/* * DDS PIKA plugin * * Copyright (C) 2004-2012 Shawn Kirst , * with parts (C) 2003 Arne Reuter where specified. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; see the file COPYING. If not, write to * the Free Software Foundation, 51 Franklin Street, Fifth Floor * Boston, MA 02110-1301, USA. */ /* ** !!! COPYRIGHT NOTICE !!! ** ** The following is based on code (C) 2003 Arne Reuter ** URL: http://www.dr-reuter.de/arne/dds.html ** */ #include "config.h" #include #include #include #include #include #include #include #include #include #include "ddsread.h" #include "dds.h" #include "dxt.h" #include "endian_rw.h" #include "misc.h" #include "imath.h" typedef struct { guchar rshift, gshift, bshift, ashift; guchar rbits, gbits, bbits, abits; guint rmask, gmask, bmask, amask; guint bpp, pika_bpp; guint pika_bps; /* bytes per sample */ gint tile_height; guchar *palette; } dds_load_info_t; static gboolean read_header (dds_header_t *hdr, FILE *fp); static gboolean read_header_dx10 (dds_header_dx10_t *hdr, FILE *fp); static gboolean validate_header (dds_header_t *hdr, GError **error); static gboolean setup_dxgi_format (dds_header_t *hdr, dds_header_dx10_t *dx10hdr, GError **error); static gboolean load_layer (FILE *fp, dds_header_t *hdr, dds_load_info_t *d, PikaImage *image, guint level, gchar *prefix, guint *l, guchar *pixels, guchar *buf, gboolean decode_images, GError **error); static gboolean load_mipmaps (FILE *fp, dds_header_t *hdr, dds_load_info_t *d, PikaImage *image, gchar *prefix, guint *l, guchar *pixels, guchar *buf, gboolean read_mipmaps, gboolean decode_images, GError **error); static gboolean load_face (FILE *fp, dds_header_t *hdr, dds_load_info_t *d, PikaImage *image, char *prefix, guint *l, guchar *pixels, guchar *buf, gboolean read_mipmaps, gboolean decode_images, GError **error); static guchar color_bits (guint mask); static guchar color_shift (guint mask); static gboolean load_dialog (PikaProcedure *procedure, GObject *config); PikaPDBStatusType read_dds (GFile *file, PikaImage **ret_image, gboolean interactive, PikaProcedure *procedure, GObject *config, GError **error) { PikaImage *image = NULL; guchar *buf; guint l = 0; guchar *pixels; FILE *fp; gsize file_size; dds_header_t hdr; dds_header_dx10_t dx10hdr; dds_load_info_t d; GList *layers; PikaImageBaseType type; PikaPrecision precision; gboolean read_mipmaps; gboolean decode_images; gint i, j; if (interactive) { pika_ui_init ("dds"); if (! load_dialog (procedure, config)) return PIKA_PDB_CANCEL; } g_object_get (config, "load-mipmaps", &read_mipmaps, "decode-images", &decode_images, NULL); fp = g_fopen (g_file_peek_path (file), "rb"); if (! fp) { g_set_error (error, G_FILE_ERROR, g_file_error_from_errno (errno), _("Could not open '%s' for reading: %s"), pika_file_get_utf8_name (file), g_strerror (errno)); return PIKA_PDB_EXECUTION_ERROR; } fseek (fp, 0L, SEEK_END); file_size = ftell (fp); fseek (fp, 0, SEEK_SET); pika_progress_init_printf ("Loading %s:", pika_file_get_utf8_name (file)); /* read header */ read_header (&hdr, fp); memset (&dx10hdr, 0, sizeof (dds_header_dx10_t)); /* read DX10 header if necessary */ if (GETL32 (hdr.pixelfmt.fourcc) == FOURCC ('D','X','1','0')) { read_header_dx10 (&dx10hdr, fp); if (! setup_dxgi_format (&hdr, &dx10hdr, error)) { fclose (fp); return PIKA_PDB_EXECUTION_ERROR; } } if (! validate_header (&hdr, error)) { fclose (fp); return PIKA_PDB_EXECUTION_ERROR; } /* a lot of DDS images out there don't have this for some reason -_- */ if (hdr.pitch_or_linsize == 0) { if (hdr.pixelfmt.flags & DDPF_FOURCC) /* assume linear size */ { hdr.pitch_or_linsize = ((hdr.width + 3) >> 2) * ((hdr.height + 3) >> 2); switch (GETL32 (hdr.pixelfmt.fourcc)) { case FOURCC ('D','X','T','1'): case FOURCC ('A','T','I','1'): case FOURCC ('B','C','4','U'): case FOURCC ('B','C','4','S'): hdr.pitch_or_linsize *= 8; break; default: hdr.pitch_or_linsize *= 16; break; } } else /* assume pitch */ { hdr.pitch_or_linsize = hdr.height * hdr.width * (hdr.pixelfmt.bpp >> 3); } } if (hdr.pixelfmt.flags & DDPF_FOURCC) { /* fourcc is dXt* or rXgb */ if (hdr.pixelfmt.fourcc[1] == 'X') hdr.pixelfmt.flags |= DDPF_ALPHAPIXELS; } d.rshift = color_shift (hdr.pixelfmt.rmask); d.gshift = color_shift (hdr.pixelfmt.gmask); d.bshift = color_shift (hdr.pixelfmt.bmask); d.ashift = color_shift (hdr.pixelfmt.amask); d.rbits = color_bits (hdr.pixelfmt.rmask); d.gbits = color_bits (hdr.pixelfmt.gmask); d.bbits = color_bits (hdr.pixelfmt.bmask); d.abits = color_bits (hdr.pixelfmt.amask); if (d.rbits <= 8) d.rmask = (hdr.pixelfmt.rmask >> d.rshift) << (8 - d.rbits); else d.rmask = (hdr.pixelfmt.rmask >> d.rshift) << (16 - d.rbits); if (d.gbits <= 8) d.gmask = (hdr.pixelfmt.gmask >> d.gshift) << (8 - d.gbits); else d.gmask = (hdr.pixelfmt.gmask >> d.gshift) << (16 - d.gbits); if (d.bbits <= 8) d.bmask = (hdr.pixelfmt.bmask >> d.bshift) << (8 - d.bbits); else d.bmask = (hdr.pixelfmt.bmask >> d.bshift) << (16 - d.bbits); if (d.abits <= 8) d.amask = (hdr.pixelfmt.amask >> d.ashift) << (8 - d.abits); else d.amask = (hdr.pixelfmt.amask >> d.ashift) << (16 - d.abits); d.pika_bps = 1; /* Most formats will be converted to 1 byte per sample */ if (hdr.pixelfmt.flags & DDPF_FOURCC) { switch (GETL32 (hdr.pixelfmt.fourcc)) { case FOURCC ('A','T','I','1'): case FOURCC ('B','C','4','U'): case FOURCC ('B','C','4','S'): d.bpp = d.pika_bpp = 1; type = PIKA_GRAY; break; case FOURCC ('A','T','I','2'): case FOURCC ('B','C','5','U'): case FOURCC ('B','C','5','S'): d.bpp = d.pika_bpp = 3; type = PIKA_RGB; break; default: d.bpp = d.pika_bpp = 4; type = PIKA_RGB; break; } } else { d.bpp = hdr.pixelfmt.bpp >> 3; if (d.bpp == 2) { if (hdr.pixelfmt.amask == 0xf000) /* RGBA4 */ { d.pika_bpp = 4; type = PIKA_RGB; } else if (hdr.pixelfmt.amask == 0xff00) /* L8A8 */ { d.pika_bpp = 2; type = PIKA_GRAY; } else if (hdr.pixelfmt.bmask == 0x1f) /* R5G6B5 or RGB5A1 */ { if (hdr.pixelfmt.amask == 0x8000) /* RGB5A1 */ d.pika_bpp = 4; else d.pika_bpp = 3; type = PIKA_RGB; } else if (hdr.pixelfmt.rmask == 0xffff || /* L16 */ hdr.pixelfmt.gmask == 0xffff || hdr.pixelfmt.bmask == 0xffff || hdr.pixelfmt.amask == 0xffff) { d.pika_bpp = 2; d.pika_bps = 2; type = PIKA_GRAY; } else { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, "Unsupported uncompressed dds format: " "bpp: %d, Rmask: %x, Gmask: %x, Bmask: %x, Amask: %x", hdr.pixelfmt.bpp, hdr.pixelfmt.rmask, hdr.pixelfmt.gmask, hdr.pixelfmt.bmask, hdr.pixelfmt.amask); return PIKA_PDB_EXECUTION_ERROR; } } else { if (hdr.pixelfmt.flags & DDPF_PALETTEINDEXED8) { type = PIKA_INDEXED; d.pika_bpp = 1; } else if (hdr.pixelfmt.rmask == 0xe0) /* R3G3B2 */ { type = PIKA_RGB; d.pika_bpp = 3; } else if (d.bpp == 4) { type = PIKA_RGB; if (d.rbits > 8 || d.gbits > 8 || d.bbits > 8 || d.abits > 8) { d.pika_bps = 2; d.pika_bpp = 8; } else { d.pika_bpp = d.bpp; } } else { /* test alpha only image */ if (d.bpp == 1 && (hdr.pixelfmt.flags & DDPF_ALPHA)) { d.pika_bpp = 2; type = PIKA_GRAY; } else { d.pika_bpp = d.bpp; type = (d.bpp == 1) ? PIKA_GRAY : PIKA_RGB; } } } } if (d.pika_bps == 2) { precision = PIKA_PRECISION_U16_NON_LINEAR; } else { precision = PIKA_PRECISION_U8_NON_LINEAR; } /* verify header information is accurate */ if (d.bpp < 1 || (hdr.pitch_or_linsize > (file_size - sizeof (hdr)))) { fclose (fp); g_set_error (error, G_FILE_ERROR, g_file_error_from_errno (errno), _("Invalid or corrupted DDS header")); return PIKA_PDB_EXECUTION_ERROR; } image = pika_image_new_with_precision (hdr.width, hdr.height, type, precision); if (! image) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_NOMEM, _("Could not allocate a new image.")); fclose (fp); return PIKA_PDB_EXECUTION_ERROR; } if (hdr.pixelfmt.flags & DDPF_PALETTEINDEXED8) { d.palette = g_malloc (256 * 4); if (fread (d.palette, 1, 1024, fp) != 1024) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Error reading palette.")); fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } for (i = j = 0; i < 768; i += 3, j += 4) { d.palette[i + 0] = d.palette[j + 0]; d.palette[i + 1] = d.palette[j + 1]; d.palette[i + 2] = d.palette[j + 2]; } pika_image_set_colormap (image, d.palette, 256); } d.tile_height = pika_tile_height (); pixels = g_new (guchar, d.tile_height * hdr.width * d.pika_bpp); buf = g_malloc (hdr.pitch_or_linsize); if (! (hdr.caps.caps2 & DDSCAPS2_CUBEMAP) && ! (hdr.caps.caps2 & DDSCAPS2_VOLUME) && dx10hdr.arraySize == 0) { if (! load_layer (fp, &hdr, &d, image, 0, "", &l, pixels, buf, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if (! load_mipmaps (fp, &hdr, &d, image, "", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } } else if (hdr.caps.caps2 & DDSCAPS2_CUBEMAP) { if ((hdr.caps.caps2 & DDSCAPS2_CUBEMAP_POSITIVEX) && ! load_face (fp, &hdr, &d, image, "(positive x)", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if ((hdr.caps.caps2 & DDSCAPS2_CUBEMAP_NEGATIVEX) && ! load_face (fp, &hdr, &d, image, "(negative