mutter/cogl/cogl-pipeline-state.c

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/*
* Cogl
*
* An object oriented GL/GLES Abstraction/Utility Layer
*
* Copyright (C) 2008,2009,2010 Intel Corporation.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library. If not, see
* <http://www.gnu.org/licenses/>.
*
*
*
* Authors:
* Robert Bragg <robert@linux.intel.com>
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include "cogl-context-private.h"
#include "cogl-color-private.h"
#include "cogl-blend-string.h"
#include "cogl-util.h"
#include "cogl-depth-state-private.h"
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
#include "cogl-pipeline-state-private.h"
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
#include "cogl-snippet-private.h"
#include "string.h"
#ifndef GL_FUNC_ADD
#define GL_FUNC_ADD 0x8006
#endif
CoglPipeline *
_cogl_pipeline_get_user_program (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), NULL);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_USER_SHADER);
return authority->big_state->user_program;
}
gboolean
_cogl_pipeline_color_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
return cogl_color_equal (&authority0->color, &authority1->color);
}
gboolean
_cogl_pipeline_lighting_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineLightingState *state0 = &authority0->big_state->lighting_state;
CoglPipelineLightingState *state1 = &authority1->big_state->lighting_state;
if (memcmp (state0->ambient, state1->ambient, sizeof (float) * 4) != 0)
return FALSE;
if (memcmp (state0->diffuse, state1->diffuse, sizeof (float) * 4) != 0)
return FALSE;
if (memcmp (state0->specular, state1->specular, sizeof (float) * 4) != 0)
return FALSE;
if (memcmp (state0->emission, state1->emission, sizeof (float) * 4) != 0)
return FALSE;
if (state0->shininess != state1->shininess)
return FALSE;
return TRUE;
}
gboolean
_cogl_pipeline_alpha_func_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineAlphaFuncState *alpha_state0 =
&authority0->big_state->alpha_state;
CoglPipelineAlphaFuncState *alpha_state1 =
&authority1->big_state->alpha_state;
return alpha_state0->alpha_func == alpha_state1->alpha_func;
}
gboolean
_cogl_pipeline_alpha_func_reference_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineAlphaFuncState *alpha_state0 =
&authority0->big_state->alpha_state;
CoglPipelineAlphaFuncState *alpha_state1 =
&authority1->big_state->alpha_state;
return (alpha_state0->alpha_func_reference ==
alpha_state1->alpha_func_reference);
}
gboolean
_cogl_pipeline_blend_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineBlendState *blend_state0 = &authority0->big_state->blend_state;
CoglPipelineBlendState *blend_state1 = &authority1->big_state->blend_state;
_COGL_GET_CONTEXT (ctx, FALSE);
#if defined(HAVE_COGL_GLES2) || defined(HAVE_COGL_GL)
if (ctx->driver != COGL_DRIVER_GLES1)
{
if (blend_state0->blend_equation_rgb != blend_state1->blend_equation_rgb)
return FALSE;
if (blend_state0->blend_equation_alpha !=
blend_state1->blend_equation_alpha)
return FALSE;
if (blend_state0->blend_src_factor_alpha !=
blend_state1->blend_src_factor_alpha)
return FALSE;
if (blend_state0->blend_dst_factor_alpha !=
blend_state1->blend_dst_factor_alpha)
return FALSE;
}
#endif
if (blend_state0->blend_src_factor_rgb !=
blend_state1->blend_src_factor_rgb)
return FALSE;
if (blend_state0->blend_dst_factor_rgb !=
blend_state1->blend_dst_factor_rgb)
return FALSE;
#if defined(HAVE_COGL_GLES2) || defined(HAVE_COGL_GL)
if (ctx->driver != COGL_DRIVER_GLES1 &&
(blend_state0->blend_src_factor_rgb == GL_ONE_MINUS_CONSTANT_COLOR ||
blend_state0->blend_src_factor_rgb == GL_CONSTANT_COLOR ||
blend_state0->blend_dst_factor_rgb == GL_ONE_MINUS_CONSTANT_COLOR ||
blend_state0->blend_dst_factor_rgb == GL_CONSTANT_COLOR))
{
if (!cogl_color_equal (&blend_state0->blend_constant,
&blend_state1->blend_constant))
return FALSE;
}
#endif
return TRUE;
}
gboolean
_cogl_pipeline_depth_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
if (authority0->big_state->depth_state.test_enabled == FALSE &&
authority1->big_state->depth_state.test_enabled == FALSE)
return TRUE;
else
{
CoglDepthState *s0 = &authority0->big_state->depth_state;
CoglDepthState *s1 = &authority1->big_state->depth_state;
return s0->test_enabled == s1->test_enabled &&
s0->test_function == s1->test_function &&
s0->write_enabled == s1->write_enabled &&
s0->range_near == s1->range_near &&
s0->range_far == s1->range_far;
}
}
gboolean
_cogl_pipeline_fog_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineFogState *fog_state0 = &authority0->big_state->fog_state;
CoglPipelineFogState *fog_state1 = &authority1->big_state->fog_state;
if (fog_state0->enabled == fog_state1->enabled &&
cogl_color_equal (&fog_state0->color, &fog_state1->color) &&
fog_state0->mode == fog_state1->mode &&
fog_state0->density == fog_state1->density &&
fog_state0->z_near == fog_state1->z_near &&
fog_state0->z_far == fog_state1->z_far)
return TRUE;
else
return FALSE;
}
gboolean
_cogl_pipeline_point_size_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
return authority0->big_state->point_size == authority1->big_state->point_size;
}
gboolean
_cogl_pipeline_logic_ops_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineLogicOpsState *logic_ops_state0 = &authority0->big_state->logic_ops_state;
CoglPipelineLogicOpsState *logic_ops_state1 = &authority1->big_state->logic_ops_state;
return logic_ops_state0->color_mask == logic_ops_state1->color_mask;
}
gboolean
_cogl_pipeline_cull_face_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
CoglPipelineCullFaceState *cull_face_state0
= &authority0->big_state->cull_face_state;
CoglPipelineCullFaceState *cull_face_state1
= &authority1->big_state->cull_face_state;
/* The cull face state is considered equal if two pipelines are both
set to no culling. If the front winding property is ever used for
anything else or the comparison is used not just for drawing then
this would have to change */
if (cull_face_state0->mode == COGL_PIPELINE_CULL_FACE_MODE_NONE)
return cull_face_state1->mode == COGL_PIPELINE_CULL_FACE_MODE_NONE;
return (cull_face_state0->mode == cull_face_state1->mode &&
cull_face_state0->front_winding == cull_face_state1->front_winding);
}
gboolean
_cogl_pipeline_user_shader_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
