static void
clutter_clone_apply_transform (ClutterActor *self, CoglMatrix *matrix)
{
ClutterClonePrivate *priv = CLUTTER_CLONE (self)->priv;
ClutterActorBox box, source_box;
gfloat x_scale, y_scale;
/* First chain up and apply all the standard ClutterActor
* transformations... */
CLUTTER_ACTOR_CLASS (clutter_clone_parent_class)->apply_transform (self,
matrix);
/* if we don't have a source, nothing else to do */
if (priv->clone_source == NULL)
return;
/* get our allocated size */
clutter_actor_get_allocation_box (self, &box);
/* and get the allocated size of the source */
clutter_actor_get_allocation_box (priv->clone_source, &source_box);
/* We need to scale what the clone-source actor paints to fill our own
* allocation...
*/
x_scale = clutter_actor_box_get_width (&box)
/ clutter_actor_box_get_width (&source_box);
y_scale = clutter_actor_box_get_height (&box)
/ clutter_actor_box_get_height (&source_box);
cogl_matrix_scale (matrix, x_scale, y_scale, x_scale);
}
void
cogl_matrix_view_2d_in_frustum (CoglMatrix *matrix,
float left,
float right,
float bottom,
float top,
float z_near,
float z_2d,
float width_2d,
float height_2d)
{
float left_2d_plane = left / z_near * z_2d;
float right_2d_plane = right / z_near * z_2d;
float bottom_2d_plane = bottom / z_near * z_2d;
float top_2d_plane = top / z_near * z_2d;
float width_2d_start = right_2d_plane - left_2d_plane;
float height_2d_start = top_2d_plane - bottom_2d_plane;
/* Factors to scale from framebuffer geometry to frustum
* cross-section geometry. */
float width_scale = width_2d_start / width_2d;
float height_scale = height_2d_start / height_2d;
cogl_matrix_translate (matrix,
left_2d_plane, top_2d_plane, -z_2d);
cogl_matrix_scale (matrix, width_scale, -height_scale, width_scale);
}
void
rig_camera_update_view (RigEngine *engine, RutEntity *camera, CoglBool shadow_pass)
{
RutCamera *camera_component =
rut_entity_get_component (camera, RUT_COMPONENT_TYPE_CAMERA);
CoglMatrix transform;
CoglMatrix inverse_transform;
CoglMatrix view;
/* translate to z_2d and scale */
if (!shadow_pass)
view = engine->main_view;
else
view = engine->identity;
/* apply the camera viewing transform */
rut_graphable_get_transform (camera, &transform);
cogl_matrix_get_inverse (&transform, &inverse_transform);
cogl_matrix_multiply (&view, &view, &inverse_transform);
if (shadow_pass)
{
CoglMatrix flipped_view;
cogl_matrix_init_identity (&flipped_view);
cogl_matrix_scale (&flipped_view, 1, -1, 1);
cogl_matrix_multiply (&flipped_view, &flipped_view, &view);
rut_camera_set_view_transform (camera_component, &flipped_view);
}
else
rut_camera_set_view_transform (camera_component, &view);
}
void
rut_transform_scale (RutTransform *transform,
float x,
float y,
float z)
{
cogl_matrix_scale (&transform->matrix, x, y, z);
}
static void
paint_matrix_pipeline (CoglPipeline *pipeline)
{
CoglMatrix matrices[4];
float matrix_floats[16 * 4];
int uniform_location;
int i;
for (i = 0; i < 4; i++)
cogl_matrix_init_identity (matrices + i);
/* Use the first matrix to make the color red */
cogl_matrix_translate (matrices + 0, 1.0f, 0.0f, 0.0f);
/* Rotate the vertex so that it ends up green */
cogl_matrix_rotate (matrices + 1, 90.0f, 0.0f, 0.0f, 1.0f);
/* Scale the vertex so it ends up halved */
cogl_matrix_scale (matrices + 2, 0.5f, 0.5f, 0.5f);
/* Add a blue component in the final matrix. The final matrix is
uploaded as transposed so we need to transpose first to cancel
that out */
cogl_matrix_translate (matrices + 3, 0.0f, 0.0f, 1.0f);
cogl_matrix_transpose (matrices + 3);
for (i = 0; i < 4; i++)
memcpy (matrix_floats + i * 16,
cogl_matrix_get_array (matrices + i),
sizeof (float) * 16);
/* Set the first three matrices as transposed */
uniform_location =
cogl_pipeline_get_uniform_location (pipeline, "matrix_array");
cogl_pipeline_set_uniform_matrix (pipeline,
uniform_location,
4, /* dimensions */
3, /* count */
FALSE, /* not transposed */
matrix_floats);
/* Set the last matrix as untransposed */
uniform_location =
cogl_pipeline_get_uniform_location (pipeline, "matrix_array[3]");
cogl_pipeline_set_uniform_matrix (pipeline,
uniform_location,
4, /* dimensions */
1, /* count */
TRUE, /* transposed */
matrix_floats + 16 * 3);
paint_pipeline (pipeline, 12);
}
void
_cogl_matrix_stack_scale (CoglMatrixStack *stack,
float x,
float y,
float z)
{
CoglMatrixState *state;
state = _cogl_matrix_stack_top_mutable (stack, TRUE);
cogl_matrix_scale (&state->matrix, x, y, z);
state->is_identity = FALSE;
stack->age++;
}
void
mai_node_draw_recursive (MaiNode *self)
{
CoglMatrix initial_mtx;
cogl_matrix_init_identity (&initial_mtx);
cogl_set_modelview_matrix (&initial_mtx);
cogl_set_source_color4ub ('\x1', '\x1', '\xFF', 255);
cogl_set_source_texture (g_testtex);
cogl_ortho (0, 64, 0, 64, -1, 1);
cogl_matrix_translate (&initial_mtx, 20.0f, 20.0f, 0.0f);
cogl_matrix_scale (&initial_mtx, 5.0f, 5.0f, 1.0f);
cogl_matrix_rotate(&initial_mtx, -90.0f, 1.0f, 0.0f, 0.0f);
_mai_node_draw_recursive (self, &initial_mtx);
cogl_flush ();
}
static void
mx_deform_bow_tie_texture_vflip (ClutterTexture *texture)
{
CoglHandle material;
material = clutter_texture_get_cogl_material (texture);
if (material)
{
CoglMatrix matrix;
cogl_matrix_init_identity (&matrix);
/* Vflip */
cogl_matrix_scale (&matrix, 1.f, -1.f, 1.f);
cogl_matrix_translate (&matrix, 0.f, 1.f, 0.f);
cogl_material_set_layer_matrix (material, 0, &matrix);
}
}
static RutShapeModel *
shape_model_new (RutContext *ctx,
CoglBool shaped,
float tex_width,
float tex_height)
{
RutShapeModel *shape_model = g_slice_new (RutShapeModel);
RutBuffer *buffer = rut_buffer_new (sizeof (CoglVertexP3) * 6);
RutMesh *pick_mesh = rut_mesh_new_from_buffer_p3 (COGL_VERTICES_MODE_TRIANGLES,
6,
buffer);
CoglVertexP3 *pick_vertices = (CoglVertexP3 *)buffer->data;
CoglMatrix matrix;
float tex_aspect;
float size_x;
float size_y;
float half_size_x;
float half_size_y;
float geom_size_x;
float geom_size_y;
float half_geom_size_x;
float half_geom_size_y;
rut_object_init (&shape_model->_parent, &rut_shape_model_type);
shape_model->ref_count = 1;
if (shaped)
{
/* In this case we are using a shape mask texture which is has a
* square size and is padded with transparent pixels to provide
* antialiasing. The shape mask is half the size of the texture
* itself so we make the geometry twice as large to compensate.
