/*

 * Copyright © 2000 SuSE, Inc.

 * Copyright © 2007 Red Hat, Inc.

 *

 * Permission to use, copy, modify, distribute, and sell this software and its

 * documentation for any purpose is hereby granted without fee, provided that

 * the above copyright notice appear in all copies and that both that

 * copyright notice and this permission notice appear in supporting

 * documentation, and that the name of SuSE not be used in advertising or

 * publicity pertaining to distribution of the software without specific,

 * written prior permission.  SuSE makes no representations about the

 * suitability of this software for any purpose.  It is provided "as is"

 * without express or implied warranty.

 *

 * SuSE DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL

 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL SuSE

 * BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES

 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION

 * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN

 * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.

 */

#ifdef HAVE_CONFIG_H

#include <pixman-config.h>

#endif

#include <stdlib.h>

#include <stdio.h>

#include <string.h>

#include <assert.h>

#include "pixman-private.h"

static const pixman_color_t transparent_black = { 0, 0, 0, 0 };

static void

gradient_property_changed (pixman_image_t *image)

{

    gradient_t *gradient = &image->gradient;

    int n = gradient->n_stops;

    pixman_gradient_stop_t *stops = gradient->stops;

    pixman_gradient_stop_t *begin = &(gradient->stops[-1]);

    pixman_gradient_stop_t *end = &(gradient->stops[n]);

    switch (gradient->common.repeat)

    {

    default:

    case PIXMAN_REPEAT_NONE:

  begin->x = INT32_MIN;

  begin->color = transparent_black;

  end->x = INT32_MAX;

  end->color = transparent_black;

  break;

    case PIXMAN_REPEAT_NORMAL:

  begin->x = stops[n - 1].x - pixman_fixed_1;

  begin->color = stops[n - 1].color;

  end->x = stops[0].x + pixman_fixed_1;

  end->color = stops[0].color;

  break;

    case PIXMAN_REPEAT_REFLECT:

  begin->x = - stops[0].x;

  begin->color = stops[0].color;

  end->x = pixman_int_to_fixed (2) - stops[n - 1].x;

  end->color = stops[n - 1].color;

  break;

    case PIXMAN_REPEAT_PAD:

  begin->x = INT32_MIN;

  begin->color = stops[0].color;

  end->x = INT32_MAX;

  end->color = stops[n - 1].color;

  break;

    }

}

pixman_bool_t

_pixman_init_gradient (gradient_t *                  gradient,

                       const pixman_gradient_stop_t *stops,

                       int                           n_stops)

{

    return_val_if_fail (n_stops > 0, FALSE);

    /* We allocate two extra stops, one before the beginning of the stop list,

     * and one after the end. These stops are initialized to whatever color

     * would be used for positions outside the range of the stop list.

     *

     * This saves a bit of computation in the gradient walker.

     *

     * The pointer we store in the gradient_t struct still points to the

     * first user-supplied struct, so when freeing, we will have to

     * subtract one.

     */

    gradient->stops =

  pixman_malloc_ab (n_stops + 2, sizeof (pixman_gradient_stop_t));

    if (!gradient->stops)

  return FALSE;

    gradient->stops += 1;

    memcpy (gradient->stops, stops, n_stops * sizeof (pixman_gradient_stop_t));

    gradient->n_stops = n_stops;

    gradient->common.property_changed = gradient_property_changed;

    return TRUE;

}

void

_pixman_image_init (pixman_image_t *image)

{

    image_common_t *common = &image->common;

    pixman_region32_init (&common->clip_region);

    common->alpha_count = 0;

    common->have_clip_region = FALSE;

    common->clip_sources = FALSE;

    common->transform = NULL;

    common->repeat = PIXMAN_REPEAT_NONE;

    common->filter = PIXMAN_FILTER_NEAREST;

    common->filter_params = NULL;

    common->n_filter_params = 0;

    common->alpha_map = NULL;

    common->component_alpha = FALSE;

    common->ref_count = 1;

    common->property_changed = NULL;

    common->client_clip = FALSE;

    common->destroy_func = NULL;

    common->destroy_data = NULL;

    common->dirty = TRUE;