return (authority0->big_state->user_program ==
authority1->big_state->user_program);
}
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
typedef struct
{
const CoglBoxedValue **dst_values;
const CoglBoxedValue *src_values;
int override_count;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
} GetUniformsClosure;
static gboolean
get_uniforms_cb (int uniform_num, void *user_data)
{
GetUniformsClosure *data = user_data;
if (data->dst_values[uniform_num] == NULL)
data->dst_values[uniform_num] = data->src_values + data->override_count;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
data->override_count++;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
return TRUE;
}
static void
_cogl_pipeline_get_all_uniform_values (CoglPipeline *pipeline,
const CoglBoxedValue **values)
{
GetUniformsClosure data;
_COGL_GET_CONTEXT (ctx, NO_RETVAL);
memset (values, 0,
sizeof (const CoglBoxedValue *) * ctx->n_uniform_names);
data.dst_values = values;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
do
{
const CoglPipelineUniformsState *uniforms_state =
&pipeline->big_state->uniforms_state;
data.override_count = 0;
data.src_values = uniforms_state->override_values;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
if ((pipeline->differences & COGL_PIPELINE_STATE_UNIFORMS))
_cogl_bitmask_foreach (&uniforms_state->override_mask,
get_uniforms_cb,
&data);
pipeline = _cogl_pipeline_get_parent (pipeline);
}
while (pipeline);
}
gboolean
_cogl_pipeline_uniforms_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
unsigned long *differences;
const CoglBoxedValue **values0, **values1;
int n_longs;
int i;
_COGL_GET_CONTEXT (ctx, FALSE);
if (authority0 == authority1)
return TRUE;
values0 = g_alloca (sizeof (const CoglBoxedValue *) * ctx->n_uniform_names);
values1 = g_alloca (sizeof (const CoglBoxedValue *) * ctx->n_uniform_names);
n_longs = COGL_FLAGS_N_LONGS_FOR_SIZE (ctx->n_uniform_names);
differences = g_alloca (n_longs * sizeof (unsigned long));
memset (differences, 0, sizeof (unsigned long) * n_longs);
_cogl_pipeline_compare_uniform_differences (differences,
authority0,
authority1);
_cogl_pipeline_get_all_uniform_values (authority0, values0);
_cogl_pipeline_get_all_uniform_values (authority1, values1);
COGL_FLAGS_FOREACH_START (differences, n_longs, i)
{
const CoglBoxedValue *value0 = values0[i];
const CoglBoxedValue *value1 = values1[i];
if (value0 == NULL)
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
{
if (value1 != NULL && value1->type != COGL_BOXED_NONE)
return FALSE;
}
else if (value1 == NULL)
{
if (value0 != NULL && value0->type != COGL_BOXED_NONE)
return FALSE;
}
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
else if (!_cogl_boxed_value_equal (value0, value1))
return FALSE;
}
COGL_FLAGS_FOREACH_END;
return TRUE;
}
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
gboolean
_cogl_pipeline_vertex_snippets_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
return _cogl_pipeline_snippet_list_equal (&authority0->big_state->
vertex_snippets,
&authority1->big_state->
vertex_snippets);
}
gboolean
_cogl_pipeline_fragment_snippets_state_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
return _cogl_pipeline_snippet_list_equal (&authority0->big_state->
fragment_snippets,
&authority1->big_state->
fragment_snippets);
}
void
cogl_pipeline_get_color (CoglPipeline *pipeline,
CoglColor *color)
{
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_COLOR);
*color = authority->color;
}
/* This is used heavily by the cogl journal when logging quads */
void
_cogl_pipeline_get_colorubv (CoglPipeline *pipeline,
guint8 *color)
{
CoglPipeline *authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_COLOR);
_cogl_color_get_rgba_4ubv (&authority->color, color);
}
void
cogl_pipeline_set_color (CoglPipeline *pipeline,
const CoglColor *color)
{
CoglPipelineState state = COGL_PIPELINE_STATE_COLOR;
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
if (cogl_color_equal (color, &authority->color))
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, color, FALSE);
pipeline->color = *color;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_color_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
void
cogl_pipeline_set_color4ub (CoglPipeline *pipeline,
guint8 red,
guint8 green,
guint8 blue,
guint8 alpha)
{
CoglColor color;
cogl_color_init_from_4ub (&color, red, green, blue, alpha);
cogl_pipeline_set_color (pipeline, &color);
}
void
cogl_pipeline_set_color4f (CoglPipeline *pipeline,
float red,
float green,
float blue,
float alpha)
{
CoglColor color;
cogl_color_init_from_4f (&color, red, green, blue, alpha);
cogl_pipeline_set_color (pipeline, &color);
}
CoglPipelineBlendEnable
_cogl_pipeline_get_blend_enabled (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), FALSE);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_BLEND_ENABLE);
return authority->blend_enable;
}
gboolean
_cogl_pipeline_blend_enable_equal (CoglPipeline *authority0,
CoglPipeline *authority1)
{
return authority0->blend_enable == authority1->blend_enable ? TRUE : FALSE;
}
void
_cogl_pipeline_set_blend_enabled (CoglPipeline *pipeline,
CoglPipelineBlendEnable enable)
{
CoglPipelineState state = COGL_PIPELINE_STATE_BLEND_ENABLE;
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
_COGL_RETURN_IF_FAIL (enable > 1 &&
"don't pass TRUE or FALSE to _set_blend_enabled!");
authority = _cogl_pipeline_get_authority (pipeline, state);
if (authority->blend_enable == enable)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
pipeline->blend_enable = enable;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_blend_enable_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
void
cogl_pipeline_get_ambient (CoglPipeline *pipeline,
CoglColor *ambient)
{
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_LIGHTING);
cogl_color_init_from_4fv (ambient,
authority->big_state->lighting_state.ambient);
}
void
cogl_pipeline_set_ambient (CoglPipeline *pipeline,
const CoglColor *ambient)
{
CoglPipelineState state = COGL_PIPELINE_STATE_LIGHTING;
CoglPipeline *authority;
CoglPipelineLightingState *lighting_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
lighting_state = &authority->big_state->lighting_state;
if (cogl_color_equal (ambient, &lighting_state->ambient))
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