*/
size_x = MIN (tex_width, tex_height);
size_y = size_x;
geom_size_x = size_x * 2.0;
geom_size_y = geom_size_x;
}
else
{
size_x = tex_width;
size_y = tex_height;
geom_size_x = tex_width;
geom_size_y = tex_height;
}
half_size_x = size_x / 2.0;
half_size_y = size_y / 2.0;
half_geom_size_x = geom_size_x / 2.0;
half_geom_size_y = geom_size_y / 2.0;
{
int n_vertices;
int i;
VertexP2T2T2 vertices[] =
{
{ -half_geom_size_x, -half_geom_size_y, 0, 0, 0, 0 },
{ -half_geom_size_x, half_geom_size_y, 0, 1, 0, 1 },
{ half_geom_size_x, half_geom_size_y, 1, 1, 1, 1 },
{ -half_geom_size_x, -half_geom_size_y, 0, 0, 0, 0 },
{ half_geom_size_x, half_geom_size_y, 1, 1, 1, 1 },
{ half_geom_size_x, -half_geom_size_y, 1, 0, 1, 0 },
};
cogl_matrix_init_identity (&matrix);
tex_aspect = (float)tex_width / (float)tex_height;
if (shaped)
{
float s_scale, t_scale;
float s0, t0;
/* NB: The circle mask texture has a centered circle that is
* half the width of the texture itself. We want the primary
* texture to be mapped to this center circle. */
s_scale = 2;
t_scale = 2;
if (tex_aspect < 1) /* taller than it is wide */
t_scale *= tex_aspect;
else /* wider than it is tall */
{
float inverse_aspect = 1.0f / tex_aspect;
s_scale *= inverse_aspect;
}
s0 = 0.5 - (s_scale / 2.0);
t0 = 0.5 - (t_scale / 2.0);
cogl_matrix_translate (&matrix, s0, t0, 0);
cogl_matrix_scale (&matrix, s_scale, t_scale, 1);
}
n_vertices = sizeof (vertices) / sizeof (VertexP2T2T2);
for (i = 0; i < n_vertices; i++)
{
float z = 0, w = 1;
cogl_matrix_transform_point (&matrix,
&vertices[i].s1,
&vertices[i].t1,
&z,
&w);
#ifdef MESA_CONST_ATTRIB_BUG_WORKAROUND
vertices[i].Nx = 0;
vertices[i].Ny = 0;
vertices[i].Nz = 1;
vertices[i].Tx = 1;
vertices[i].Ty = 0;
vertices[i].Tz = 0;
#endif
}
shape_model->primitive =
primitive_new_p2t2t2 (ctx->cogl_context,
COGL_VERTICES_MODE_TRIANGLES,
n_vertices,
vertices);
}
shape_model->shape_texture = cogl_object_ref (ctx->circle_texture);
pick_vertices[0].x = -half_size_x;
pick_vertices[0].y = -half_size_y;
pick_vertices[1].x = -half_size_x;
pick_vertices[1].y = half_size_y;
pick_vertices[2].x = half_size_x;
pick_vertices[2].y = half_size_y;
pick_vertices[3] = pick_vertices[0];
pick_vertices[4] = pick_vertices[2];
pick_vertices[5].x = half_size_x;
pick_vertices[5].y = -half_size_y;
shape_model->pick_mesh = pick_mesh;
return shape_model;
}
/* For reference: There was some deliberation over whether to have a
* constructor that could throw an exception but looking at standard
* practices with several high level OO languages including python, C++,
* C# Java and Ruby they all support exceptions in constructors and the
* general consensus appears to be that throwing an exception is neater
* than successfully constructing with an internal error status that
* would then have to be explicitly checked via some form of ::is_ok()
* method.
*/
CoglContext *
cogl_context_new (CoglDisplay *display,
CoglError **error)
{
CoglContext *context;
uint8_t white_pixel[] = { 0xff, 0xff, 0xff, 0xff };
CoglBitmap *white_pixel_bitmap;
const CoglWinsysVtable *winsys;
int i;
CoglError *internal_error = NULL;
_cogl_init ();
#ifdef COGL_ENABLE_PROFILE
/* We need to be absolutely sure that uprof has been initialized
* before calling _cogl_uprof_init. uprof_init (NULL, NULL)
* will be a NOP if it has been initialized but it will also
* mean subsequent parsing of the UProf GOptionGroup will have no
* affect.
*
* Sadly GOptionGroup based library initialization is extremely
* fragile by design because GOptionGroups have no notion of
* dependencies and so the order things are initialized isn't
* currently under tight control.
*/
uprof_init (NULL, NULL);
_cogl_uprof_init ();
#endif
/* Allocate context memory */
context = g_malloc0 (sizeof (CoglContext));
/* Convert the context into an object immediately in case any of the
code below wants to verify that the context pointer is a valid
object */
_cogl_context_object_new (context);
/* XXX: Gross hack!
* Currently everything in Cogl just assumes there is a default
* context which it can access via _COGL_GET_CONTEXT() including
* code used to construct a CoglContext. Until all of that code
* has been updated to take an explicit context argument we have
* to immediately make our pointer the default context.