}

pixman_bool_t

_pixman_image_fini (pixman_image_t *image)

{

    image_common_t *common = (image_common_t *)image;

    common->ref_count--;

    if (common->ref_count == 0)

    {

  if (image->common.destroy_func)

      image->common.destroy_func (image, image->common.destroy_data);

  pixman_region32_fini (&common->clip_region);

  free (common->transform);

  free (common->filter_params);

  if (common->alpha_map)

      pixman_image_unref ((pixman_image_t *)common->alpha_map);

  if (image->type == LINEAR ||

      image->type == RADIAL ||

      image->type == CONICAL)

  {

      if (image->gradient.stops)

      {

    /* See _pixman_init_gradient() for an explanation of the - 1 */

    free (image->gradient.stops - 1);

      }

      /* This will trigger if someone adds a property_changed

       * method to the linear/radial/conical gradient overwriting

       * the general one.

       */

      assert (

    image->common.property_changed == gradient_property_changed);

  }

  if (image->type == BITS && image->bits.free_me)

      free (image->bits.free_me);

  return TRUE;

    }

    return FALSE;

}

pixman_image_t *

_pixman_image_allocate (void)

{

    pixman_image_t *image = malloc (sizeof (pixman_image_t));

    if (image)

  _pixman_image_init (image);

    return image;

}

static void

image_property_changed (pixman_image_t *image)

{

    image->common.dirty = TRUE;

}

/* Ref Counting */

PIXMAN_EXPORT pixman_image_t *

pixman_image_ref (pixman_image_t *image)

{

    image->common.ref_count++;

    return image;

}

/* returns TRUE when the image is freed */

PIXMAN_EXPORT pixman_bool_t

pixman_image_unref (pixman_image_t *image)

{

    if (_pixman_image_fini (image))

    {

  free (image);

  return TRUE;

    }

    return FALSE;

}

PIXMAN_EXPORT void

pixman_image_set_destroy_function (pixman_image_t *            image,

                                   pixman_image_destroy_func_t func,

                                   void *                      data)

{

    image->common.destroy_func = func;

    image->common.destroy_data = data;

}

PIXMAN_EXPORT void *

pixman_image_get_destroy_data (pixman_image_t *image)

{

  return image->common.destroy_data;

}

void

_pixman_image_reset_clip_region (pixman_image_t *image)

{

    image->common.have_clip_region = FALSE;

}

/* Executive Summary: This function is a no-op that only exists

 * for historical reasons.

 *

 * There used to be a bug in the X server where it would rely on

 * out-of-bounds accesses when it was asked to composite with a

 * window as the source. It would create a pixman image pointing

 * to some bogus position in memory, but then set a clip region

 * to the position where the actual bits were.

 *

 * Due to a bug in old versions of pixman, where it would not clip

 * against the image bounds when a clip region was set, this would

 * actually work. So when the pixman bug was fixed, a workaround was

 * added to allow certain out-of-bound accesses. This function disabled

 * those workarounds.

 *

 * Since 0.21.2, pixman doesn't do these workarounds anymore, so now

 * this function is a no-op.

 */

PIXMAN_EXPORT void

pixman_disable_out_of_bounds_workaround (void)

{

}

static void

compute_image_info (pixman_image_t *image)

{

    pixman_format_code_t code;

    uint32_t flags = 0;

    /* Transform */

    if (!image->common.transform)

    {

  flags |= (FAST_PATH_ID_TRANSFORM  |

      FAST_PATH_X_UNIT_POSITIVE  |

      FAST_PATH_Y_UNIT_ZERO    |

      FAST_PATH_AFFINE_TRANSFORM);

    }

    else

    {

  flags |= FAST_PATH_HAS_TRANSFORM;

  if (image->common.transform->matrix[2][0] == 0      &&

      image->common.transform->matrix[2][1] == 0      &&

      image->common.transform->matrix[2][2] == pixman_fixed_1)

  {

      flags |= FAST_PATH_AFFINE_TRANSFORM;

      if (image->common.transform->matrix[0][1] == 0 &&

    image->common.transform->matrix[1][0] == 0)