x)", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if ((hdr.caps.caps2 & DDSCAPS2_CUBEMAP_POSITIVEY) && ! load_face (fp, &hdr, &d, image, "(positive y)", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if ((hdr.caps.caps2 & DDSCAPS2_CUBEMAP_NEGATIVEY) && ! load_face (fp, &hdr, &d, image, "(negative y)", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if ((hdr.caps.caps2 & DDSCAPS2_CUBEMAP_POSITIVEZ) && ! load_face (fp, &hdr, &d, image, "(positive z)", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if ((hdr.caps.caps2 & DDSCAPS2_CUBEMAP_NEGATIVEZ) && ! load_face (fp, &hdr, &d, image, "(negative z)", &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } } else if ((hdr.caps.caps2 & DDSCAPS2_VOLUME) && (hdr.flags & DDSD_DEPTH)) { guint i, level; gchar *plane; for (i = 0; i < hdr.depth; ++i) { plane = g_strdup_printf ("(z = %d)", i); if (! load_layer (fp, &hdr, &d, image, 0, plane, &l, pixels, buf, decode_images, error)) { g_free (plane); fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } g_free (plane); } if ((hdr.flags & DDSD_MIPMAPCOUNT) && (hdr.caps.caps1 & DDSCAPS_MIPMAP) && read_mipmaps) { for (level = 1; level < hdr.num_mipmaps; ++level) { int n = hdr.depth >> level; if (n < 1) n = 1; for (i = 0; i < n; ++i) { plane = g_strdup_printf ("(z = %d)", i); if (! load_layer (fp, &hdr, &d, image, level, plane, &l, pixels, buf, decode_images, error)) { g_free (plane); fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } g_free (plane); } } } } else if (dx10hdr.arraySize > 0) { guint i; gchar *elem; for (i = 0; i < dx10hdr.arraySize; ++i) { elem = g_strdup_printf ("(array element %d)", i); if (! load_layer (fp, &hdr, &d, image, 0, elem, &l, pixels, buf, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } if (! load_mipmaps (fp, &hdr, &d, image, elem, &l, pixels, buf, read_mipmaps, decode_images, error)) { fclose (fp); pika_image_delete (image); return PIKA_PDB_EXECUTION_ERROR; } g_free (elem); } } pika_progress_update (1.0); if (hdr.pixelfmt.flags & DDPF_PALETTEINDEXED8) g_free (d.palette); g_free (buf); g_free (pixels); fclose (fp); layers = pika_image_list_layers (image); if (! layers) { /* XXX This error should never happen, and probably it should be a * CRITICAL/g_return_if_fail(). Yet let's just set it to the * GError until we better handle the debug dialog for plug-ins. A * pop-up with this message will be easier to track. No need to * localize it though. */ g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, "Oops! NULL image read! Please report this!"); return PIKA_PDB_EXECUTION_ERROR; } pika_image_take_selected_layers (image, layers); *ret_image = image; return PIKA_PDB_SUCCESS; } static gboolean read_header (dds_header_t *hdr, FILE *fp) { guchar buf[DDS_HEADERSIZE]; memset (hdr, 0, sizeof (dds_header_t)); if (fread (buf, 1, DDS_HEADERSIZE, fp) != DDS_HEADERSIZE) return FALSE; hdr->magic = GETL32(buf); hdr->size = GETL32 (buf + 4); hdr->flags = GETL32 (buf + 8); hdr->height = GETL32 (buf + 12); hdr->width = GETL32 (buf + 16); hdr->pitch_or_linsize = GETL32 (buf + 20); hdr->depth = GETL32 (buf + 24); hdr->num_mipmaps = GETL32 (buf + 28); hdr->pixelfmt.size = GETL32 (buf + 76); hdr->pixelfmt.flags = GETL32 (buf + 80); hdr->pixelfmt.fourcc[0] = buf[84]; hdr->pixelfmt.fourcc[1] = buf[85]; hdr->pixelfmt.fourcc[2] = buf[86]; hdr->pixelfmt.fourcc[3] = buf[87]; hdr->pixelfmt.bpp = GETL32 (buf + 88); hdr->pixelfmt.rmask = GETL32 (buf + 92); hdr->pixelfmt.gmask = GETL32 (buf + 96); hdr->pixelfmt.bmask = GETL32 (buf + 100); hdr->pixelfmt.amask = GETL32 (buf + 104); hdr->caps.caps1 = GETL32 (buf + 108); hdr->caps.caps2 = GETL32 (buf + 112); /* PIKA-DDS special info */ if (GETL32 (buf + 32) == FOURCC ('G','I','M','P') && GETL32 (buf + 36) == FOURCC ('-','D','D','S')) { hdr->reserved.pika_dds_special.magic1 = GETL32 (buf + 32); hdr->reserved.pika_dds_special.magic2 = GETL32 (buf + 36); hdr->reserved.pika_dds_special.version = GETL32 (buf + 40); hdr->reserved.pika_dds_special.extra_fourcc = GETL32 (buf + 44); } return TRUE; } static gboolean read_header_dx10 (dds_header_dx10_t *hdr, FILE *fp) { gchar buf[DDS_HEADERSIZE_DX10]; memset (hdr, 0, sizeof (dds_header_dx10_t)); if (fread (buf, 1, DDS_HEADERSIZE_DX10, fp) != DDS_HEADERSIZE_DX10) return FALSE; hdr->dxgiFormat = GETL32 (buf); hdr->resourceDimension = GETL32 (buf + 4); hdr->miscFlag = GETL32 (buf + 8); hdr->arraySize = GETL32 (buf + 12); hdr->reserved = GETL32 (buf + 