx; int chan_names_len = 0; int sep_num; const devn_separation_name *separation_name; cmm_dev_profile_t *profile_struct; cmm_profile_t *dev_profile; int profile_resource_size; psd_device *pdev_psd = (psd_device*)pdev; bool has_tags = (pdev_psd->color_model == psd_DEVICE_CMYKT); int extra_std_colors = 0; 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)num_channels); /* Channels (2 Bytes) - Supported range is 1 to 56 */ psd_write_32(xc, xc->height); /* Rows */ psd_write_32(xc, xc->width); /* Columns */ psd_write_16(xc, bpc); /* Depth - 1, 8 and 16 */ /* Modes: Bitmap=0, Grayscale=1, RGB=3, CMYK=4 MultiChannel=7 Lab=9 */ psd_write_16(xc, (bits16)xc->base_num_channels); /* We use 1, 3 or 4. */ /* Color Mode Data. Only used for indexed and duotone */ psd_write_32(xc, 0); /* Resources */ /* ICC profile */ code = dev_proc(pdev, get_profile)((gx_device*)pdev, &profile_struct); if (code < 0) { dev_profile = NULL; profile_resource_size = 0; } else { dev_profile = profile_struct->device_profile[GS_DEFAULT_DEVICE_PROFILE]; /* Resource has to be padded to even size */ profile_resource_size = dev_profile->buffer_size + dev_profile->buffer_size % 2; } /* Channel Names size computation -- this will get the "Tags" name */ for (chan_idx = NUM_CMYK_COMPONENTS; chan_idx < xc->num_channels; chan_idx++) { fixed_colorant_name n = pdev->devn_params.std_colorant_names[chan_idx]; if (n == NULL) break; chan_names_len += strlen(n) + 1; } extra_std_colors = chan_idx - NUM_CMYK_COMPONENTS; for (; chan_idx < xc->num_channels; chan_idx++) { sep_num = xc->chnl_to_orig_sep[chan_idx] - NUM_CMYK_COMPONENTS - has_tags; separation_name = &(pdev->devn_params.separations.names[sep_num]); chan_names_len += (separation_name->size + 1); } /* Length of resource section */ psd_write_32(xc, 12 + (chan_names_len + (chan_names_len % 2)) + (12 + (14 * (xc->num_channels - xc->base_num_channels))) + (profile_resource_size ? (12 + profile_resource_size) : 0) + 28); /* Channel names resource */ 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)); /* If it has tags, do the spots first (if there are any), then the tags. We will need to rework this if we were to add tags to psdcmykog or similar such device that has pre-defined spots with the tags plane */ if (has_tags) { chan_idx = NUM_CMYK_COMPONENTS + extra_std_colors; psd_write_src_spot_names(xc, pdev, chan_idx, has_tags); chan_idx = NUM_CMYK_COMPONENTS; psd_write_std_extra_names(xc, pdev, chan_idx); } else { chan_idx = NUM_CMYK_COMPONENTS; psd_write_std_extra_names(xc, pdev, chan_idx); chan_idx = NUM_CMYK_COMPONENTS + extra_std_colors; psd_write_src_spot_names(xc, pdev, chan_idx, has_tags); } if (chan_names_len % 2) psd_write_8(xc, 0); /* pad */ /* DisplayInfo - Colors for each spot channels resource*/ 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_num_channels)); /* 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 { /* This is a bit of a hack, introduced for the psdcmykog device * so that we get a reasonable approximation for the colors out * even when used without the appropriate profile. */ fixed_colorant_name sepname = get_sep_name(pdev, chan_idx); if (sepname && !strcmp(sepname, "Artifex Orange")) { psd_write_16(xc, 0xfbde); /* Cyan */ psd_write_16(xc, 0x7376); /* Magenta */ psd_write_16(xc, 0x0000); /* Yellow */ psd_write_16(xc, 0xffff); /* Black */ } else if (sepname && !strcmp(sepname, "Artifex Green")) { psd_write_16(xc, 0x0000); /* Cyan */ psd_write_16(xc, 0xe33d); /* Magenta */ psd_write_16(xc, 0x0000); /* Yellow */ psd_write_16(xc, 0xf8c8); /* Black */ } 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 resource */ 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 * xc->width / pdev->width + 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 * xc->height / pdev->height + 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 */ /* ICC