*/
_cogl_context = context;
/* Init default values */
memset (context->features, 0, sizeof (context->features));
context->feature_flags = 0;
memset (context->private_features, 0, sizeof (context->private_features));
context->rectangle_state = COGL_WINSYS_RECTANGLE_STATE_UNKNOWN;
memset (context->winsys_features, 0, sizeof (context->winsys_features));
if (!display)
{
CoglRenderer *renderer = cogl_renderer_new ();
if (!cogl_renderer_connect (renderer, error))
{
g_free (context);
return NULL;
}
display = cogl_display_new (renderer, NULL);
cogl_object_unref(renderer);
}
else
cogl_object_ref (display);
if (!cogl_display_setup (display, error))
{
cogl_object_unref (display);
g_free (context);
return NULL;
}
context->display = display;
/* This is duplicated data, but it's much more convenient to have
the driver attached to the context and the value is accessed a
lot throughout Cogl */
context->driver = display->renderer->driver;
/* Again this is duplicated data, but it convenient to be able
* access these from the context. */
context->driver_vtable = display->renderer->driver_vtable;
context->texture_driver = display->renderer->texture_driver;
for (i = 0; i < G_N_ELEMENTS (context->private_features); i++)
context->private_features[i] |= display->renderer->private_features[i];
winsys = _cogl_context_get_winsys (context);
if (!winsys->context_init (context, error))
{
cogl_object_unref (display);
g_free (context);
return NULL;
}
context->attribute_name_states_hash =
g_hash_table_new_full (g_str_hash, g_str_equal, g_free, g_free);
context->attribute_name_index_map = NULL;
context->n_attribute_names = 0;
/* The "cogl_color_in" attribute needs a deterministic name_index
* so we make sure it's the first attribute name we register */
_cogl_attribute_register_attribute_name (context, "cogl_color_in");
context->uniform_names =
g_ptr_array_new_with_free_func ((GDestroyNotify) g_free);
context->uniform_name_hash = g_hash_table_new (g_str_hash, g_str_equal);
context->n_uniform_names = 0;
/* Initialise the driver specific state */
_cogl_init_feature_overrides (context);
/* XXX: ONGOING BUG: Intel viewport scissor
*
* Intel gen6 drivers don't currently correctly handle offset
* viewports, since primitives aren't clipped within the bounds of
* the viewport. To workaround this we push our own clip for the
* viewport that will use scissoring to ensure we clip as expected.
*
* TODO: file a bug upstream!
*/
if (context->gpu.driver_package == COGL_GPU_INFO_DRIVER_PACKAGE_MESA &&
context->gpu.architecture == COGL_GPU_INFO_ARCHITECTURE_SANDYBRIDGE &&
!getenv ("COGL_DISABLE_INTEL_VIEWPORT_SCISSORT_WORKAROUND"))
context->needs_viewport_scissor_workaround = TRUE;
else
context->needs_viewport_scissor_workaround = FALSE;
context->sampler_cache = _cogl_sampler_cache_new (context);
_cogl_pipeline_init_default_pipeline ();
_cogl_pipeline_init_default_layers ();
_cogl_pipeline_init_state_hash_functions ();
_cogl_pipeline_init_layer_state_hash_functions ();
context->current_clip_stack_valid = FALSE;
context->current_clip_stack = NULL;
context->legacy_backface_culling_enabled = FALSE;
cogl_matrix_init_identity (&context->identity_matrix);
cogl_matrix_init_identity (&context->y_flip_matrix);
cogl_matrix_scale (&context->y_flip_matrix, 1, -1, 1);
context->flushed_matrix_mode = COGL_MATRIX_MODELVIEW;
context->texture_units =
g_array_new (FALSE, FALSE, sizeof (CoglTextureUnit));
if (_cogl_has_private_feature (context, COGL_PRIVATE_FEATURE_ANY_GL))
{
/* See cogl-pipeline.c for more details about why we leave texture unit 1
* active by default... */
context->active_texture_unit = 1;
GE (context, glActiveTexture (GL_TEXTURE1));
}
context->legacy_fog_state.enabled = FALSE;
context->opaque_color_pipeline = cogl_pipeline_new (context);
context->blended_color_pipeline = cogl_pipeline_new (context);
context->texture_pipeline = cogl_pipeline_new (context);
context->codegen_header_buffer = g_string_new ("");
context->codegen_source_buffer = g_string_new ("");
context->codegen_boilerplate_buffer = g_string_new ("");
context->source_stack = NULL;
context->legacy_state_set = 0;
context->default_gl_texture_2d_tex = NULL;
context->default_gl_texture_3d_tex = NULL;
context->default_gl_texture_rect_tex = NULL;
context->framebuffers = NULL;
context->current_draw_buffer = NULL;
context->current_read_buffer = NULL;
context->current_draw_buffer_state_flushed = 0;
context->current_draw_buffer_changes = COGL_FRAMEBUFFER_STATE_ALL;
context->swap_callback_closures =
g_hash_table_new (g_direct_hash, g_direct_equal);
_cogl_list_init (&context->onscreen_events_queue);
_cogl_list_init (&context->onscreen_dirty_queue);
g_queue_init (&context->gles2_context_stack);
context->journal_flush_attributes_array =
g_array_new (TRUE, FALSE, sizeof (CoglAttribute *));
context->journal_clip_bounds = NULL;
context->polygon_vertices = g_array_new (FALSE, FALSE, sizeof (float));
context->current_pipeline = NULL;
context->current_pipeline_changes_since_flush = 0;
context->current_pipeline_with_color_attrib = FALSE;
_cogl_bitmask_init (&context->enabled_builtin_attributes);
_cogl_bitmask_init (&context->enable_builtin_attributes_tmp);
_cogl_bitmask_init (&context->enabled_texcoord_attributes);
_cogl_bitmask_init (&context->enable_texcoord_attributes_tmp);
_cogl_bitmask_init (&context->enabled_custom_attributes);
_cogl_bitmask_init (&context->enable_custom_attributes_tmp);
_cogl_bitmask_init (&context->changed_bits_tmp);
context->max_texture_units = -1;
context->max_activateable_texture_units = -1;
context->current_fragment_program_type = COGL_PIPELINE_PROGRAM_TYPE_GLSL;
context->current_vertex_program_type = COGL_PIPELINE_PROGRAM_TYPE_GLSL;
context->current_gl_program = 0;
context->current_gl_dither_enabled = TRUE;
context->current_gl_color_mask = COGL_COLOR_MASK_ALL;
context->gl_blend_enable_cache = FALSE;
context->depth_test_enabled_cache = FALSE;
context->depth_test_function_cache = COGL_DEPTH_TEST_FUNCTION_LESS;
context->depth_writing_enabled_cache = TRUE;
context->depth_range_near_cache = 0;
context->depth_range_far_cache = 1;
context->legacy_depth_test_enabled = FALSE;
context->pipeline_cache = _cogl_pipeline_cache_new ();
for (i = 0; i < COGL_BUFFER_BIND_TARGET_COUNT; i++)
context->current_buffer[i] = NULL;
context->window_buffer = NULL;