      {

    if (image->common.transform->matrix[0][0] == -pixman_fixed_1 &&

        image->common.transform->matrix[1][1] == -pixman_fixed_1)

    {

        flags |= FAST_PATH_ROTATE_180_TRANSFORM;

    }

    flags |= FAST_PATH_SCALE_TRANSFORM;

      }

      else if (image->common.transform->matrix[0][0] == 0 &&

               image->common.transform->matrix[1][1] == 0)

      {

    pixman_fixed_t m01 = image->common.transform->matrix[0][1];

    pixman_fixed_t m10 = image->common.transform->matrix[1][0];

    if (m01 == -pixman_fixed_1 && m10 == pixman_fixed_1)

        flags |= FAST_PATH_ROTATE_90_TRANSFORM;

    else if (m01 == pixman_fixed_1 && m10 == -pixman_fixed_1)

        flags |= FAST_PATH_ROTATE_270_TRANSFORM;

      }

  }

  if (image->common.transform->matrix[0][0] > 0)

      flags |= FAST_PATH_X_UNIT_POSITIVE;

  if (image->common.transform->matrix[1][0] == 0)

      flags |= FAST_PATH_Y_UNIT_ZERO;

    }

    /* Filter */

    switch (image->common.filter)

    {

    case PIXMAN_FILTER_NEAREST:

    case PIXMAN_FILTER_FAST:

  flags |= (FAST_PATH_NEAREST_FILTER | FAST_PATH_NO_CONVOLUTION_FILTER);

  break;

    case PIXMAN_FILTER_BILINEAR:

    case PIXMAN_FILTER_GOOD:

    case PIXMAN_FILTER_BEST:

  flags |= (FAST_PATH_BILINEAR_FILTER | FAST_PATH_NO_CONVOLUTION_FILTER);

  /* Here we have a chance to optimize BILINEAR filter to NEAREST if

   * they are equivalent for the currently used transformation matrix.

   */

  if (flags & FAST_PATH_ID_TRANSFORM)

  {

      flags |= FAST_PATH_NEAREST_FILTER;

  }

  else if (flags & FAST_PATH_AFFINE_TRANSFORM)

  {

      /* Suppose the transform is

       *

       *    [ t00, t01, t02 ]

       *    [ t10, t11, t12 ]

       *    [   0,   0,   1 ]

       *

       * and the destination coordinates are (n + 0.5, m + 0.5). Then

       * the transformed x coordinate is:

       *

       *     tx = t00 * (n + 0.5) + t01 * (m + 0.5) + t02

       *        = t00 * n + t01 * m + t02 + (t00 + t01) * 0.5

       *

       * which implies that if t00, t01 and t02 are all integers

       * and (t00 + t01) is odd, then tx will be an integer plus 0.5,

       * which means a BILINEAR filter will reduce to NEAREST. The same

       * applies in the y direction

       */

      pixman_fixed_t (*t)[3] = image->common.transform->matrix;

      if ((pixman_fixed_frac (

         t[0][0] | t[0][1] | t[0][2] |

         t[1][0] | t[1][1] | t[1][2]) == 0)     &&

    (pixman_fixed_to_int (

        (t[0][0] + t[0][1]) & (t[1][0] + t[1][1])) % 2) == 1)

      {

    /* FIXME: there are some affine-test failures, showing that

     * handling of BILINEAR and NEAREST filter is not quite

     * equivalent when getting close to 32K for the translation

     * components of the matrix. That's likely some bug, but for

     * now just skip BILINEAR->NEAREST optimization in this case.