lighting_state = &pipeline->big_state->lighting_state;
lighting_state->ambient[0] = cogl_color_get_red_float (ambient);
lighting_state->ambient[1] = cogl_color_get_green_float (ambient);
lighting_state->ambient[2] = cogl_color_get_blue_float (ambient);
lighting_state->ambient[3] = cogl_color_get_alpha_float (ambient);
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_lighting_state_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
void
cogl_pipeline_get_diffuse (CoglPipeline *pipeline,
CoglColor *diffuse)
{
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_LIGHTING);
cogl_color_init_from_4fv (diffuse,
authority->big_state->lighting_state.diffuse);
}
void
cogl_pipeline_set_diffuse (CoglPipeline *pipeline,
const CoglColor *diffuse)
{
CoglPipelineState state = COGL_PIPELINE_STATE_LIGHTING;
CoglPipeline *authority;
CoglPipelineLightingState *lighting_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
lighting_state = &authority->big_state->lighting_state;
if (cogl_color_equal (diffuse, &lighting_state->diffuse))
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
lighting_state = &pipeline->big_state->lighting_state;
lighting_state->diffuse[0] = cogl_color_get_red_float (diffuse);
lighting_state->diffuse[1] = cogl_color_get_green_float (diffuse);
lighting_state->diffuse[2] = cogl_color_get_blue_float (diffuse);
lighting_state->diffuse[3] = cogl_color_get_alpha_float (diffuse);
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_lighting_state_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
void
cogl_pipeline_set_ambient_and_diffuse (CoglPipeline *pipeline,
const CoglColor *color)
{
cogl_pipeline_set_ambient (pipeline, color);
cogl_pipeline_set_diffuse (pipeline, color);
}
void
cogl_pipeline_get_specular (CoglPipeline *pipeline,
CoglColor *specular)
{
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_LIGHTING);
cogl_color_init_from_4fv (specular,
authority->big_state->lighting_state.specular);
}
void
cogl_pipeline_set_specular (CoglPipeline *pipeline, const CoglColor *specular)
{
CoglPipeline *authority;
CoglPipelineState state = COGL_PIPELINE_STATE_LIGHTING;
CoglPipelineLightingState *lighting_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
lighting_state = &authority->big_state->lighting_state;
if (cogl_color_equal (specular, &lighting_state->specular))
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
lighting_state = &pipeline->big_state->lighting_state;
lighting_state->specular[0] = cogl_color_get_red_float (specular);
lighting_state->specular[1] = cogl_color_get_green_float (specular);
lighting_state->specular[2] = cogl_color_get_blue_float (specular);
lighting_state->specular[3] = cogl_color_get_alpha_float (specular);
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_lighting_state_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
float
cogl_pipeline_get_shininess (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), 0);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_LIGHTING);
return authority->big_state->lighting_state.shininess;
}
void
cogl_pipeline_set_shininess (CoglPipeline *pipeline,
float shininess)
{
CoglPipeline *authority;
CoglPipelineState state = COGL_PIPELINE_STATE_LIGHTING;
CoglPipelineLightingState *lighting_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
if (shininess < 0.0)
{
g_warning ("Out of range shininess %f supplied for pipeline\n",
shininess);
return;
}
authority = _cogl_pipeline_get_authority (pipeline, state);
lighting_state = &authority->big_state->lighting_state;
if (lighting_state->shininess == shininess)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
lighting_state = &pipeline->big_state->lighting_state;
lighting_state->shininess = shininess;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_lighting_state_equal);
}
void
cogl_pipeline_get_emission (CoglPipeline *pipeline,
CoglColor *emission)
{
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_LIGHTING);
cogl_color_init_from_4fv (emission,
authority->big_state->lighting_state.emission);
}
void
cogl_pipeline_set_emission (CoglPipeline *pipeline, const CoglColor *emission)
{
CoglPipeline *authority;
CoglPipelineState state = COGL_PIPELINE_STATE_LIGHTING;
CoglPipelineLightingState *lighting_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
lighting_state = &authority->big_state->lighting_state;
if (cogl_color_equal (emission, &lighting_state->emission))
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
lighting_state = &pipeline->big_state->lighting_state;
lighting_state->emission[0] = cogl_color_get_red_float (emission);
lighting_state->emission[1] = cogl_color_get_green_float (emission);
lighting_state->emission[2] = cogl_color_get_blue_float (emission);
lighting_state->emission[3] = cogl_color_get_alpha_float (emission);
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_lighting_state_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
static void
_cogl_pipeline_set_alpha_test_function (CoglPipeline *pipeline,
CoglPipelineAlphaFunc alpha_func)
{
CoglPipelineState state = COGL_PIPELINE_STATE_ALPHA_FUNC;
CoglPipeline *authority;
CoglPipelineAlphaFuncState *alpha_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
alpha_state = &authority->big_state->alpha_state;
if (alpha_state->alpha_func == alpha_func)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
alpha_state = &pipeline->big_state->alpha_state;
alpha_state->alpha_func = alpha_func;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_alpha_func_state_equal);
}
static void
_cogl_pipeline_set_alpha_test_function_reference (CoglPipeline *pipeline,
float alpha_reference)
{
CoglPipelineState state = COGL_PIPELINE_STATE_ALPHA_FUNC_REFERENCE;
CoglPipeline *authority;
CoglPipelineAlphaFuncState *alpha_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
alpha_state = &authority->big_state->alpha_state;
if (alpha_state->alpha_func_reference == alpha_reference)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
alpha_state = &pipeline->big_state->alpha_state;
alpha_state->alpha_func_reference = alpha_reference;
_cogl_pipeline_update_authority
(pipeline, authority, state,
_cogl_pipeline_alpha_func_reference_state_equal);
}
void
cogl_pipeline_set_alpha_test_function (CoglPipeline *pipeline,
CoglPipelineAlphaFunc alpha_func,
float alpha_reference)
{