context->framebuffer_stack = _cogl_create_framebuffer_stack ();
/* XXX: In this case the Clutter backend is still responsible for
* the OpenGL binding API and for creating onscreen framebuffers and
* so we have to add a dummy framebuffer to represent the backend
* owned window... */
if (_cogl_context_get_winsys (context) == _cogl_winsys_stub_get_vtable ())
{
CoglOnscreen *window = _cogl_onscreen_new ();
cogl_set_framebuffer (COGL_FRAMEBUFFER (window));
cogl_object_unref (COGL_FRAMEBUFFER (window));
}
context->current_path = NULL;
context->stencil_pipeline = cogl_pipeline_new (context);
context->in_begin_gl_block = FALSE;
context->quad_buffer_indices_byte = NULL;
context->quad_buffer_indices = NULL;
context->quad_buffer_indices_len = 0;
context->rectangle_byte_indices = NULL;
context->rectangle_short_indices = NULL;
context->rectangle_short_indices_len = 0;
context->texture_download_pipeline = NULL;
context->blit_texture_pipeline = NULL;
#ifdef HAVE_COGL_GL
if (_cogl_has_private_feature (context, COGL_PRIVATE_FEATURE_ALPHA_TEST))
/* The default for GL_ALPHA_TEST is to always pass which is equivalent to
* the test being disabled therefore we assume that for all drivers there
* will be no performance impact if we always leave the test enabled which
* makes things a bit simpler for us. Under GLES2 the alpha test is
* implemented in the fragment shader so there is no enable for it
*/
GE (context, glEnable (GL_ALPHA_TEST));
if ((context->driver == COGL_DRIVER_GL3))
{
GLuint vertex_array;
/* In a forward compatible context, GL 3 doesn't support rendering
* using the default vertex array object. Cogl doesn't use vertex
* array objects yet so for now we just create a dummy array
* object that we will use as our own default object. Eventually
* it could be good to attach the vertex array objects to
* CoglPrimitives */
context->glGenVertexArrays (1, &vertex_array);
context->glBindVertexArray (vertex_array);
}
#endif
context->current_modelview_entry = NULL;
context->current_projection_entry = NULL;
_cogl_matrix_entry_identity_init (&context->identity_entry);
_cogl_matrix_entry_cache_init (&context->builtin_flushed_projection);
_cogl_matrix_entry_cache_init (&context->builtin_flushed_modelview);
/* Create default textures used for fall backs */
context->default_gl_texture_2d_tex =
cogl_texture_2d_new_from_data (context,
1, 1,
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
0, /* rowstride */
white_pixel,
NULL); /* abort on error */
/* If 3D or rectangle textures aren't supported then these will
* return errors that we can simply ignore. */
internal_error = NULL;
context->default_gl_texture_3d_tex =
cogl_texture_3d_new_from_data (context,
1, 1, 1, /* width, height, depth */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
0, /* rowstride */
0, /* image stride */
white_pixel,
&internal_error);
if (internal_error)
cogl_error_free (internal_error);
/* TODO: add cogl_texture_rectangle_new_from_data() */
white_pixel_bitmap =
cogl_bitmap_new_for_data (context,
1, 1, /* width/height */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
4, /* rowstride */
white_pixel);
internal_error = NULL;
context->default_gl_texture_rect_tex =
cogl_texture_rectangle_new_from_bitmap (white_pixel_bitmap);
/* XXX: we need to allocate the texture now because the white_pixel
* data is on the stack */
cogl_texture_allocate (COGL_TEXTURE (context->default_gl_texture_rect_tex),
&internal_error);
if (internal_error)
cogl_error_free (internal_error);
cogl_object_unref (white_pixel_bitmap);
cogl_push_source (context->opaque_color_pipeline);
context->atlases = NULL;
g_hook_list_init (&context->atlas_reorganize_callbacks, sizeof (GHook));
context->buffer_map_fallback_array = g_byte_array_new ();
context->buffer_map_fallback_in_use = FALSE;
/* As far as I can tell, GL_POINT_SPRITE doesn't have any effect
unless GL_COORD_REPLACE is enabled for an individual layer.
Therefore it seems like it should be ok to just leave it enabled
all the time instead of having to have a set property on each
pipeline to track whether any layers have point sprite coords
enabled. We don't need to do this for GL3 or GLES2 because point
sprites are handled using a builtin varying in the shader. */
if (_cogl_has_private_feature (context, COGL_PRIVATE_FEATURE_GL_FIXED) &&
cogl_has_feature (context, COGL_FEATURE_ID_POINT_SPRITE))
GE (context, glEnable (GL_POINT_SPRITE));
_cogl_list_init (&context->fences);
return context;
}
/* For reference: There was some deliberation over whether to have a
* constructor that could throw an exception but looking at standard
* practices with several high level OO languages including python, C++,
* C# Java and Ruby they all support exceptions in constructors and the
* general consensus appears to be that throwing an exception is neater
* than successfully constructing with an internal error status that
* would then have to be explicitly checked via some form of ::is_ok()
* method.
*/
CoglContext *
cogl_context_new (CoglDisplay *display,
GError **error)
{
CoglContext *context;
GLubyte default_texture_data[] = { 0xff, 0xff, 0xff, 0x0 };
CoglBitmap *default_texture_bitmap;
const CoglWinsysVtable *winsys;
int i;
_cogl_init ();
#ifdef COGL_ENABLE_PROFILE
/* We need to be absolutely sure that uprof has been initialized
* before calling _cogl_uprof_init. uprof_init (NULL, NULL)
* will be a NOP if it has been initialized but it will also
* mean subsequent parsing of the UProf GOptionGroup will have no
* affect.
*
* Sadly GOptionGroup based library initialization is extremely
* fragile by design because GOptionGroups have no notion of
* dependencies and so the order things are initialized isn't
* currently under tight control.
*/
uprof_init (NULL, NULL);
_cogl_uprof_init ();
#endif
/* Allocate context memory */
context = g_malloc0 (sizeof (CoglContext));
/* Convert the context into an object immediately in case any of the
code below wants to verify that the context pointer is a valid
object */
_cogl_context_object_new (context);
/* XXX: Gross hack!
* Currently everything in Cogl just assumes there is a default
* context which it can access via _COGL_GET_CONTEXT() including
* code used to construct a CoglContext. Until all of that code
* has been updated to take an explicit context argument we have
* to immediately make our pointer the default context.