     */

    pixman_fixed_t magic_limit = pixman_int_to_fixed (30000);

    if (image->common.transform->matrix[0][2] <= magic_limit  &&

        image->common.transform->matrix[1][2] <= magic_limit  &&

        image->common.transform->matrix[0][2] >= -magic_limit &&

        image->common.transform->matrix[1][2] >= -magic_limit)

    {

        flags |= FAST_PATH_NEAREST_FILTER;

    }

      }

  }

  break;

    case PIXMAN_FILTER_CONVOLUTION:

  break;

    case PIXMAN_FILTER_SEPARABLE_CONVOLUTION:

  flags |= FAST_PATH_SEPARABLE_CONVOLUTION_FILTER;

  break;

    default:

  flags |= FAST_PATH_NO_CONVOLUTION_FILTER;

  break;

    }

    /* Repeat mode */

    switch (image->common.repeat)

    {

    case PIXMAN_REPEAT_NONE:

  flags |=

      FAST_PATH_NO_REFLECT_REPEAT    |

      FAST_PATH_NO_PAD_REPEAT    |

      FAST_PATH_NO_NORMAL_REPEAT;

  break;

    case PIXMAN_REPEAT_REFLECT:

  flags |=

      FAST_PATH_NO_PAD_REPEAT    |

      FAST_PATH_NO_NONE_REPEAT    |

      FAST_PATH_NO_NORMAL_REPEAT;

  break;

    case PIXMAN_REPEAT_PAD:

  flags |=

      FAST_PATH_NO_REFLECT_REPEAT    |

      FAST_PATH_NO_NONE_REPEAT    |

      FAST_PATH_NO_NORMAL_REPEAT;

  break;

    default:

  flags |=

      FAST_PATH_NO_REFLECT_REPEAT    |

      FAST_PATH_NO_PAD_REPEAT    |

      FAST_PATH_NO_NONE_REPEAT;

  break;

    }

    /* Component alpha */

    if (image->common.component_alpha)

  flags |= FAST_PATH_COMPONENT_ALPHA;

    else

  flags |= FAST_PATH_UNIFIED_ALPHA;

    flags |= (FAST_PATH_NO_ACCESSORS | FAST_PATH_NARROW_FORMAT);

    /* Type specific checks */

    switch (image->type)

    {

    case SOLID:

  code = PIXMAN_solid;

  if (image->solid.color.alpha == 0xffff)

      flags |= FAST_PATH_IS_OPAQUE;

  break;

    case BITS:

  if (image->bits.width == 1  &&

      image->bits.height == 1  &&

      image->common.repeat != PIXMAN_REPEAT_NONE)

  {

      code = PIXMAN_solid;

  }

  else

  {

      code = image->bits.format;

      flags |= FAST_PATH_BITS_IMAGE;

  }

  if (!PIXMAN_FORMAT_A (image->bits.format)       &&

      PIXMAN_FORMAT_TYPE (image->bits.format) != PIXMAN_TYPE_GRAY    &&

      PIXMAN_FORMAT_TYPE (image->bits.format) != PIXMAN_TYPE_COLOR)

  {

      flags |= FAST_PATH_SAMPLES_OPAQUE;

      if (image->common.repeat != PIXMAN_REPEAT_NONE)

    flags |= FAST_PATH_IS_OPAQUE;

  }

  if (image->bits.read_func || image->bits.write_func)

      flags &= ~FAST_PATH_NO_ACCESSORS;

  if (PIXMAN_FORMAT_IS_WIDE (image->bits.format))

      flags &= ~FAST_PATH_NARROW_FORMAT;

  break;

    case RADIAL:

  code = PIXMAN_unknown;

  /*

   * As explained in pixman-radial-gradient.c, every point of

   * the plane has a valid associated radius (and thus will be

   * colored) if and only if a is negative (i.e. one of the two

   * circles contains the other one).

   */

        if (image->radial.a >= 0)

      break;

  /* Fall through */

    case CONICAL:

    case LINEAR:

  code = PIXMAN_unknown;

  if (image->common.repeat != PIXMAN_REPEAT_NONE)

  {

      int i;

      flags |= FAST_PATH_IS_OPAQUE;

      for (i = 0; i < image->gradient.n_stops; ++i)

      {

    if (image->gradient.stops[i].color.alpha != 0xffff)

    {

        flags &= ~FAST_PATH_IS_OPAQUE;

        break;

    }

      }

  }

  break;

    default:

  code = PIXMAN_unknown;

  break;

    }

    /* Alpha maps are only supported for BITS images, so it's always

     * safe to ignore their presense for non-BITS images

     */

    if (!image->common.alpha_map || image->type != BITS)

    {

  flags |= FAST_PATH_NO_ALPHA_MAP;

    }

    else

    {

  if (PIXMAN_FORMAT_IS_WIDE (image->common.alpha_map->format))

      flags &= ~FAST_PATH_NARROW_FORMAT;

    }

    /* Both alpha maps and convolution filters can introduce

     * non-opaqueness in otherwise opaque images. Also

     * an image with component alpha turned on is only opaque

     * if all channels are opaque, so we simply turn it off

     * unconditionally for those images.