_cogl_pipeline_set_alpha_test_function (pipeline, alpha_func);
_cogl_pipeline_set_alpha_test_function_reference (pipeline, alpha_reference);
}
CoglPipelineAlphaFunc
cogl_pipeline_get_alpha_test_function (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), 0);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_ALPHA_FUNC);
return authority->big_state->alpha_state.alpha_func;
}
float
cogl_pipeline_get_alpha_test_reference (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), 0.0f);
authority =
_cogl_pipeline_get_authority (pipeline,
COGL_PIPELINE_STATE_ALPHA_FUNC_REFERENCE);
return authority->big_state->alpha_state.alpha_func_reference;
}
GLenum
arg_to_gl_blend_factor (CoglBlendStringArgument *arg)
{
if (arg->source.is_zero)
return GL_ZERO;
if (arg->factor.is_one)
return GL_ONE;
else if (arg->factor.is_src_alpha_saturate)
return GL_SRC_ALPHA_SATURATE;
else if (arg->factor.source.info->type ==
COGL_BLEND_STRING_COLOR_SOURCE_SRC_COLOR)
{
if (arg->factor.source.mask != COGL_BLEND_STRING_CHANNEL_MASK_ALPHA)
{
if (arg->factor.source.one_minus)
return GL_ONE_MINUS_SRC_COLOR;
else
return GL_SRC_COLOR;
}
else
{
if (arg->factor.source.one_minus)
return GL_ONE_MINUS_SRC_ALPHA;
else
return GL_SRC_ALPHA;
}
}
else if (arg->factor.source.info->type ==
COGL_BLEND_STRING_COLOR_SOURCE_DST_COLOR)
{
if (arg->factor.source.mask != COGL_BLEND_STRING_CHANNEL_MASK_ALPHA)
{
if (arg->factor.source.one_minus)
return GL_ONE_MINUS_DST_COLOR;
else
return GL_DST_COLOR;
}
else
{
if (arg->factor.source.one_minus)
return GL_ONE_MINUS_DST_ALPHA;
else
return GL_DST_ALPHA;
}
}
#if defined(HAVE_COGL_GLES2) || defined(HAVE_COGL_GL)
else if (arg->factor.source.info->type ==
COGL_BLEND_STRING_COLOR_SOURCE_CONSTANT)
{
if (arg->factor.source.mask != COGL_BLEND_STRING_CHANNEL_MASK_ALPHA)
{
if (arg->factor.source.one_minus)
return GL_ONE_MINUS_CONSTANT_COLOR;
else
return GL_CONSTANT_COLOR;
}
else
{
if (arg->factor.source.one_minus)
return GL_ONE_MINUS_CONSTANT_ALPHA;
else
return GL_CONSTANT_ALPHA;
}
}
#endif
g_warning ("Unable to determine valid blend factor from blend string\n");
return GL_ONE;
}
void
setup_blend_state (CoglBlendStringStatement *statement,
GLenum *blend_equation,
GLint *blend_src_factor,
GLint *blend_dst_factor)
{
switch (statement->function->type)
{
case COGL_BLEND_STRING_FUNCTION_ADD:
*blend_equation = GL_FUNC_ADD;
break;
/* TODO - add more */
default:
g_warning ("Unsupported blend function given");
*blend_equation = GL_FUNC_ADD;
}
*blend_src_factor = arg_to_gl_blend_factor (&statement->args[0]);
*blend_dst_factor = arg_to_gl_blend_factor (&statement->args[1]);
}
gboolean
cogl_pipeline_set_blend (CoglPipeline *pipeline,
const char *blend_description,
GError **error)
{
CoglPipelineState state = COGL_PIPELINE_STATE_BLEND;
CoglPipeline *authority;
CoglBlendStringStatement statements[2];
CoglBlendStringStatement *rgb;
CoglBlendStringStatement *a;
GError *internal_error = NULL;
int count;
CoglPipelineBlendState *blend_state;
_COGL_GET_CONTEXT (ctx, FALSE);
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), FALSE);
count =
_cogl_blend_string_compile (blend_description,
COGL_BLEND_STRING_CONTEXT_BLENDING,
statements,
&internal_error);
if (!count)
{
if (error)
g_propagate_error (error, internal_error);
else
{
g_warning ("Cannot compile blend description: %s\n",
internal_error->message);
g_error_free (internal_error);
}
return FALSE;
}
if (count == 1)
rgb = a = statements;
else
{
rgb = &statements[0];
a = &statements[1];
}
authority =
_cogl_pipeline_get_authority (pipeline, state);
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
blend_state = &pipeline->big_state->blend_state;
#if defined (HAVE_COGL_GL) || defined (HAVE_COGL_GLES2)
if (ctx->driver != COGL_DRIVER_GLES1)
{
setup_blend_state (rgb,
&blend_state->blend_equation_rgb,
&blend_state->blend_src_factor_rgb,
&blend_state->blend_dst_factor_rgb);
setup_blend_state (a,
&blend_state->blend_equation_alpha,
&blend_state->blend_src_factor_alpha,
&blend_state->blend_dst_factor_alpha);
}
else
#endif
{
setup_blend_state (rgb,
NULL,
&blend_state->blend_src_factor_rgb,
&blend_state->blend_dst_factor_rgb);
}
/* If we are the current authority see if we can revert to one of our
* ancestors being the authority */
if (pipeline == authority &&
_cogl_pipeline_get_parent (authority) != NULL)
{
CoglPipeline *parent = _cogl_pipeline_get_parent (authority);
CoglPipeline *old_authority =
_cogl_pipeline_get_authority (parent, state);
if (_cogl_pipeline_blend_state_equal (authority, old_authority))
pipeline->differences &= ~state;
}
/* If we weren't previously the authority on this state then we need
* to extended our differences mask and so it's possible that some
* of our ancestry will now become redundant, so we aim to reparent
* ourselves if that's true... */
if (pipeline != authority)
{
pipeline->differences |= state;
_cogl_pipeline_prune_redundant_ancestry (pipeline);
}
_cogl_pipeline_update_blend_enable (pipeline, state);
return TRUE;
}
void
cogl_pipeline_set_blend_constant (CoglPipeline *pipeline,
const CoglColor *constant_color)
{
_COGL_GET_CONTEXT (ctx, NO_RETVAL);
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
if (ctx->driver == COGL_DRIVER_GLES1)
return;
#if defined(HAVE_COGL_GLES2) || defined(HAVE_COGL_GL)
{
CoglPipelineState state = COGL_PIPELINE_STATE_BLEND;
CoglPipeline *authority;
CoglPipelineBlendState *blend_state;
authority = _cogl_pipeline_get_authority (pipeline, state);
blend_state = &authority->big_state->blend_state;
if (cogl_color_equal (constant_color, &blend_state->blend_constant))
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
blend_state = &pipeline->big_state->blend_state;
blend_state->blend_constant = *constant_color;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_blend_state_equal);
_cogl_pipeline_update_blend_enable (pipeline, state);
}
#endif
}
CoglHandle
cogl_pipeline_get_user_program (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), COGL_INVALID_HANDLE);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_USER_SHADER);
return authority->big_state->user_program;
}
/* XXX: for now we don't mind if the program has vertex shaders
* attached but if we ever make a similar API public we should only
* allow attaching of programs containing fragment shaders. Eventually
* we will have a CoglPipeline abstraction to also cover vertex
* processing.