16); return TRUE; } static gboolean validate_header (dds_header_t *hdr, GError **error) { guint fourcc; if (hdr->magic != FOURCC ('D','D','S',' ')) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_INVAL, _("Invalid DDS format magic number.")); return FALSE; } if (hdr->pixelfmt.flags & DDPF_FOURCC) { /* These format errors are recoverable as we recognize other codes * allowing us to decode the image without data loss. * Therefore let's not bother with GUI error messaging, but still * print out the warning to standard error. See #5357. */ if (hdr->flags & DDSD_PITCH) { g_printerr ("Warning: DDSD_PITCH is incorrectly set for DDPF_FOURCC! (recovered)\n"); hdr->flags &= DDSD_PITCH; } if (! (hdr->flags & DDSD_LINEARSIZE)) { g_printerr ("Warning: DDSD_LINEARSIZE is incorrectly not set for DDPF_FOURCC! (recovered)\n"); hdr->flags |= DDSD_LINEARSIZE; } } else { if (! (hdr->flags & DDSD_PITCH)) { g_printerr ("Warning: DDSD_PITCH is incorrectly not set for an uncompressed texture! (recovered)\n"); hdr->flags |= DDSD_PITCH; } if ((hdr->flags & DDSD_LINEARSIZE)) { g_printerr ("Warning: DDSD_LINEARSIZE is incorrectly set for an uncompressed texture! (recovered)\n"); hdr->flags &= DDSD_LINEARSIZE; } } /* if ((hdr->pixelfmt.flags & DDPF_FOURCC) == (hdr->pixelfmt.flags & DDPF_RGB)) { g_message ("Invalid pixel format.\n"); return 0; } */ fourcc = GETL32(hdr->pixelfmt.fourcc); if ((hdr->pixelfmt.flags & DDPF_FOURCC) && fourcc != FOURCC ('D','X','T','1') && fourcc != FOURCC ('D','X','T','2') && fourcc != FOURCC ('D','X','T','3') && fourcc != FOURCC ('D','X','T','4') && fourcc != FOURCC ('D','X','T','5') && fourcc != FOURCC ('R','X','G','B') && fourcc != FOURCC ('A','T','I','1') && fourcc != FOURCC ('B','C','4','U') && fourcc != FOURCC ('B','C','4','S') && fourcc != FOURCC ('A','T','I','2') && fourcc != FOURCC ('B','C','5','U') && fourcc != FOURCC ('B','C','5','S') && fourcc != FOURCC ('D','X','1','0')) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, "Unsupported format (FOURCC: %c%c%c%c, hex: %08x).", hdr->pixelfmt.fourcc[0], hdr->pixelfmt.fourcc[1], hdr->pixelfmt.fourcc[2], hdr->pixelfmt.fourcc[3], GETL32(hdr->pixelfmt.fourcc)); return FALSE; } if (hdr->pixelfmt.flags & DDPF_RGB) { if ((hdr->pixelfmt.bpp != 8) && (hdr->pixelfmt.bpp != 16) && (hdr->pixelfmt.bpp != 24) && (hdr->pixelfmt.bpp != 32)) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Invalid bpp value for RGB data: %d"), hdr->pixelfmt.bpp); return FALSE; } } else if (hdr->pixelfmt.flags & DDPF_LUMINANCE) { if ((hdr->pixelfmt.bpp != 8) && (hdr->pixelfmt.bpp != 16)) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Invalid bpp value for luminance data: %d"), hdr->pixelfmt.bpp); return FALSE; } hdr->pixelfmt.flags |= DDPF_RGB; } else if (hdr->pixelfmt.flags & DDPF_PALETTEINDEXED8) { hdr->pixelfmt.flags |= DDPF_RGB; } if (! (hdr->pixelfmt.flags & DDPF_RGB) && ! (hdr->pixelfmt.flags & DDPF_ALPHA) && ! (hdr->pixelfmt.flags & DDPF_FOURCC) && ! (hdr->pixelfmt.flags & DDPF_LUMINANCE)) { g_message ("Unknown pixel format! Taking a guess, expect trouble!"); switch (fourcc) { case FOURCC ('D','X','T','1'): case FOURCC ('D','X','T','2'): case FOURCC ('D','X','T','3'): case FOURCC ('D','X','T','4'): case FOURCC ('D','X','T','5'): case FOURCC ('R','X','G','B'): case FOURCC ('A','T','I','1'): case FOURCC ('B','C','4','U'): case FOURCC ('B','C','4','S'): case FOURCC ('A','T','I','2'): case FOURCC ('B','C','5','U'): case FOURCC ('B','C','5','S'): hdr->pixelfmt.flags |= DDPF_FOURCC; break; default: switch (hdr->pixelfmt.bpp) { case 8: if (hdr->pixelfmt.flags & DDPF_ALPHAPIXELS) hdr->pixelfmt.flags |= DDPF_ALPHA; else hdr->pixelfmt.flags |= DDPF_LUMINANCE; break; case 16: case 24: case 32: case 64: hdr->pixelfmt.flags |= DDPF_RGB; break; default: g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Invalid pixel format.")); return FALSE; } break; } } return TRUE; } /* * This function will set the necessary flags and attributes in the standard * dds header using the information found in the DX10 header. */ static gboolean setup_dxgi_format (dds_header_t *hdr, dds_header_dx10_t *dx10hdr, GError **error) { if ((dx10hdr->resourceDimension == D3D10_RESOURCE_DIMENSION_TEXTURE2D) && (dx10hdr->miscFlag & D3D10_RESOURCE_MISC_TEXTURECUBE)) { hdr->caps.caps2 |= DDSCAPS2_CUBEMAP | DDSCAPS2_CUBEMAP_ALL_FACES; } else if (dx10hdr->resourceDimension == D3D10_RESOURCE_DIMENSION_TEXTURE3D) { hdr->flags |= DDSD_DEPTH; hdr->caps.caps2 |= DDSCAPS2_VOLUME; } if ((dx10hdr->resourceDimension != D3D10_RESOURCE_DIMENSION_TEXTURE1D) && (dx10hdr->resourceDimension != D3D10_RESOURCE_DIMENSION_TEXTURE2D) && (dx10hdr->resourceDimension != D3D10_RESOURCE_DIMENSION_TEXTURE3D)) return FALSE; /* check for a compressed DXGI format */ if ((dx10hdr->dxgiFormat >= DXGI_FORMAT_BC1_TYPELESS) && (dx10hdr->dxgiFormat <= DXGI_FORMAT_BC5_SNORM)) { /* set flag and replace FOURCC */ hdr->pixelfmt.flags |= DDPF_FOURCC; switch (dx10hdr->dxgiFormat) { case DXGI_FORMAT_BC1_TYPELESS: case DXGI_FORMAT_BC1_UNORM: case DXGI_FORMAT_BC1_UNORM_SRGB: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('D','X','T','1')); break; case DXGI_FORMAT_BC2_TYPELESS: case DXGI_FORMAT_BC2_UNORM: case DXGI_FORMAT_BC2_UNORM_SRGB: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('D','X','T','3')); break; case DXGI_FORMAT_BC3_TYPELESS: case DXGI_FORMAT_BC3_UNORM: case DXGI_FORMAT_BC3_UNORM_SRGB: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('D','X','T','5')); break; case DXGI_FORMAT_BC4_TYPELESS: case DXGI_FORMAT_BC4_UNORM: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('A','T','I','1')); break; case DXGI_FORMAT_BC4_SNORM: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('B','C','4','S')); break; case DXGI_FORMAT_BC5_TYPELESS: case DXGI_FORMAT_BC5_UNORM: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('A','T','I','2')); break; case DXGI_FORMAT_BC5_SNORM: PUTL32(hdr->pixelfmt.fourcc, FOURCC ('B','C','5','S')); break; default: break; } } else { /* unset the FOURCC flag */ hdr->pixelfmt.flags &= ~DDPF_FOURCC; switch (dx10hdr->dxgiFormat) { case DXGI_FORMAT_B8G8R8A8_TYPELESS: case DXGI_FORMAT_B8G8R8A8_UNORM: case DXGI_FORMAT_B8G8R8A8_UNORM_SRGB: hdr->pixelfmt.bpp = 32; hdr->pixelfmt.flags |= DDPF_ALPHAPIXELS; hdr->pixelfmt.rmask = 0x00ff0000; hdr->pixelfmt.gmask = 0x0000ff00; hdr->pixelfmt.bmask = 0x000000ff; hdr->pixelfmt.amask = 0xff000000; break; case DXGI_FORMAT_B8G8R8X8_TYPELESS: case DXGI_FORMAT_B8G8R8X8_UNORM: case DXGI_FORMAT_B8G8R8X8_UNORM_SRGB: hdr->pixelfmt.bpp = 32; hdr->pixelfmt.flags |= DDPF_ALPHAPIXELS; hdr->pixelfmt.rmask = 0x00ff0000; hdr->pixelfmt.gmask = 0x0000ff00; hdr->pixelfmt.bmask = 0x000000ff; hdr->pixelfmt.amask = 0x00000000; break; case DXGI_FORMAT_R8G8B8A8_TYPELESS: case DXGI_FORMAT_R8G8B8A8_UNORM: case DXGI_FORMAT_R8G8B8A8_UNORM_SRGB: case DXGI_FORMAT_R8G8B8A8_UINT: case DXGI_FORMAT_R8G8B8A8_SNORM: case DXGI_FORMAT_R8G8B8A8_SINT: hdr->pixelfmt.bpp = 32; hdr->pixelfmt.flags |= DDPF_ALPHAPIXELS; hdr->pixelfmt.rmask = 0x000000ff; hdr->pixelfmt.gmask = 0x0000ff00; hdr->pixelfmt.bmask = 0x00ff0000; hdr->pixelfmt.amask = 0xff000000; break; case DXGI_FORMAT_B5G6R5_UNORM: hdr->pixelfmt.bpp = 16; hdr->pixelfmt.rmask = 0x0000f800; hdr->pixelfmt.gmask = 0x000007e0; hdr->pixelfmt.bmask = 0x0000001f; hdr->pixelfmt.amask = 0x00000000; break; case DXGI_FORMAT_B5G5R5A1_UNORM: hdr->pixelfmt.bpp = 16; hdr->pixelfmt.rmask = 0x00007c00; hdr->pixelfmt.gmask = 0x000003e0; hdr->pixelfmt.bmask = 0x0000001f; hdr->pixelfmt.amask = 0x00008000; break; case DXGI_FORMAT_R10G10B10A2_TYPELESS: case DXGI_FORMAT_R10G10B10A2_UNORM: case DXGI_FORMAT_R10G10B10A2_UINT: hdr->pixelfmt.bpp = 32; hdr->pixelfmt.flags |= DDPF_ALPHAPIXELS; hdr->pixelfmt.rmask = 0x000003ff; hdr->pixelfmt.gmask = 0x000ffc00; hdr->pixelfmt.bmask = 0x3ff00000; hdr->pixelfmt.amask = 0xc0000000; break; case DXGI_FORMAT_A8_UNORM: hdr->pixelfmt.bpp = 8; hdr->pixelfmt.flags |= DDPF_ALPHA | DDPF_ALPHAPIXELS; hdr->pixelfmt.rmask = hdr->pixelfmt.gmask = hdr->pixelfmt.bmask = 0; hdr->pixelfmt.amask = 0x000000ff; break; case DXGI_FORMAT_R8_TYPELESS: case DXGI_FORMAT_R8_UNORM: case DXGI_FORMAT_R8_UINT: case DXGI_FORMAT_R8_SNORM: case DXGI_FORMAT_R8_SINT: hdr->pixelfmt.bpp = 8; hdr->pixelfmt.rmask = 0x000000ff; hdr->pixelfmt.gmask = hdr->pixelfmt.bmask = hdr->pixelfmt.amask = 0; break; case DXGI_FORMAT_B4G4R4A4_UNORM: hdr->pixelfmt.bpp = 16; hdr->pixelfmt.flags |= DDPF_ALPHAPIXELS; hdr->pixelfmt.rmask = 0x00000f00; hdr->pixelfmt.gmask = 0x000000f0; hdr->pixelfmt.bmask = 0x0000000f; hdr->pixelfmt.amask = 0x0000f000; break; case DXGI_FORMAT_UNKNOWN: g_message ("Unknown DXGI format. Expect problems..."); break; default: /* unsupported DXGI format */ g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Unsupported DXGI format (%d)"), dx10hdr->dxgiFormat); return FALSE; } } return TRUE; } static const Babl * premultiplied_variant (const Babl* format) { if (format == babl_format ("R'G'B'A