     */

    if (image->common.alpha_map            ||

  image->common.filter == PIXMAN_FILTER_CONVOLUTION    ||

        image->common.filter == PIXMAN_FILTER_SEPARABLE_CONVOLUTION     ||

  image->common.component_alpha)

    {

  flags &= ~(FAST_PATH_IS_OPAQUE | FAST_PATH_SAMPLES_OPAQUE);

    }

    image->common.flags = flags;

    image->common.extended_format_code = code;

}

void

_pixman_image_validate (pixman_image_t *image)

{

    if (image->common.dirty)

    {

  compute_image_info (image);

  /* It is important that property_changed is

   * called *after* compute_image_info() because

   * property_changed() can make use of the flags

   * to set up accessors etc.

   */

  if (image->common.property_changed)

      image->common.property_changed (image);

  image->common.dirty = FALSE;

    }

    if (image->common.alpha_map)

  _pixman_image_validate ((pixman_image_t *)image->common.alpha_map);

}

PIXMAN_EXPORT pixman_bool_t

pixman_image_set_clip_region32 (pixman_image_t *   image,

                                const pixman_region32_t *region)

{

    image_common_t *common = (image_common_t *)image;

    pixman_bool_t result;

    if (region)

    {

  if ((result = pixman_region32_copy (&common->clip_region, region)))

      image->common.have_clip_region = TRUE;

    }

    else

    {

  _pixman_image_reset_clip_region (image);

  result = TRUE;

    }

    image_property_changed (image);

    return result;

}

PIXMAN_EXPORT pixman_bool_t

pixman_image_set_clip_region (pixman_image_t *   image,

                              const pixman_region16_t *region)

{

    image_common_t *common = (image_common_t *)image;

    pixman_bool_t result;

    if (region)

    {

  if ((result = pixman_region32_copy_from_region16 (&common->clip_region, region)))

      image->common.have_clip_region = TRUE;

    }

    else

    {

  _pixman_image_reset_clip_region (image);

  result = TRUE;

    }

    image_property_changed (image);

    return result;

}

PIXMAN_EXPORT void

pixman_image_set_has_client_clip (pixman_image_t *image,

                                  pixman_bool_t   client_clip)

{

    image->common.client_clip = client_clip;

}

PIXMAN_EXPORT pixman_bool_t

pixman_image_set_transform (pixman_image_t *          image,

                            const pixman_transform_t *transform)

{

    static const pixman_transform_t id =

    {

  { { pixman_fixed_1, 0, 0 },

    { 0, pixman_fixed_1, 0 },

    { 0, 0, pixman_fixed_1 } }

    };

    image_common_t *common = (image_common_t *)image;

    pixman_bool_t result;

    if (common->transform == transform)

  return TRUE;

    if (!transform || memcmp (&id, transform, sizeof (pixman_transform_t)) == 0)

    {

  free (common->transform);

  common->transform = NULL;

  result = TRUE;

  goto out;

    }

    if (common->transform &&

  memcmp (common->transform, transform, sizeof (pixman_transform_t)) == 0)

    {

  return TRUE;

    }

    if (common->transform == NULL)

  common->transform = malloc (sizeof (pixman_transform_t));

    if (common->transform == NULL)

    {

  result = FALSE;

  goto out;

    }

    memcpy (common->transform, transform, sizeof(pixman_transform_t));

    result = TRUE;

out:

    image_property_changed (image);

    return result;

}

PIXMAN_EXPORT void

pixman_image_set_repeat (pixman_image_t *image,

                         pixman_repeat_t repeat)