*/
void
cogl_pipeline_set_user_program (CoglPipeline *pipeline,
CoglHandle program)
{
CoglPipelineState state = COGL_PIPELINE_STATE_USER_SHADER;
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
if (authority->big_state->user_program == program)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
if (program != COGL_INVALID_HANDLE)
{
_cogl_pipeline_set_fragend (pipeline, COGL_PIPELINE_FRAGEND_DEFAULT);
_cogl_pipeline_set_vertend (pipeline, COGL_PIPELINE_VERTEND_DEFAULT);
}
/* If we are the current authority see if we can revert to one of our
* ancestors being the authority */
if (pipeline == authority &&
_cogl_pipeline_get_parent (authority) != NULL)
{
CoglPipeline *parent = _cogl_pipeline_get_parent (authority);
CoglPipeline *old_authority =
_cogl_pipeline_get_authority (parent, state);
if (old_authority->big_state->user_program == program)
pipeline->differences &= ~state;
}
else if (pipeline != authority)
{
/* If we weren't previously the authority on this state then we
* need to extended our differences mask and so it's possible
* that some of our ancestry will now become redundant, so we
* aim to reparent ourselves if that's true... */
pipeline->differences |= state;
_cogl_pipeline_prune_redundant_ancestry (pipeline);
}
if (program != COGL_INVALID_HANDLE)
cogl_handle_ref (program);
if (authority == pipeline &&
pipeline->big_state->user_program != COGL_INVALID_HANDLE)
cogl_handle_unref (pipeline->big_state->user_program);
pipeline->big_state->user_program = program;
_cogl_pipeline_update_blend_enable (pipeline, state);
}
gboolean
cogl_pipeline_set_depth_state (CoglPipeline *pipeline,
const CoglDepthState *depth_state,
GError **error)
{
CoglPipelineState state = COGL_PIPELINE_STATE_DEPTH;
CoglPipeline *authority;
CoglDepthState *orig_state;
_COGL_GET_CONTEXT (ctx, FALSE);
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), FALSE);
_COGL_RETURN_VAL_IF_FAIL (depth_state->magic == COGL_DEPTH_STATE_MAGIC, FALSE);
authority = _cogl_pipeline_get_authority (pipeline, state);
orig_state = &authority->big_state->depth_state;
if (orig_state->test_enabled == depth_state->test_enabled &&
orig_state->write_enabled == depth_state->write_enabled &&
orig_state->test_function == depth_state->test_function &&
orig_state->range_near == depth_state->range_near &&
orig_state->range_far == depth_state->range_far)
return TRUE;
if (ctx->driver == COGL_DRIVER_GLES1 &&
(depth_state->range_near != 0 ||
depth_state->range_far != 1))
{
g_set_error (error,
COGL_ERROR,
COGL_ERROR_UNSUPPORTED,
"glDepthRange not available on GLES 1");
return FALSE;
}
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
pipeline->big_state->depth_state = *depth_state;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_depth_state_equal);
return TRUE;
}
void
cogl_pipeline_get_depth_state (CoglPipeline *pipeline,
CoglDepthState *state)
{
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_DEPTH);
*state = authority->big_state->depth_state;
}
CoglColorMask
cogl_pipeline_get_color_mask (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), 0);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_LOGIC_OPS);
return authority->big_state->logic_ops_state.color_mask;
}
void
cogl_pipeline_set_color_mask (CoglPipeline *pipeline,
CoglColorMask color_mask)
{
CoglPipelineState state = COGL_PIPELINE_STATE_LOGIC_OPS;
CoglPipeline *authority;
CoglPipelineLogicOpsState *logic_ops_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
logic_ops_state = &authority->big_state->logic_ops_state;
if (logic_ops_state->color_mask == color_mask)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
logic_ops_state = &pipeline->big_state->logic_ops_state;
logic_ops_state->color_mask = color_mask;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_logic_ops_state_equal);
}
void
_cogl_pipeline_set_fog_state (CoglPipeline *pipeline,
const CoglPipelineFogState *fog_state)
{
CoglPipelineState state = COGL_PIPELINE_STATE_FOG;
CoglPipeline *authority;
CoglPipelineFogState *current_fog_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
current_fog_state = &authority->big_state->fog_state;
if (current_fog_state->enabled == fog_state->enabled &&
cogl_color_equal (&current_fog_state->color, &fog_state->color) &&
current_fog_state->mode == fog_state->mode &&
current_fog_state->density == fog_state->density &&
current_fog_state->z_near == fog_state->z_near &&
current_fog_state->z_far == fog_state->z_far)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
pipeline->big_state->fog_state = *fog_state;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_fog_state_equal);
}
void
cogl_pipeline_set_cull_face_mode (CoglPipeline *pipeline,
CoglPipelineCullFaceMode cull_face_mode)
{
CoglPipelineState state = COGL_PIPELINE_STATE_CULL_FACE;
CoglPipeline *authority;
CoglPipelineCullFaceState *cull_face_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
cull_face_state = &authority->big_state->cull_face_state;
if (cull_face_state->mode == cull_face_mode)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
pipeline->big_state->cull_face_state.mode = cull_face_mode;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_cull_face_state_equal);
}
void
cogl_pipeline_set_front_face_winding (CoglPipeline *pipeline,
CoglWinding front_winding)
{
CoglPipelineState state = COGL_PIPELINE_STATE_CULL_FACE;
CoglPipeline *authority;
CoglPipelineCullFaceState *cull_face_state;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
cull_face_state = &authority->big_state->cull_face_state;
if (cull_face_state->front_winding == front_winding)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
pipeline->big_state->cull_face_state.front_winding = front_winding;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_cull_face_state_equal);
}
CoglPipelineCullFaceMode
cogl_pipeline_get_cull_face_mode (CoglPipeline *pipeline)
{
CoglPipelineState state = COGL_PIPELINE_STATE_CULL_FACE;
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline),
COGL_PIPELINE_CULL_FACE_MODE_NONE);
authority = _cogl_pipeline_get_authority (pipeline, state);
return authority->big_state->cull_face_state.mode;