*/
_context = context;
/* Init default values */
memset (context->features, 0, sizeof (context->features));
context->feature_flags = 0;
context->private_feature_flags = 0;
context->texture_types = NULL;
context->buffer_types = NULL;
context->rectangle_state = COGL_WINSYS_RECTANGLE_STATE_UNKNOWN;
memset (context->winsys_features, 0, sizeof (context->winsys_features));
if (!display)
{
CoglRenderer *renderer = cogl_renderer_new ();
if (!cogl_renderer_connect (renderer, error))
{
g_free (context);
return NULL;
}
display = cogl_display_new (renderer, NULL);
}
else
cogl_object_ref (display);
if (!cogl_display_setup (display, error))
{
cogl_object_unref (display);
g_free (context);
return NULL;
}
context->display = display;
/* This is duplicated data, but it's much more convenient to have
the driver attached to the context and the value is accessed a
lot throughout Cogl */
context->driver = display->renderer->driver;
switch (context->driver)
{
#ifdef HAVE_COGL_GL
case COGL_DRIVER_GL:
context->driver_vtable = &_cogl_driver_gl;
context->texture_driver = &_cogl_texture_driver_gl;
break;
#endif
#if defined (HAVE_COGL_GLES) || defined (HAVE_COGL_GLES2)
case COGL_DRIVER_GLES1:
case COGL_DRIVER_GLES2:
context->driver_vtable = &_cogl_driver_gles;
context->texture_driver = &_cogl_texture_driver_gles;
break;
#endif
default:
g_assert_not_reached ();
}
winsys = _cogl_context_get_winsys (context);
if (!winsys->context_init (context, error))
{
cogl_object_unref (display);
g_free (context);
return NULL;
}
context->attribute_name_states_hash =
g_hash_table_new_full (g_str_hash, g_str_equal, g_free, g_free);
context->attribute_name_index_map = NULL;
context->n_attribute_names = 0;
/* The "cogl_color_in" attribute needs a deterministic name_index
* so we make sure it's the first attribute name we register */
_cogl_attribute_register_attribute_name (context, "cogl_color_in");
context->uniform_names =
g_ptr_array_new_with_free_func ((GDestroyNotify) g_free);
context->uniform_name_hash = g_hash_table_new (g_str_hash, g_str_equal);
context->n_uniform_names = 0;
/* Initialise the driver specific state */
_cogl_init_feature_overrides (context);
_context->sampler_cache = _cogl_sampler_cache_new (_context);
_cogl_pipeline_init_default_pipeline ();
_cogl_pipeline_init_default_layers ();
_cogl_pipeline_init_state_hash_functions ();
_cogl_pipeline_init_layer_state_hash_functions ();
context->current_clip_stack_valid = FALSE;
context->current_clip_stack = NULL;
cogl_matrix_init_identity (&context->identity_matrix);
cogl_matrix_init_identity (&context->y_flip_matrix);
cogl_matrix_scale (&context->y_flip_matrix, 1, -1, 1);
context->flushed_matrix_mode = COGL_MATRIX_MODELVIEW;
context->texture_units =
g_array_new (FALSE, FALSE, sizeof (CoglTextureUnit));
/* See cogl-pipeline.c for more details about why we leave texture unit 1
* active by default... */
context->active_texture_unit = 1;
GE (context, glActiveTexture (GL_TEXTURE1));
context->opaque_color_pipeline = cogl_pipeline_new (context);
context->blended_color_pipeline = cogl_pipeline_new (context);
context->texture_pipeline = cogl_pipeline_new (context);
context->codegen_header_buffer = g_string_new ("");
context->codegen_source_buffer = g_string_new ("");
context->default_gl_texture_2d_tex = NULL;
context->default_gl_texture_3d_tex = NULL;
context->default_gl_texture_rect_tex = NULL;
context->framebuffers = NULL;
context->current_draw_buffer = NULL;
context->current_read_buffer = NULL;
context->current_draw_buffer_state_flushed = 0;
context->current_draw_buffer_changes = COGL_FRAMEBUFFER_STATE_ALL;
g_queue_init (&context->gles2_context_stack);
context->journal_flush_attributes_array =
g_array_new (TRUE, FALSE, sizeof (CoglAttribute *));
context->journal_clip_bounds = NULL;
context->polygon_vertices = g_array_new (FALSE, FALSE, sizeof (float));
context->current_pipeline = NULL;
context->current_pipeline_changes_since_flush = 0;
context->current_pipeline_skip_gl_color = FALSE;
_cogl_bitmask_init (&context->enabled_builtin_attributes);
_cogl_bitmask_init (&context->enable_builtin_attributes_tmp);
_cogl_bitmask_init (&context->enabled_texcoord_attributes);
_cogl_bitmask_init (&context->enable_texcoord_attributes_tmp);
_cogl_bitmask_init (&context->enabled_custom_attributes);
_cogl_bitmask_init (&context->enable_custom_attributes_tmp);
_cogl_bitmask_init (&context->changed_bits_tmp);
context->max_texture_units = -1;
context->max_activateable_texture_units = -1;
context->current_fragment_program_type = COGL_PIPELINE_PROGRAM_TYPE_FIXED;
context->current_vertex_program_type = COGL_PIPELINE_PROGRAM_TYPE_FIXED;
context->current_gl_program = 0;
context->current_gl_dither_enabled = TRUE;
context->current_gl_color_mask = COGL_COLOR_MASK_ALL;
context->gl_blend_enable_cache = FALSE;
context->depth_test_enabled_cache = FALSE;
context->depth_test_function_cache = COGL_DEPTH_TEST_FUNCTION_LESS;
context->depth_writing_enabled_cache = TRUE;
context->depth_range_near_cache = 0;
context->depth_range_far_cache = 1;
context->pipeline_cache = cogl_pipeline_cache_new ();
for (i = 0; i < COGL_BUFFER_BIND_TARGET_COUNT; i++)
context->current_buffer[i] = NULL;
context->window_buffer = NULL;
context->framebuffer_stack = _cogl_create_framebuffer_stack ();
/* XXX: In this case the Clutter backend is still responsible for
* the OpenGL binding API and for creating onscreen framebuffers and
* so we have to add a dummy framebuffer to represent the backend
* owned window... */
if (_cogl_context_get_winsys (context) == _cogl_winsys_stub_get_vtable ())
{