u8")) return babl_format ("R'aG'aB'aA u8"); else g_printerr ("Add format %s to premultiplied_variant () %s: %d\n", babl_get_name (format), __FILE__, __LINE__); return format; } static gboolean load_layer (FILE *fp, dds_header_t *hdr, dds_load_info_t *d, PikaImage *image, guint level, char *prefix, guint *l, guchar *pixels, guchar *buf, gboolean decode_images, GError **error) { GeglBuffer *buffer; const Babl *bablfmt = NULL; PikaImageType type = PIKA_RGBA_IMAGE; gchar *layer_name; gint x, y, z, n; PikaLayer *layer; guint width = hdr->width >> level; guint height = hdr->height >> level; guint size = hdr->pitch_or_linsize >> (2 * level); guint layerw; gint format = DDS_COMPRESS_NONE; gsize file_size; gsize current_position; current_position = ftell (fp); fseek (fp, 0L, SEEK_END); file_size = ftell (fp); fseek (fp, current_position, SEEK_SET); if (width < 1) width = 1; if (height < 1) height = 1; switch (d->bpp) { case 1: if (hdr->pixelfmt.flags & DDPF_PALETTEINDEXED8) { type = PIKA_INDEXED_IMAGE; } else if (hdr->pixelfmt.rmask == 0xe0) { type = PIKA_RGB_IMAGE; bablfmt = babl_format ("R'G'B' u8"); } else if (hdr->pixelfmt.flags & DDPF_ALPHA) { type = PIKA_GRAYA_IMAGE; bablfmt = babl_format ("Y'A u8"); } else { type = PIKA_GRAY_IMAGE; bablfmt = babl_format ("Y' u8"); } break; case 2: if ((hdr->pixelfmt.flags & (DDPF_PALETTEINDEXED8 + DDPF_ALPHA)) == DDPF_PALETTEINDEXED8 + DDPF_ALPHA) { type = PIKA_INDEXEDA_IMAGE; } else if (hdr->pixelfmt.amask == 0xf000) /* RGBA4 */ { type = PIKA_RGBA_IMAGE; bablfmt = babl_format ("R'G'B'A u8"); } else if (hdr->pixelfmt.amask == 0xff00) /* L8A8 */ { type = PIKA_GRAYA_IMAGE; bablfmt = babl_format ("Y'A u8"); } else if (hdr->pixelfmt.bmask == 0x1f) /* R5G6B5 or RGB5A1 */ { type = (hdr->pixelfmt.amask == 0x8000) ? PIKA_RGBA_IMAGE : PIKA_RGB_IMAGE; bablfmt = (hdr->pixelfmt.amask == 0x8000) ? babl_format ("R'G'B'A u8") : babl_format ("R'G'B' u8"); } else if (hdr->pixelfmt.rmask == 0xffff || /* L16 */ hdr->pixelfmt.gmask == 0xffff || hdr->pixelfmt.bmask == 0xffff || hdr->pixelfmt.amask == 0xffff) { type = PIKA_GRAY_IMAGE; bablfmt = babl_format ("Y' u16"); } break; case 3: type = PIKA_RGB_IMAGE; bablfmt = babl_format ("R'G'B' u8"); break; case 4: case 8: { type = PIKA_RGBA_IMAGE; if (d->pika_bps == 1) bablfmt = babl_format ("R'G'B'A u8"); else if (d->pika_bps == 2) bablfmt = babl_format ("R'G'B'A u16"); } break; } layer_name = (level) ? g_strdup_printf ("mipmap %d %s", level, prefix) : g_strdup_printf ("main surface %s", prefix); layer = pika_layer_new (image, layer_name, width, height, type, 100, pika_image_get_default_new_layer_mode (image)); g_free (layer_name); pika_image_insert_layer (image, layer, NULL, *l); if (type == PIKA_INDEXED_IMAGE || type == PIKA_INDEXEDA_IMAGE) bablfmt = pika_drawable_get_format (PIKA_DRAWABLE (layer)); if ((*l)++) pika_item_set_visible (PIKA_ITEM (layer), FALSE); buffer = pika_drawable_get_buffer (PIKA_DRAWABLE (layer)); layerw = gegl_buffer_get_width (buffer); if (hdr->pixelfmt.flags & DDPF_FOURCC) { guint w = (width + 3) >> 2; guint h = (height + 3) >> 2; switch (GETL32(hdr->pixelfmt.fourcc)) { case FOURCC ('D','X','T','1'): format = DDS_COMPRESS_BC1; break; case FOURCC ('D','X','T','2'): bablfmt = premultiplied_variant (bablfmt); case FOURCC ('D','X','T','3'): format = DDS_COMPRESS_BC2; break; case FOURCC ('D','X','T','4'): bablfmt = premultiplied_variant (bablfmt); case FOURCC ('D','X','T','5'): format = DDS_COMPRESS_BC3; break; case FOURCC ('R','X','G','B'): format = DDS_COMPRESS_BC3; break; case FOURCC ('A','T','I','1'): case FOURCC ('B','C','4','U'): case FOURCC ('B','C','4','S'): format = DDS_COMPRESS_BC4; break; case FOURCC ('A','T','I','2'): case FOURCC ('B','C','5','U'): case FOURCC ('B','C','5','S'): format = DDS_COMPRESS_BC5; break; } size = w * h; if ((format == DDS_COMPRESS_BC1) || (format == DDS_COMPRESS_BC4)) size *= 8; else size *= 16; } if (size > (file_size - current_position) || size > hdr->pitch_or_linsize) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Requested data exceeds size of file.\n")); return FALSE; } if ((hdr->flags & DDSD_LINEARSIZE) && !fread (buf, size, 1, fp)) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Unexpected EOF.