}
CoglWinding
cogl_pipeline_get_front_face_winding (CoglPipeline *pipeline)
{
CoglPipelineState state = COGL_PIPELINE_STATE_CULL_FACE;
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline),
COGL_PIPELINE_CULL_FACE_MODE_NONE);
authority = _cogl_pipeline_get_authority (pipeline, state);
return authority->big_state->cull_face_state.front_winding;
}
float
cogl_pipeline_get_point_size (CoglPipeline *pipeline)
{
CoglPipeline *authority;
_COGL_RETURN_VAL_IF_FAIL (cogl_is_pipeline (pipeline), FALSE);
authority =
_cogl_pipeline_get_authority (pipeline, COGL_PIPELINE_STATE_POINT_SIZE);
return authority->big_state->point_size;
}
void
cogl_pipeline_set_point_size (CoglPipeline *pipeline,
float point_size)
{
CoglPipelineState state = COGL_PIPELINE_STATE_POINT_SIZE;
CoglPipeline *authority;
_COGL_RETURN_IF_FAIL (cogl_is_pipeline (pipeline));
authority = _cogl_pipeline_get_authority (pipeline, state);
if (authority->big_state->point_size == point_size)
return;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
pipeline->big_state->point_size = point_size;
_cogl_pipeline_update_authority (pipeline, authority, state,
_cogl_pipeline_point_size_equal);
}
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
static CoglBoxedValue *
_cogl_pipeline_override_uniform (CoglPipeline *pipeline,
int location)
{
CoglPipelineState state = COGL_PIPELINE_STATE_UNIFORMS;
CoglPipelineUniformsState *uniforms_state;
int override_index;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
_COGL_GET_CONTEXT (ctx, NULL);
g_return_val_if_fail (cogl_is_pipeline (pipeline), NULL);
g_return_val_if_fail (location >= 0, NULL);
g_return_val_if_fail (location < ctx->n_uniform_names, NULL);
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
uniforms_state = &pipeline->big_state->uniforms_state;
/* Count the number of bits that are set below this location. That
should give us the position where our new value should lie */
override_index = _cogl_bitmask_popcount_upto (&uniforms_state->override_mask,
location);
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
_cogl_bitmask_set (&uniforms_state->changed_mask, location, TRUE);
/* If this pipeline already has an override for this value then we
can just use it directly */
if (_cogl_bitmask_get (&uniforms_state->override_mask, location))
return uniforms_state->override_values + override_index;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
/* We need to create a new override value in the right position
within the array. This is pretty inefficient but the hope is that
it will be much more common to modify an existing uniform rather
than modify a new one so it is more important to optimise the
former case. */
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
if (uniforms_state->override_values == NULL)
{
g_assert (override_index == 0);
uniforms_state->override_values = g_new (CoglBoxedValue, 1);
}
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
else
{
/* We need to grow the array and copy in the old values */
CoglBoxedValue *old_values = uniforms_state->override_values;
int old_size = _cogl_bitmask_popcount (&uniforms_state->override_mask);
uniforms_state->override_values = g_new (CoglBoxedValue, old_size + 1);
/* Copy in the old values leaving a gap for the new value */
memcpy (uniforms_state->override_values,
old_values,
sizeof (CoglBoxedValue) * override_index);
memcpy (uniforms_state->override_values + override_index + 1,
old_values + override_index,
sizeof (CoglBoxedValue) * (old_size - override_index));
g_free (old_values);
}
_cogl_boxed_value_init (uniforms_state->override_values + override_index);
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
_cogl_bitmask_set (&uniforms_state->override_mask, location, TRUE);
return uniforms_state->override_values + override_index;
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
}
void
cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline,
int uniform_location,
float value)
{
CoglBoxedValue *boxed_value;
boxed_value = _cogl_pipeline_override_uniform (pipeline, uniform_location);
_cogl_boxed_value_set_1f (boxed_value, value);
}
void
cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline,
int uniform_location,
int value)
{
CoglBoxedValue *boxed_value;
boxed_value = _cogl_pipeline_override_uniform (pipeline, uniform_location);
_cogl_boxed_value_set_1i (boxed_value, value);
}
void
cogl_pipeline_set_uniform_float (CoglPipeline *pipeline,
int uniform_location,
int n_components,
int count,
const float *value)
{
CoglBoxedValue *boxed_value;
boxed_value = _cogl_pipeline_override_uniform (pipeline, uniform_location);
_cogl_boxed_value_set_float (boxed_value, n_components, count, value);
}
void
cogl_pipeline_set_uniform_int (CoglPipeline *pipeline,
int uniform_location,
int n_components,
int count,
const int *value)
{
CoglBoxedValue *boxed_value;
boxed_value = _cogl_pipeline_override_uniform (pipeline, uniform_location);
_cogl_boxed_value_set_int (boxed_value, n_components, count, value);
}
void
cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline,
int uniform_location,
int dimensions,
int count,
gboolean transpose,
const float *value)
{
CoglBoxedValue *boxed_value;
boxed_value = _cogl_pipeline_override_uniform (pipeline, uniform_location);
_cogl_boxed_value_set_matrix (boxed_value,
dimensions,
count,
transpose,
value);
}
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
static void
_cogl_pipeline_add_vertex_snippet (CoglPipeline *pipeline,
CoglSnippet *snippet)
{
CoglPipelineState state = COGL_PIPELINE_STATE_VERTEX_SNIPPETS;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
_cogl_pipeline_snippet_list_add (&pipeline->big_state->vertex_snippets,
snippet);
}
static void
_cogl_pipeline_add_fragment_snippet (CoglPipeline *pipeline,
CoglSnippet *snippet)
{
CoglPipelineState state = COGL_PIPELINE_STATE_FRAGMENT_SNIPPETS;
/* - Flush journal primitives referencing the current state.
* - Make sure the pipeline has no dependants so it may be modified.
* - If the pipeline isn't currently an authority for the state being
* changed, then initialize that state from the current authority.