CoglOnscreen *window = _cogl_onscreen_new ();
cogl_set_framebuffer (COGL_FRAMEBUFFER (window));
cogl_object_unref (COGL_FRAMEBUFFER (window));
}
context->stencil_pipeline = cogl_pipeline_new (context);
context->in_begin_gl_block = FALSE;
context->quad_buffer_indices_byte = NULL;
context->quad_buffer_indices = NULL;
context->quad_buffer_indices_len = 0;
context->rectangle_byte_indices = NULL;
context->rectangle_short_indices = NULL;
context->rectangle_short_indices_len = 0;
context->texture_download_pipeline = NULL;
context->blit_texture_pipeline = NULL;
#if defined (HAVE_COGL_GL) || defined (HAVE_COGL_GLES)
if (context->driver != COGL_DRIVER_GLES2)
/* The default for GL_ALPHA_TEST is to always pass which is equivalent to
* the test being disabled therefore we assume that for all drivers there
* will be no performance impact if we always leave the test enabled which
* makes things a bit simpler for us. Under GLES2 the alpha test is
* implemented in the fragment shader so there is no enable for it
*/
GE (context, glEnable (GL_ALPHA_TEST));
#endif
_context->current_modelview_entry = NULL;
_context->current_projection_entry = NULL;
_cogl_matrix_entry_identity_init (&_context->identity_entry);
_cogl_matrix_entry_cache_init (&_context->builtin_flushed_projection);
_cogl_matrix_entry_cache_init (&_context->builtin_flushed_modelview);
default_texture_bitmap =
cogl_bitmap_new_for_data (_context,
1, 1, /* width/height */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
4, /* rowstride */
default_texture_data);
/* Create default textures used for fall backs */
context->default_gl_texture_2d_tex =
cogl_texture_2d_new_from_bitmap (default_texture_bitmap,
/* internal format */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
NULL);
/* If 3D or rectangle textures aren't supported then these should
just silently return NULL */
context->default_gl_texture_3d_tex =
cogl_texture_3d_new_from_bitmap (default_texture_bitmap,
1, /* height */
1, /* depth */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
NULL);
context->default_gl_texture_rect_tex =
cogl_texture_rectangle_new_from_bitmap (default_texture_bitmap,
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
NULL);
cogl_object_unref (default_texture_bitmap);
context->atlases = NULL;
g_hook_list_init (&context->atlas_reorganize_callbacks, sizeof (GHook));
_context->buffer_map_fallback_array = g_byte_array_new ();
_context->buffer_map_fallback_in_use = FALSE;
/* As far as I can tell, GL_POINT_SPRITE doesn't have any effect
unless GL_COORD_REPLACE is enabled for an individual
layer. Therefore it seems like it should be ok to just leave it
enabled all the time instead of having to have a set property on
each pipeline to track whether any layers have point sprite
coords enabled. We don't need to do this for GLES2 because point
sprites are handled using a builtin varying in the shader. */
if (_context->driver != COGL_DRIVER_GLES2 &&
cogl_has_feature (context, COGL_FEATURE_ID_POINT_SPRITE))
GE (context, glEnable (GL_POINT_SPRITE));
return context;
}
/* In addition to writing the stack matrix into the give @matrix
* argument this function *may* sometimes also return a pointer
* to a matrix too so if we are querying the inverse matrix we
* should query from the return matrix so that the result can
* be cached within the stack. */
CoglMatrix *
cogl_matrix_entry_get (CoglMatrixEntry *entry,
CoglMatrix *matrix)
{
int depth;
CoglMatrixEntry *current;
CoglMatrixEntry **children;
int i;
for (depth = 0, current = entry;
current;
current = current->parent, depth++)
{
switch (current->op)
{
case COGL_MATRIX_OP_LOAD_IDENTITY:
cogl_matrix_init_identity (matrix);
goto initialized;
case COGL_MATRIX_OP_LOAD:
{
CoglMatrixEntryLoad *load = (CoglMatrixEntryLoad *)current;
*matrix = *load->matrix;
goto initialized;
}
case COGL_MATRIX_OP_SAVE:
{
CoglMatrixEntrySave *save = (CoglMatrixEntrySave *)current;
if (!save->cache_valid)
{
CoglMagazine *matrices_magazine =
cogl_matrix_stack_matrices_magazine;
save->cache = _cogl_magazine_chunk_alloc (matrices_magazine);
cogl_matrix_entry_get (current->parent, save->cache);
save->cache_valid = TRUE;
}
*matrix = *save->cache;
goto initialized;
}
default:
continue;
}
}
initialized:
if (depth == 0)
{
switch (entry->op)
{
case COGL_MATRIX_OP_LOAD_IDENTITY:
case COGL_MATRIX_OP_TRANSLATE:
case COGL_MATRIX_OP_ROTATE:
case COGL_MATRIX_OP_ROTATE_QUATERNION:
case COGL_MATRIX_OP_ROTATE_EULER:
case COGL_MATRIX_OP_SCALE:
case COGL_MATRIX_OP_MULTIPLY:
return NULL;
case COGL_MATRIX_OP_LOAD:
{
CoglMatrixEntryLoad *load = (CoglMatrixEntryLoad *)entry;
return load->matrix;
}
case COGL_MATRIX_OP_SAVE:
{
CoglMatrixEntrySave *save = (CoglMatrixEntrySave *)entry;
return save->cache;
}
}
g_warn_if_reached ();
return NULL;
}
#ifdef COGL_ENABLE_DEBUG
if (!current)
{
g_warning ("Inconsistent matrix stack");
return NULL;
}
entry->composite_gets++;
#endif
children = g_alloca (sizeof (CoglMatrixEntry) * depth);
/* We need walk the list of entries from the init/load/save entry
* back towards the leaf node but the nodes don't link to their
* children so we need to re-walk them here to add to a separate
* array. */
for (i = depth - 1, current = entry;
i >= 0 && current;
i--, current = current->parent)
{
children[i] = current;
}
#ifdef COGL_ENABLE_DEBUG
if (COGL_DEBUG_ENABLED (COGL_DEBUG_PERFORMANCE) &&
entry->composite_gets >= 2)
{
COGL_NOTE (PERFORMANCE,
"Re-composing a matrix stack entry multiple times");
}
#endif
for (i = 0; i < depth; i++)
{
switch (children[i]->op)
{
case COGL_MATRIX_OP_TRANSLATE:
{
CoglMatrixEntryTranslate *translate =