\n")); return FALSE; } if ((hdr->pixelfmt.flags & DDPF_RGB) || (hdr->pixelfmt.flags & DDPF_ALPHA)) { guint ired = 0; guint iblue = 2; if (hdr->reserved.pika_dds_special.magic1 == FOURCC ('G','I','M','P') && hdr->reserved.pika_dds_special.version <= 199003 && hdr->reserved.pika_dds_special.version > 0 && d->bpp >= 3 && hdr->pixelfmt.amask == 0xc0000000) { /* PIKA dds plug-in versions before or equal to 199003 (3.9.91) wrote * the red and green channels reversed for RGB10A2. We will fix that here. */ g_printerr ("Switching incorrect red and green channels in RGB10A2 dds " "written by an older version of PIKA's dds plug-in.\n"); ired = 2; iblue = 0; } z = 0; for (y = 0, n = 0; y < height; ++y, ++n) { if (n >= d->tile_height) { gegl_buffer_set (buffer, GEGL_RECTANGLE (0, y - n, layerw, n), 0, bablfmt, pixels, GEGL_AUTO_ROWSTRIDE); n = 0; pika_progress_update ((double) y / (double) hdr->height); } current_position = ftell (fp); if ((hdr->flags & DDSD_PITCH) && ((width * d->bpp) > (file_size - current_position) || (width * d->bpp) > hdr->pitch_or_linsize)) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Requested data exceeds size of file.\n")); return FALSE; } if ((hdr->flags & DDSD_PITCH) && ! fread (buf, width * d->bpp, 1, fp)) { g_set_error (error, G_FILE_ERROR, G_FILE_ERROR_FAILED, _("Unexpected EOF.\n")); return FALSE; } if (!(hdr->flags & DDSD_LINEARSIZE)) z = 0; for (x = 0; x < layerw; ++x) { guint pixel = buf[z]; guint pos = (n * layerw + x) * d->pika_bpp; if (d->bpp > 1) pixel += ((guint) buf[z + 1] << 8); if (d->bpp > 2) pixel += ((guint) buf[z + 2] << 16); if (d->bpp > 3) pixel += ((guint) buf[z + 3] << 24); if (d->bpp >= 3) { if (hdr->pixelfmt.amask == 0xc0000000) /* handle RGB10A2 */ { pixels[pos + ired] = (pixel >> d->rshift) >> 2; pixels[pos + 1] = (pixel >> d->gshift) >> 2; pixels[pos + iblue] = (pixel >> d->bshift) >> 2; if (hdr->pixelfmt.flags & DDPF_ALPHAPIXELS) pixels[pos + 3] = (pixel >> d->ashift << (8 - d->abits) & d->amask) * 255 / d->amask; } else if (d->rmask > 0 && d->gmask > 0 && d->bmask > 0) { pixels[pos] = (pixel >> d->rshift << (8 - d->rbits) & d->rmask) * 255 / d->rmask; pixels[pos + 1] = (pixel >> d->gshift << (8 - d->gbits) & d->gmask) * 255 / d->gmask; pixels[pos + 2] = (pixel >> d->bshift << (8 - d->bbits) & d->bmask) * 255 / d->bmask; if (hdr->pixelfmt.flags & DDPF_ALPHAPIXELS && d->bpp == 4) { if (d->amask > 0) pixels[pos + 3] = (pixel >> d->ashift << (8 - d->abits) & d->amask) * 255 / d->amask; else pixels[pos + 3] = 255; } } else if (d->bpp == 4) { if (d->pika_bps == 2) { guint16 *pixels16 = (guint16 *) &pixels[pos]; if (d->rbits == 16) /* red */ { pixels16[0] = (guint16) (pixel >> d->rshift & d->rmask); } else { pixels16[0] = 0; } if (d->gbits == 16) /* green */ { pixels16[1] = (guint16) (pixel >> d->gshift & d->gmask); } else { pixels16[1] = 0; } if (d->bbits == 16) /* blue */ { pixels16[2] = (guint16) (pixel >> d->bshift & d->bmask); } else { pixels16[2] = 0; } if (d->abits == 16) /* alpha */ { pixels16[3] = (guint16) (pixel >> d->ashift & d->amask); } else { pixels16[3] = 0xffff; } } } } else if (d->bpp == 2) { if (hdr->pixelfmt.amask == 0xf000) /* RGBA4 */ { pixels[pos] = (pixel >> d->rshift << (8 - d->rbits) & d->rmask) * 255 / d->rmask; pixels[pos + 1] = (pixel >> d->gshift << (8 - d->gbits) & d->gmask) * 255 / d->gmask; pixels[pos + 2] = (pixel >> d->bshift << (8 - d->bbits) & d->bmask) * 255 / d->bmask; pixels[pos + 3] = (pixel >> d->ashift << (8 - d->abits) & d->amask) * 255 / d->amask; } else if (hdr->pixelfmt.amask == 0xff00) /* L8A8 */ { pixels[pos] = (pixel >> d->rshift << (8 - d->rbits) & d->rmask) * 255 / d->rmask; pixels[pos + 1] = (pixel >> d->ashift << (8 - d->abits) & d->amask) * 255 / d->amask; } else if (hdr->pixelfmt.bmask == 0x1f) /* R5G6B5 or RGB5A1 */ { pixels[pos] = (pixel >> d->rshift << (8 - d->rbits) & d->rmask) * 255 / d->rmask; pixels[pos + 1] = (pixel >> d->gshift << (8 - d->gbits) & d->gmask) * 255 / d->gmask; pixels[pos + 2] = (pixel >> d->bshift << (8 - d->bbits) & d->bmask) * 255 / d->bmask; if (hdr->pixelfmt.amask == 0x8000) { pixels[pos + 3] = (pixel >> d->ashift << (8 - d->abits) & d->amask) * 255 / d->amask; } } else if (hdr->pixelfmt.rmask == 0xffff || /* L16 */ hdr->pixelfmt.gmask == 0xffff || hdr->pixelfmt.bmask == 0xffff || hdr->pixelfmt.amask == 0xffff) { guint16 *pixels16 = (guint16 *) &pixels[pos]; *pixels16 = (guint16) (pixel & 0xffff); } } else { if (hdr->pixelfmt.flags & DDPF_PALETTEINDEXED8) { pixels[pos] = pixel & 0xff; } else if (hdr->pixelfmt.rmask == 0xe0) /* R3G3B2 */ { pixels[pos] = (pixel >> d->rshift << (8 - d->rbits) & d->rmask) * 255 / d->rmask; pixels[pos + 1] = (pixel >> d->gshift << (8 - d->gbits) & d->gmask) * 255 / d->gmask; pixels[pos + 2] = (pixel >> d->bshift << (8 - d->bbits) & d->bmask) * 255 / d->bmask; } else if (hdr->pixelfmt.flags & DDPF_ALPHA) { pixels[pos + 0] = 255; pixels[pos + 1] = pixel & 0xff; } else /* LUMINANCE */ { pixels[pos] = pixel & 0xff; } } z += d->bpp; } } gegl_buffer_set (buffer, GEGL_RECTANGLE (0, y - n, layerw, n), 0, bablfmt, pixels, GEGL_AUTO_ROWSTRIDE); } else if (hdr->pixelfmt.flags & DDPF_FOURCC) { guchar *dst; dst = g_malloc (width * height * d->pika_bpp); memset (dst, 0, width * height * d->pika_bpp); if (d->pika_bpp == 4) { for (y = 0; y < height; ++y) for (x = 0; x < width; ++x) dst[y * (width * 4) + (x * 4) + 3] = 255; } dxt_decompress (dst, buf, format, size, width, height, d->pika_bpp, hdr->pixelfmt.flags & DDPF_NORMAL); if (format == DDS_COMPRESS_BC5 && hdr->reserved.pika_dds_special.magic1 == FOURCC ('G','I','M','P') && hdr->reserved.pika_dds_special.version > 0 && hdr->reserved.pika_dds_special.version <= 199002) { /* PIKA dds plug-in versions before 199002 == 3.9.90 wrote * the red and green channels reversed. We will fix that here. */ g_printerr ("Switching incorrect red and green channels in BC5 dds " "written by an older version of PIKA's dds plug-in.\n"); for (y = 0; y < height; ++y) for (x = 0; x < width; ++x) { guchar tmpG; guint pix_width = width * d->pika_bpp; guint x_width = x * d->pika_bpp; tmpG = dst[y * pix_width + x_width]; dst[y * pix_width + x_width] = dst[y * pix_width + x_width + 1]; dst[y * pix_width + x_width + 1] = tmpG; } } z = 0; for (y = 0, n = 0; y < height; ++y, ++n) { if (n >= d->tile_height) { gegl_buffer_set (buffer, GEGL_RECTANGLE (0, y - n, layerw, n), 0, bablfmt, pixels, GEGL_AUTO_ROWSTRIDE); n = 0; pika_progress_update ((double)y / (double)hdr->height); } memcpy (pixels + n * layerw * d->pika_bpp, dst + y * layerw * d->pika_bpp, width * d->pika_bpp); } gegl_buffer_set (buffer, GEGL_RECTANGLE (0, y - n, layerw, n), 0, bablfmt, pixels, GEGL_AUTO_ROWSTRIDE); g_free (dst); } gegl_buffer_flush (buffer); g_object_unref (buffer); /* pika dds specific. decode encoded images */ if (decode_images && hdr->reserved.pika_dds_special.magic1 == FOURCC ('G','I','M','P') && hdr->reserved.pika_dds_special.magic2 == FOURCC ('-','D','D','S')) { switch (hdr->reserved.pika_dds_special.extra_fourcc) { case FOURCC ('A','E','X','P'): decode_alpha_exp_image (PIKA_DRAWABLE (layer), FALSE); break; case FOURCC ('Y','C','G','1'): decode_ycocg_image (PIKA_DRAWABLE (layer), FALSE); break; case FOURCC ('Y','C','G','2'): decode_ycocg_scaled_image (PIKA_DRAWABLE (layer), FALSE); break; default: break; } } return TRUE; } static gboolean load_mipmaps (FILE *fp, dds_header_t *hdr, dds_load_info_t *d, PikaImage *image, char *prefix, unsigned int *l, guchar *pixels, guchar *buf, gboolean read_mipmaps, gboolean decode_images, GError **error) { guint level; if ((hdr->flags & DDSD_MIPMAPCOUNT) && (hdr->caps.caps1 & DDSCAPS_MIPMAP) && read_mipmaps) { for (level = 1; level < hdr->num_mipmaps; ++level) { if (! load_layer (fp, hdr, d, image, level, prefix, l, pixels, buf, decode_images, error)) return FALSE; } } return TRUE; } static gboolean load_face (FILE *fp, dds_header_t *hdr, dds_load_info_t *d, PikaImage *image, gchar *prefix, guint *l, guchar *pixels, guchar *buf, gboolean read_mipmaps, gboolean decode_images, GError **error) { if (! load_layer (fp, hdr, d, image, 0, prefix, l, pixels, buf, decode_images, error)) return FALSE; return load_mipmaps (fp, hdr, d, image, prefix, l, pixels, buf, read_mipmaps, decode_images, error); } static guchar color_bits (guint mask) { guchar i = 0; while (mask) { if (mask & 1) ++i; mask >>= 1; } return i; } static guchar color_shift (guint mask) { guchar i = 0; if (! mask) return 0; while (!((mask >> i) & 1)) ++i; return i; } static gboolean load_dialog (PikaProcedure *procedure, GObject *config) { GtkWidget *dialog; GtkWidget *vbox; gboolean run; dialog = pika_procedure_dialog_new (procedure, PIKA_PROCEDURE_CONFIG (config), _("Open DDS")); vbox = pika_procedure_dialog_fill_box (PIKA_PROCEDURE_DIALOG (dialog), "dds-read-box", "load-mipmaps", "decode-images", NULL); gtk_box_set_spacing (GTK_BOX (vbox), 8); gtk_container_set_border_width (GTK_CONTAINER (vbox), 8); pika_procedure_dialog_fill (PIKA_PROCEDURE_DIALOG (dialog), "dds-read-box", NULL); gtk_widget_show (dialog); run = pika_procedure_dialog_run (PIKA_PROCEDURE_DIALOG (dialog)); gtk_widget_destroy (dialog); return run; }