*/
_cogl_pipeline_pre_change_notify (pipeline, state, NULL, FALSE);
_cogl_pipeline_snippet_list_add (&pipeline->big_state->fragment_snippets,
snippet);
}
void
cogl_pipeline_add_snippet (CoglPipeline *pipeline,
CoglSnippet *snippet)
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
{
g_return_if_fail (cogl_is_pipeline (pipeline));
g_return_if_fail (cogl_is_snippet (snippet));
g_return_if_fail (snippet->hook < COGL_SNIPPET_FIRST_LAYER_HOOK);
if (snippet->hook < COGL_SNIPPET_FIRST_PIPELINE_FRAGMENT_HOOK)
_cogl_pipeline_add_vertex_snippet (pipeline, snippet);
else
_cogl_pipeline_add_fragment_snippet (pipeline, snippet);
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
}
gboolean
_cogl_pipeline_has_non_layer_vertex_snippets (CoglPipeline *pipeline)
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
{
CoglPipeline *authority =
_cogl_pipeline_get_authority (pipeline,
COGL_PIPELINE_STATE_VERTEX_SNIPPETS);
return !COGL_LIST_EMPTY (&authority->big_state->vertex_snippets);
}
static gboolean
check_layer_has_vertex_snippet (CoglPipelineLayer *layer,
void *user_data)
{
unsigned long state = COGL_PIPELINE_LAYER_STATE_VERTEX_SNIPPETS;
CoglPipelineLayer *authority =
_cogl_pipeline_layer_get_authority (layer, state);
gboolean *found_vertex_snippet = user_data;
if (!COGL_LIST_EMPTY (&authority->big_state->vertex_snippets))
{
*found_vertex_snippet = TRUE;
return FALSE;
}
return TRUE;
}
gboolean
_cogl_pipeline_has_vertex_snippets (CoglPipeline *pipeline)
{
gboolean found_vertex_snippet = FALSE;
if (_cogl_pipeline_has_non_layer_vertex_snippets (pipeline))
return TRUE;
_cogl_pipeline_foreach_layer_internal (pipeline,
check_layer_has_vertex_snippet,
&found_vertex_snippet);
return found_vertex_snippet;
}
gboolean
_cogl_pipeline_has_non_layer_fragment_snippets (CoglPipeline *pipeline)
{
CoglPipeline *authority =
_cogl_pipeline_get_authority (pipeline,
COGL_PIPELINE_STATE_FRAGMENT_SNIPPETS);
return !COGL_LIST_EMPTY (&authority->big_state->fragment_snippets);
}
static gboolean
check_layer_has_fragment_snippet (CoglPipelineLayer *layer,
void *user_data)
{
unsigned long state = COGL_PIPELINE_LAYER_STATE_FRAGMENT_SNIPPETS;
CoglPipelineLayer *authority =
_cogl_pipeline_layer_get_authority (layer, state);
gboolean *found_fragment_snippet = user_data;
if (!COGL_LIST_EMPTY (&authority->big_state->fragment_snippets))
{
*found_fragment_snippet = TRUE;
return FALSE;
}
return TRUE;
}
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
gboolean
_cogl_pipeline_has_fragment_snippets (CoglPipeline *pipeline)
{
gboolean found_fragment_snippet = FALSE;
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
if (_cogl_pipeline_has_non_layer_fragment_snippets (pipeline))
return TRUE;
_cogl_pipeline_foreach_layer_internal (pipeline,
check_layer_has_fragment_snippet,
&found_fragment_snippet);
return found_fragment_snippet;
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
}
void
_cogl_pipeline_hash_color_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
state->hash = _cogl_util_one_at_a_time_hash (state->hash, &authority->color,
_COGL_COLOR_DATA_SIZE);
}
void
_cogl_pipeline_hash_blend_enable_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
guint8 blend_enable = authority->blend_enable;
state->hash = _cogl_util_one_at_a_time_hash (state->hash, &blend_enable, 1);
}
void
_cogl_pipeline_hash_lighting_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineLightingState *lighting_state =
&authority->big_state->lighting_state;
state->hash =
_cogl_util_one_at_a_time_hash (state->hash, lighting_state,
sizeof (CoglPipelineLightingState));
}
void
_cogl_pipeline_hash_alpha_func_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineAlphaFuncState *alpha_state = &authority->big_state->alpha_state;
state->hash =
_cogl_util_one_at_a_time_hash (state->hash, &alpha_state->alpha_func,
sizeof (alpha_state->alpha_func));
}
void
_cogl_pipeline_hash_alpha_func_reference_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineAlphaFuncState *alpha_state = &authority->big_state->alpha_state;
float ref = alpha_state->alpha_func_reference;
state->hash =
_cogl_util_one_at_a_time_hash (state->hash, &ref, sizeof (float));
}
void
_cogl_pipeline_hash_blend_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineBlendState *blend_state = &authority->big_state->blend_state;
unsigned int hash;
_COGL_GET_CONTEXT (ctx, NO_RETVAL);
if (!authority->real_blend_enable)
return;
hash = state->hash;
#if defined(HAVE_COGL_GLES2) || defined(HAVE_COGL_GL)
if (ctx->driver != COGL_DRIVER_GLES1)
{
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_equation_rgb,
sizeof (blend_state->blend_equation_rgb));
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_equation_alpha,
sizeof (blend_state->blend_equation_alpha));
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_src_factor_alpha,
sizeof (blend_state->blend_src_factor_alpha));
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_dst_factor_alpha,
sizeof (blend_state->blend_dst_factor_alpha));
if (blend_state->blend_src_factor_rgb == GL_ONE_MINUS_CONSTANT_COLOR ||
blend_state->blend_src_factor_rgb == GL_CONSTANT_COLOR ||
blend_state->blend_dst_factor_rgb == GL_ONE_MINUS_CONSTANT_COLOR ||
blend_state->blend_dst_factor_rgb == GL_CONSTANT_COLOR)
{
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_constant,
sizeof (blend_state->blend_constant));
}
}
#endif
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_src_factor_rgb,
sizeof (blend_state->blend_src_factor_rgb));
hash =
_cogl_util_one_at_a_time_hash (hash, &blend_state->blend_dst_factor_rgb,
sizeof (blend_state->blend_dst_factor_rgb));
state->hash = hash;
}
void
_cogl_pipeline_hash_user_shader_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglHandle user_program = authority->big_state->user_program;
state->hash = _cogl_util_one_at_a_time_hash (state->hash, &user_program,
sizeof (user_program));
}
void
_cogl_pipeline_hash_depth_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglDepthState *depth_state = &authority->big_state->depth_state;
unsigned int hash = state->hash;
if (depth_state->test_enabled)
{
guint8 enabled = depth_state->test_enabled;
CoglDepthTestFunction function = depth_state->test_function;
hash = _cogl_util_one_at_a_time_hash (hash, &enabled, sizeof (enabled));
hash = _cogl_util_one_at_a_time_hash (hash, &function, sizeof (function));
}
if (depth_state->write_enabled)
{
guint8 enabled = depth_state->write_enabled;
float near_val = depth_state->range_near;
float far_val = depth_state->range_far;
hash = _cogl_util_one_at_a_time_hash (hash, &enabled, sizeof (enabled));
hash = _cogl_util_one_at_a_time_hash (hash, &near_val, sizeof (near_val));
hash = _cogl_util_one_at_a_time_hash (hash, &far_val, sizeof (far_val));
}
state->hash = hash;
}
void
_cogl_pipeline_hash_fog_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineFogState *fog_state = &authority->big_state->fog_state;
unsigned long hash = state->hash;
if (!fog_state->enabled)
hash = _cogl_util_one_at_a_time_hash (hash, &fog_state->enabled,
sizeof (fog_state->enabled));
else
hash = _cogl_util_one_at_a_time_hash (hash, &fog_state,
sizeof (CoglPipelineFogState));
state->hash = hash;
}
void
_cogl_pipeline_hash_point_size_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
float point_size = authority->big_state->point_size;
state->hash = _cogl_util_one_at_a_time_hash (state->hash, &point_size,
sizeof (point_size));
}
void
_cogl_pipeline_hash_logic_ops_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineLogicOpsState *logic_ops_state = &authority->big_state->logic_ops_state;