{

    if (image->common.repeat == repeat)

  return;

    image->common.repeat = repeat;

    image_property_changed (image);

}

PIXMAN_EXPORT void

pixman_image_set_dither (pixman_image_t *image,

       pixman_dither_t dither)

{

    if (image->type == BITS)

    {

  if (image->bits.dither == dither)

      return;

  image->bits.dither = dither;

  image_property_changed (image);

    }

}

PIXMAN_EXPORT void

pixman_image_set_dither_offset (pixman_image_t *image,

        int             offset_x,

        int             offset_y)

{

    if (image->type == BITS)

    {

  if (image->bits.dither_offset_x == offset_x &&

      image->bits.dither_offset_y == offset_y)

  {

      return;

  }

  image->bits.dither_offset_x = offset_x;

  image->bits.dither_offset_y = offset_y;

  image_property_changed (image);

    }

}

PIXMAN_EXPORT pixman_bool_t

pixman_image_set_filter (pixman_image_t *      image,

                         pixman_filter_t       filter,

                         const pixman_fixed_t *params,

                         int                   n_params)

{

    image_common_t *common = (image_common_t *)image;

    pixman_fixed_t *new_params;

    if (params == common->filter_params && filter == common->filter)

  return TRUE;

    if (filter == PIXMAN_FILTER_SEPARABLE_CONVOLUTION)

    {

  int width = pixman_fixed_to_int (params[0]);

  int height = pixman_fixed_to_int (params[1]);

  int x_phase_bits = pixman_fixed_to_int (params[2]);

  int y_phase_bits = pixman_fixed_to_int (params[3]);

  int n_x_phases = (1 << x_phase_bits);

  int n_y_phases = (1 << y_phase_bits);

  return_val_if_fail (

      n_params == 4 + n_x_phases * width + n_y_phases * height, FALSE);

    }

    new_params = NULL;

    if (params)

    {

  new_params = pixman_malloc_ab (n_params, sizeof (pixman_fixed_t));

  if (!new_params)

      return FALSE;

  memcpy (new_params,

          params, n_params * sizeof (pixman_fixed_t));

    }

    common->filter = filter;

    if (common->filter_params)

  free (common->filter_params);

    common->filter_params = new_params;

    common->n_filter_params = n_params;

    image_property_changed (image);

    return TRUE;

}

PIXMAN_EXPORT void

pixman_image_set_source_clipping (pixman_image_t *image,

                                  pixman_bool_t   clip_sources)

{

    if (image->common.clip_sources == clip_sources)

  return;

    image->common.clip_sources = clip_sources;

    image_property_changed (image);

}

/* Unlike all the other property setters, this function does not

 * copy the content of indexed. Doing this copying is simply

 * way, way too expensive.

 */

PIXMAN_EXPORT void

pixman_image_set_indexed (pixman_image_t *        image,

                          const pixman_indexed_t *indexed)

{

    bits_image_t *bits = (bits_image_t *)image;

    if (bits->indexed == indexed)

  return;

    bits->indexed = indexed;

    image_property_changed (image);

}

PIXMAN_EXPORT void

pixman_image_set_alpha_map (pixman_image_t *image,

                            pixman_image_t *alpha_map,

                            int16_t         x,

                            int16_t         y)

{

    image_common_t *common = (image_common_t *)image;

    return_if_fail (!alpha_map || alpha_map->type == BITS);

    if (alpha_map && common->alpha_count > 0)

    {

  /* If this image is being used as an alpha map itself,

   * then you can't give it an alpha map of its own.