(CoglMatrixEntryTranslate *)children[i];
cogl_matrix_translate (matrix,
translate->x,
translate->y,
translate->z);
continue;
}
case COGL_MATRIX_OP_ROTATE:
{
CoglMatrixEntryRotate *rotate=
(CoglMatrixEntryRotate *)children[i];
cogl_matrix_rotate (matrix,
rotate->angle,
rotate->x,
rotate->y,
rotate->z);
continue;
}
case COGL_MATRIX_OP_ROTATE_EULER:
{
CoglMatrixEntryRotateEuler *rotate =
(CoglMatrixEntryRotateEuler *)children[i];
CoglEuler euler;
cogl_euler_init (&euler,
rotate->heading,
rotate->pitch,
rotate->roll);
cogl_matrix_rotate_euler (matrix,
&euler);
continue;
}
case COGL_MATRIX_OP_ROTATE_QUATERNION:
{
CoglMatrixEntryRotateQuaternion *rotate =
(CoglMatrixEntryRotateQuaternion *)children[i];
CoglQuaternion quaternion;
cogl_quaternion_init_from_array (&quaternion, rotate->values);
cogl_matrix_rotate_quaternion (matrix, &quaternion);
continue;
}
case COGL_MATRIX_OP_SCALE:
{
CoglMatrixEntryScale *scale =
(CoglMatrixEntryScale *)children[i];
cogl_matrix_scale (matrix,
scale->x,
scale->y,
scale->z);
continue;
}
case COGL_MATRIX_OP_MULTIPLY:
{
CoglMatrixEntryMultiply *multiply =
(CoglMatrixEntryMultiply *)children[i];
cogl_matrix_multiply (matrix, matrix, multiply->matrix);
continue;
}
case COGL_MATRIX_OP_LOAD_IDENTITY:
case COGL_MATRIX_OP_LOAD:
case COGL_MATRIX_OP_SAVE:
g_warn_if_reached ();
continue;
}
}
return NULL;
}
static RutDiamondSlice *
diamond_slice_new (RutContext *ctx,
float size,
int tex_width,
int tex_height)
{
RutDiamondSlice *diamond_slice = g_slice_new (RutDiamondSlice);
float width = size;
float height = size;
#define DIAMOND_SLICE_CORNER_RADIUS 20
CoglMatrix matrix;
float tex_aspect;
rut_object_init (&diamond_slice->_parent, &rut_diamond_slice_type);
diamond_slice->ref_count = 1;
diamond_slice->size = size;
{
/* x0,y0,x1,y1 and s0,t0,s1,t1 define the postion and texture
* coordinates for the center rectangle... */
float x0 = DIAMOND_SLICE_CORNER_RADIUS;
float y0 = DIAMOND_SLICE_CORNER_RADIUS;
float x1 = width - DIAMOND_SLICE_CORNER_RADIUS;
float y1 = height - DIAMOND_SLICE_CORNER_RADIUS;
/* The center region of the nine-slice can simply map to the
* degenerate center of the circle */
float s0 = 0.5;
float t0 = 0.5;
float s1 = 0.5;
float t1 = 0.5;
int n_vertices;
int i;
/*
* 0,0 x0,0 x1,0 width,0
* 0,0 s0,0 s1,0 1,0
* 0 1 2 3
*
* 0,y0 x0,y0 x1,y0 width,y0
* 0,t0 s0,t0 s1,t0 1,t0
* 4 5 6 7
*
* 0,y1 x0,y1 x1,y1 width,y1
* 0,t1 s0,t1 s1,t1 1,t1
* 8 9 10 11
*
* 0,height x0,height x1,height width,height
* 0,1 s0,1 s1,1 1,1
* 12 13 14 15
*/
VertexP2T2T2 vertices[] =
{
{ 0, 0, 0, 0, 0, 0 },
{ x0, 0, s0, 0, x0, 0},
{ x1, 0, s1, 0, x1, 0},
{ width, 0, 1, 0, width, 0},
{ 0, y0, 0, t0, 0, y0},
{ x0, y0, s0, t0, x0, y0},
{ x1, y0, s1, t0, x1, y0},
{ width, y0, 1, t0, width, y0},
{ 0, y1, 0, t1, 0, y1},
{ x0, y1, s0, t1, x0, y1},
{ x1, y1, s1, t1, x1, y1},
{ width, y1, 1, t1, width, y1},
{ 0, height, 0, 1, 0, height},
{ x0, height, s0, 1, x0, height},
{ x1, height, s1, 1, x1, height},
{ width, height, 1, 1, width, height},
};
cogl_matrix_init_identity (&diamond_slice->rotate_matrix);
cogl_matrix_rotate (&diamond_slice->rotate_matrix, 45, 0, 0, 1);
cogl_matrix_translate (&diamond_slice->rotate_matrix, - width / 2.0, - height / 2.0, 0);
n_vertices = sizeof (vertices) / sizeof (VertexP2T2T2);
for (i = 0; i < n_vertices; i++)
{
float z = 0, w = 1;
cogl_matrix_transform_point (&diamond_slice->rotate_matrix,
&vertices[i].x,
&vertices[i].y,
&z,
&w);
#ifdef MESA_CONST_ATTRIB_BUG_WORKAROUND
vertices[i].Nx = 0;
vertices[i].Ny = 0;
vertices[i].Nz = 1;
vertices[i].Tx = 1;
vertices[i].Ty = 0;
vertices[i].Tz = 0;
#endif
}
cogl_matrix_init_identity (&matrix);
{
float s_scale = 1.0, t_scale = 1.0;
float s0, t0;
float diagonal_size_scale = 1.0 / (sinf (G_PI_4) * 2.0);
tex_aspect = (float)tex_width / (float)tex_height;
if (tex_aspect < 1) /* taller than it is wide */
t_scale *= tex_aspect;
else /* wider than it is tall */
{
float inverse_aspect = 1.0f / tex_aspect;
s_scale *= inverse_aspect;
}
s_scale *= diagonal_size_scale;
t_scale *= diagonal_size_scale;
s0 = 0.5 - (s_scale / 2.0);
t0 = 0.5 - (t_scale / 2.0);
cogl_matrix_translate (&matrix, s0, t0, 0);
cogl_matrix_scale (&matrix, s_scale / width, t_scale / height, 1);
cogl_matrix_translate (&matrix, width / 2.0, height / 2.0, 1);
cogl_matrix_rotate (&matrix, 45, 0, 0, 1);
cogl_matrix_translate (&matrix, -width / 2.0, -height / 2.0, 1);
}
n_vertices = sizeof (vertices) / sizeof (VertexP2T2T2);
for (i = 0; i < n_vertices; i++)
{
float z = 0, w = 1;
cogl_matrix_transform_point (&matrix,
&vertices[i].s1,
&vertices[i].t1,
&z,
&w);
}
diamond_slice->primitive =
primitive_new_p2t2t2 (ctx->cogl_context,
COGL_VERTICES_MODE_TRIANGLES,
n_vertices,
vertices);
/* The vertices uploaded only map to the key intersection points of the
* 9-slice grid which isn't a topology that GPUs can handle directly so
* this specifies an array of indices that allow the GPU to interpret the
* vertices as a list of triangles... */
cogl_primitive_set_indices (diamond_slice->primitive,
ctx->nine_slice_indices,
sizeof (_rut_nine_slice_indices_data) /
sizeof (_rut_nine_slice_indices_data[0]));
}
return diamond_slice;
}
static gboolean
clutter_matrix_progress (const GValue *a,
const GValue *b,
gdouble progress,
GValue *retval)
{
const ClutterMatrix *matrix1 = g_value_get_boxed (a);
const ClutterMatrix *matrix2 = g_value_get_boxed (b);
ClutterVertex scale1 = CLUTTER_VERTEX_INIT (1.f, 1.f, 1.f);
float shear1[3] = { 0.f, 0.f, 0.f };
ClutterVertex rotate1 = CLUTTER_VERTEX_INIT_ZERO;
ClutterVertex translate1 = CLUTTER_VERTEX_INIT_ZERO;