Profile resource */ if (profile_resource_size) { psd_write(xc, (const byte*)"8BIM", 4); psd_write_16(xc, 1039); /* 0x040F */ psd_write_16(xc, 0); /* PString */ psd_write_32(xc, profile_resource_size); psd_write(xc, dev_profile->buffer, dev_profile->buffer_size); if (dev_profile->buffer_size % 2) psd_write_8(xc, 0); } /* Layer and Mask information */ psd_write_32(xc, 0); /* No layer or mask information */ /* Compression: 0=None, 1=RLE/PackBits, 2=Deflate 3=Defalte+Prediction */ psd_write_16(xc, 0); 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) { psd_device *psd_dev = (psd_device *)pdev; int bpc = psd_dev->devn_params.bitspercomponent; int raster_plane = bitmap_raster(pdev->width * bpc); byte *planes[GS_CLIENT_COLOR_MAX_COMPONENTS]; int code = 0; int i, j; byte *sep_line; int base_num_channels = xc->base_num_channels; int chan_idx; byte * unpacked; int num_comp = xc->num_channels; gs_get_bits_params_t params; gx_downscaler_t ds = { NULL }; int octets_per_component = bpc >> 3; int octets_per_line = xc->width * octets_per_component; /* 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); sep_line = gs_alloc_bytes(pdev->memory, octets_per_line, "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, bpc, bpc, num_comp, &psd_dev->downscale, ¶ms); if (code < 0) goto cleanup; /* Print the output planes */ for (j = 0; j < xc->height; ++j) { code = gx_downscaler_get_bits_rectangle(&ds, ¶ms, j); if (code < 0) goto cleanup; for (chan_idx = 0; chan_idx < num_comp; chan_idx++) { int data_pos = xc->chnl_to_position[chan_idx]; if (data_pos >= 0) { unpacked = params.data[data_pos]; if (base_num_channels == 3) { memcpy(sep_line, unpacked, octets_per_line); } else if (octets_per_component == 1) { for (i = 0; i < xc->width; ++i) { sep_line[i] = 255 - unpacked[i]; } } else { /* octets_per_component == 2 */ for (i = 0; i < xc->width; ++i) { ((unsigned short *)sep_line)[i] = 65535 - ((unsigned short *)unpacked)[i]; } } psd_write(xc, sep_line, octets_per_line); } else if (chan_idx < NUM_CMYK_COMPONENTS) { /* Write empty process color in the area */ memset(sep_line,255,octets_per_line); psd_write(xc, sep_line, octets_per_line); } code = gp_fseek(xc->f, ((gs_offset_t)xc->height-1) * octets_per_line, SEEK_CUR); if (code < 0) { code = gs_note_error(gs_error_ioerror); goto cleanup; } } if (j < xc->height-1) { code = gp_fseek(xc->f, -((gs_offset_t)num_comp * xc->height - 1) * octets_per_line, SEEK_CUR); if (code < 0) { code = gs_note_error(gs_error_ioerror); goto cleanup; } } } 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; } bool psd_allow_multiple_pages (gx_device_printer *pdev) { psd_device *psd_dev = (psd_device *)pdev; int code; const char *fmt; bool retval = true; gs_parsed_file_name_t parsed; if (strcmp(gp_null_file_name, psd_dev->fname) == 0) { /* If the output is discarded, it doesn't matter whether * the file is format valid or not */ retval = true; } else { code = gx_parse_output_file_name(&parsed, &fmt, psd_dev->fname, strlen(psd_dev->fname), psd_dev->memory); if (code < 0 || (fmt == NULL && psd_dev->PageCount > 0)) { retval = false; } } return retval; } static int psd_print_page(gx_device_printer *pdev, gp_file *file) { psd_write_ctx xc; gx_devn_prn_device *devn_dev = (gx_devn_prn_device *)pdev; psd_device *psd_dev = (psd_device *)pdev; int code = 0; if (!psd_allow_multiple_pages(pdev)) { emprintf(pdev->memory, "Use of the %%d format is required to output more than one page to PSD\nSee doc/Devices.htm#PSD for details\n\n"); code = gs_note_error(gs_error_ioerror); } else { code = psd_setup(&xc, devn_dev, file, gx_downscaler_scale(pdev->width, psd_dev->downscale.downscale_factor), gx_downscaler_scale(pdev->height, psd_dev->downscale.downscale_factor)); if (code >= 0) code = psd_write_header(&xc, devn_dev); if (code >= 0) code = psd_write_image_data(&xc, pdev); } return code; }