   */

  return;

    }

    if (alpha_map && alpha_map->common.alpha_map)

    {

  /* If the image has an alpha map of its own,

   * then it can't be used as an alpha map itself

   */

  return;

    }

    if (common->alpha_map != (bits_image_t *)alpha_map)

    {

  if (common->alpha_map)

  {

      common->alpha_map->common.alpha_count--;

      pixman_image_unref ((pixman_image_t *)common->alpha_map);

  }

  if (alpha_map)

  {

      common->alpha_map = (bits_image_t *)pixman_image_ref (alpha_map);

      common->alpha_map->common.alpha_count++;

  }

  else

  {

      common->alpha_map = NULL;

  }

    }

    common->alpha_origin_x = x;

    common->alpha_origin_y = y;

    image_property_changed (image);

}

PIXMAN_EXPORT void

pixman_image_set_component_alpha   (pixman_image_t *image,

                                    pixman_bool_t   component_alpha)

{

    if (image->common.component_alpha == component_alpha)

  return;

    image->common.component_alpha = component_alpha;

    image_property_changed (image);

}

PIXMAN_EXPORT pixman_bool_t

pixman_image_get_component_alpha   (pixman_image_t       *image)

{

    return image->common.component_alpha;

}

PIXMAN_EXPORT void

pixman_image_set_accessors (pixman_image_t *           image,

                            pixman_read_memory_func_t  read_func,

                            pixman_write_memory_func_t write_func)

{

    return_if_fail (image != NULL);

    if (image->type == BITS)

    {

  /* Accessors only work for <= 32 bpp. */

  if (PIXMAN_FORMAT_BPP(image->bits.format) > 32)

      return_if_fail (!read_func && !write_func);

  image->bits.read_func = read_func;

  image->bits.write_func = write_func;

  image_property_changed (image);

    }

}

PIXMAN_EXPORT uint32_t *

pixman_image_get_data (pixman_image_t *image)

{

    if (image->type == BITS)

  return image->bits.bits;

    return NULL;

}

PIXMAN_EXPORT int

pixman_image_get_width (pixman_image_t *image)

{

    if (image->type == BITS)

  return image->bits.width;

    return 0;

}

PIXMAN_EXPORT int

pixman_image_get_height (pixman_image_t *image)

{

    if (image->type == BITS)

  return image->bits.height;

    return 0;

}

PIXMAN_EXPORT int

pixman_image_get_stride (pixman_image_t *image)

{

    if (image->type == BITS)

  return image->bits.rowstride * (int) sizeof (uint32_t);

    return 0;

}

PIXMAN_EXPORT int

pixman_image_get_depth (pixman_image_t *image)

{

    if (image->type == BITS)

  return PIXMAN_FORMAT_DEPTH (image->bits.format);

    return 0;

}

PIXMAN_EXPORT pixman_format_code_t

pixman_image_get_format (pixman_image_t *image)

{

    if (image->type == BITS)

  return image->bits.format;

    return PIXMAN_null;

}

uint32_t

_pixman_image_get_solid (pixman_implementation_t *imp,

       pixman_image_t *         image,

                         pixman_format_code_t     format)

{

    uint32_t result;

    if (image->type == SOLID)

    {

  result = image->solid.color_32;

    }

    else if (image->type == BITS)

    {

  if (image->bits.format == PIXMAN_a8r8g8b8)

      result = image->bits.bits[0];

  else if (image->bits.format == PIXMAN_x8r8g8b8)

      result = image->bits.bits[0] | 0xff000000;

  else if (image->bits.format == PIXMAN_a8)

      result = (uint32_t)(*(uint8_t *)image->bits.bits) << 24;

  else

      goto otherwise;

    }

    else

    {

  pixman_iter_t iter;

    otherwise:

  _pixman_implementation_iter_init (

      imp, &iter, image, 0, 0, 1, 1,

      (uint8_t *)&result,

      ITER_NARROW | ITER_SRC, image->common.flags);

  result = *iter.get_scanline (&iter, NULL);

  if (iter.fini)

      iter.fini (&iter);

    }

    /* If necessary, convert RGB <--> BGR. */

    if (PIXMAN_FORMAT_TYPE (format) != PIXMAN_TYPE_ARGB

  && PIXMAN_FORMAT_TYPE (format) != PIXMAN_TYPE_ARGB_SRGB)

    {

  result = (((result & 0xff000000) >>  0) |

            ((result & 0x00ff0000) >> 16) |

            ((result & 0x0000ff00) >>  0) |

            ((result & 0x000000ff) << 16));

    }

    return result;

}