ClutterVertex4 perspective1 = { 0.f, 0.f, 0.f, 0.f };
ClutterVertex scale2 = CLUTTER_VERTEX_INIT (1.f, 1.f, 1.f);
float shear2[3] = { 0.f, 0.f, 0.f };
ClutterVertex rotate2 = CLUTTER_VERTEX_INIT_ZERO;
ClutterVertex translate2 = CLUTTER_VERTEX_INIT_ZERO;
ClutterVertex4 perspective2 = { 0.f, 0.f, 0.f, 0.f };
ClutterVertex scale_res = CLUTTER_VERTEX_INIT (1.f, 1.f, 1.f);
float shear_res = 0.f;
ClutterVertex rotate_res = CLUTTER_VERTEX_INIT_ZERO;
ClutterVertex translate_res = CLUTTER_VERTEX_INIT_ZERO;
ClutterVertex4 perspective_res = { 0.f, 0.f, 0.f, 0.f };
ClutterMatrix res;
clutter_matrix_init_identity (&res);
_clutter_util_matrix_decompose (matrix1,
&scale1, shear1, &rotate1, &translate1,
&perspective1);
_clutter_util_matrix_decompose (matrix2,
&scale2, shear2, &rotate2, &translate2,
&perspective2);
/* perspective */
_clutter_util_vertex4_interpolate (&perspective1, &perspective2, progress, &perspective_res);
res.wx = perspective_res.x;
res.wy = perspective_res.y;
res.wz = perspective_res.z;
res.ww = perspective_res.w;
/* translation */
clutter_vertex_interpolate (&translate1, &translate2, progress, &translate_res);
cogl_matrix_translate (&res, translate_res.x, translate_res.y, translate_res.z);
/* rotation */
clutter_vertex_interpolate (&rotate1, &rotate2, progress, &rotate_res);
cogl_matrix_rotate (&res, rotate_res.x, 1.0f, 0.0f, 0.0f);
cogl_matrix_rotate (&res, rotate_res.y, 0.0f, 1.0f, 0.0f);
cogl_matrix_rotate (&res, rotate_res.z, 0.0f, 0.0f, 1.0f);
/* skew */
shear_res = shear1[2] + (shear2[2] - shear1[2]) * progress; /* YZ */
if (shear_res != 0.f)
_clutter_util_matrix_skew_yz (&res, shear_res);
shear_res = shear1[1] + (shear2[1] - shear1[1]) * progress; /* XZ */
if (shear_res != 0.f)
_clutter_util_matrix_skew_xz (&res, shear_res);
shear_res = shear1[0] + (shear2[0] - shear1[0]) * progress; /* XY */
if (shear_res != 0.f)
_clutter_util_matrix_skew_xy (&res, shear_res);
/* scale */
clutter_vertex_interpolate (&scale1, &scale2, progress, &scale_res);
cogl_matrix_scale (&res, scale_res.x, scale_res.y, scale_res.z);
g_value_set_boxed (retval, &res);
return TRUE;
}
static gboolean
cogl_create_context (void)
{
GLubyte default_texture_data[] = { 0xff, 0xff, 0xff, 0x0 };
unsigned long enable_flags = 0;
CoglHandle window_buffer;
if (_context != NULL)
return FALSE;
/* Allocate context memory */
_context = (CoglContext*) g_malloc (sizeof (CoglContext));
/* Init default values */
_context->feature_flags = 0;
_context->features_cached = FALSE;
/* Initialise the driver specific state */
/* TODO: combine these two into one function */
_cogl_create_context_driver (_context);
_cogl_features_init ();
_cogl_material_init_default_material ();
_context->enable_flags = 0;
_context->color_alpha = 0;
_context->enable_backface_culling = FALSE;
_context->flushed_front_winding = COGL_FRONT_WINDING_COUNTER_CLOCKWISE;
_context->indirect = gl_is_indirect;
cogl_matrix_init_identity (&_context->identity_matrix);
cogl_matrix_init_identity (&_context->y_flip_matrix);
cogl_matrix_scale (&_context->y_flip_matrix, 1, -1, 1);
_context->flushed_matrix_mode = COGL_MATRIX_MODELVIEW;
_context->texture_units = NULL;
_context->simple_material = cogl_material_new ();
_context->source_material = NULL;
_context->default_gl_texture_2d_tex = COGL_INVALID_HANDLE;
_context->default_gl_texture_rect_tex = COGL_INVALID_HANDLE;
_context->journal = g_array_new (FALSE, FALSE, sizeof (CoglJournalEntry));
_context->logged_vertices = g_array_new (FALSE, FALSE, sizeof (GLfloat));
_context->current_material = NULL;
_context->current_material_flags = 0;
memset (&_context->current_material_flush_options,
0, sizeof (CoglMaterialFlushOptions));
_context->current_layers = g_array_new (FALSE, FALSE,
sizeof (CoglLayerInfo));
_context->n_texcoord_arrays_enabled = 0;
_context->framebuffer_stack = _cogl_create_framebuffer_stack ();
window_buffer = _cogl_onscreen_new ();
cogl_set_framebuffer (window_buffer);
/* XXX: the deprecated _cogl_set_draw_buffer API expects to
* find the window buffer here... */
_context->window_buffer = window_buffer;
_context->dirty_bound_framebuffer = TRUE;
_context->dirty_gl_viewport = TRUE;
_context->path_nodes = g_array_new (FALSE, FALSE, sizeof (CoglPathNode));
_context->last_path = 0;
_context->stencil_material = cogl_material_new ();
_context->in_begin_gl_block = FALSE;
_context->quad_indices_byte = COGL_INVALID_HANDLE;
_context->quad_indices_short = COGL_INVALID_HANDLE;
_context->quad_indices_short_len = 0;
_context->texture_download_material = COGL_INVALID_HANDLE;
/* Create default textures used for fall backs */
_context->default_gl_texture_2d_tex =
cogl_texture_new_from_data (1, /* width */
1, /* height */
COGL_TEXTURE_NO_SLICING,
COGL_PIXEL_FORMAT_RGBA_8888_PRE, /* data format */
/* internal format */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
0, /* auto calc row stride */
default_texture_data);
_context->default_gl_texture_rect_tex =
cogl_texture_new_from_data (1, /* width */
1, /* height */
COGL_TEXTURE_NO_SLICING,
COGL_PIXEL_FORMAT_RGBA_8888_PRE, /* data format */
/* internal format */
COGL_PIXEL_FORMAT_RGBA_8888_PRE,
0, /* auto calc row stride */
default_texture_data);
cogl_set_source (_context->simple_material);
_cogl_material_flush_gl_state (_context->source_material, NULL);
enable_flags =
_cogl_material_get_cogl_enable_flags (_context->source_material);
cogl_enable (enable_flags);
_cogl_flush_face_winding ();
_context->atlas = NULL;
_context->atlas_texture = COGL_INVALID_HANDLE;
_context->current_pbo = NULL;
_context->max_texture_units = -1;
return TRUE;
}