state->hash = _cogl_util_one_at_a_time_hash (state->hash, &logic_ops_state->color_mask,
sizeof (CoglColorMask));
}
void
_cogl_pipeline_hash_cull_face_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
CoglPipelineCullFaceState *cull_face_state
= &authority->big_state->cull_face_state;
/* The cull face state is considered equal if two pipelines are both
set to no culling. If the front winding property is ever used for
anything else or the hashing is used not just for drawing then
this would have to change */
if (cull_face_state->mode == COGL_PIPELINE_CULL_FACE_MODE_NONE)
state->hash =
_cogl_util_one_at_a_time_hash (state->hash,
&cull_face_state->mode,
sizeof (CoglPipelineCullFaceMode));
else
state->hash =
_cogl_util_one_at_a_time_hash (state->hash,
cull_face_state,
sizeof (CoglPipelineCullFaceState));
}
cogl-pipeline: Add support for setting uniform values This adds the following new public experimental functions to set uniform values on a CoglPipeline: void cogl_pipeline_set_uniform_1f (CoglPipeline *pipeline, int uniform_location, float value); void cogl_pipeline_set_uniform_1i (CoglPipeline *pipeline, int uniform_location, int value); void cogl_pipeline_set_uniform_float (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const float *value); void cogl_pipeline_set_uniform_int (CoglPipeline *pipeline, int uniform_location, int n_components, int count, const int *value); void cogl_pipeline_set_uniform_matrix (CoglPipeline *pipeline, int uniform_location, int dimensions, int count, gboolean transpose, const float *value); These are similar to the old functions used to set uniforms on a CoglProgram. To get a value to pass in as the uniform_location there is also: int cogl_pipeline_get_uniform_location (CoglPipeline *pipeline, const char *uniform_name); Conceptually the uniform locations are tied to the pipeline so that whenever setting a value for a new pipeline the application is expected to call this function. However in practice the uniform locations are global to the CoglContext. The names are stored in a linked list where the position in the list is the uniform location. The global indices are used so that each pipeline can store a mask of which uniforms it overrides. That way it is quicker to detect which uniforms are different from the last pipeline that used the same CoglProgramState so it can avoid flushing uniforms that haven't changed. Currently the values are not actually compared which means that it will only avoid flushing a uniform if there is a common ancestor that sets the value (or if the same pipeline is being flushed again - in which case the pipeline and its common ancestor are the same thing). The uniform values are stored in the big state of the pipeline as a sparse linked list. A bitmask stores which values have been overridden and only overridden values are stored in the linked list. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-03 13:20:43 -04:00
void
_cogl_pipeline_hash_uniforms_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
/* This isn't used anywhere yet because the uniform state doesn't
affect program generation. It's quite a hassle to implement so
let's just leave it until something actually needs it */
g_warn_if_reached ();
}
void
_cogl_pipeline_compare_uniform_differences (unsigned long *differences,
CoglPipeline *pipeline0,
CoglPipeline *pipeline1)
{
GSList *head0 = NULL;
GSList *head1 = NULL;
CoglPipeline *node0;
CoglPipeline *node1;
int len0 = 0;
int len1 = 0;
int count;
GSList *common_ancestor0;
GSList *common_ancestor1;
/* This algorithm is copied from
_cogl_pipeline_compare_differences(). It might be nice to share
the code more */
for (node0 = pipeline0; node0; node0 = _cogl_pipeline_get_parent (node0))
{
GSList *link = alloca (sizeof (GSList));
link->next = head0;
link->data = node0;
head0 = link;
len0++;
}
for (node1 = pipeline1; node1; node1 = _cogl_pipeline_get_parent (node1))
{
GSList *link = alloca (sizeof (GSList));
link->next = head1;
link->data = node1;
head1 = link;
len1++;
}
/* NB: There's no point looking at the head entries since we know both
* pipelines must have the same default pipeline as their root node. */
common_ancestor0 = head0;
common_ancestor1 = head1;
head0 = head0->next;
head1 = head1->next;
count = MIN (len0, len1) - 1;
while (count--)
{
if (head0->data != head1->data)
break;
common_ancestor0 = head0;
common_ancestor1 = head1;
head0 = head0->next;
head1 = head1->next;
}
for (head0 = common_ancestor0->next; head0; head0 = head0->next)
{
node0 = head0->data;
if ((node0->differences & COGL_PIPELINE_STATE_UNIFORMS))
{
const CoglPipelineUniformsState *uniforms_state =
&node0->big_state->uniforms_state;
_cogl_bitmask_set_flags (&uniforms_state->override_mask,
differences);
}
}
for (head1 = common_ancestor1->next; head1; head1 = head1->next)
{
node1 = head1->data;
if ((node1->differences & COGL_PIPELINE_STATE_UNIFORMS))
{
const CoglPipelineUniformsState *uniforms_state =
&node1->big_state->uniforms_state;
_cogl_bitmask_set_flags (&uniforms_state->override_mask,
differences);
}
}
}
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
void
_cogl_pipeline_hash_vertex_snippets_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
_cogl_pipeline_snippet_list_hash (&authority->big_state->vertex_snippets,
&state->hash);
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
}
void
_cogl_pipeline_hash_fragment_snippets_state (CoglPipeline *authority,
CoglPipelineHashState *state)
{
_cogl_pipeline_snippet_list_hash (&authority->big_state->fragment_snippets,
&state->hash);
cogl-pipeline: Add two hook points for adding shader snippets This adds two new public experimental functions for attaching CoglSnippets to two hook points on a CoglPipeline: void cogl_pipeline_add_vertex_hook (CoglPipeline *, CoglSnippet *) void cogl_pipeline_add_fragment_hook (CoglPipeline *, CoglSnippet *) The hooks are intended to be around the entire vertex or fragment processing. That means the pre string in the snippet will be inserted at the very top of the main function and the post function will be inserted at the very end. The declarations get inserted in the global scope. The snippets are stored in two separate linked lists with a structure containing an enum representing the hook point and a pointer to the snippet. The lists are meant to be for hooks that affect the vertex shader and fragment shader respectively. Although there are currently only two hooks and the names match these two lists, the intention is *not* that each new hook will be in a separate list. The separation of the lists is just to make it easier to determine which shader needs to be regenerated when a new snippet is added. When a pipeline becomes the authority for either the vertex or fragment snipper state, it simply copies the entire list from the previous authority (although of course the shader snippet objects are referenced instead of copied so it doesn't duplicate the source strings). Each string is inserted into its own block in the shader. This means that each string has its own scope so it doesn't need to worry about name collisions with variables in other snippets. However it does mean that the pre and post strings can't share variables. It could be possible to wrap both parts in one block and then wrap the actual inner hook code in another block, however this would mean that any further snippets within the outer snippet would be able to see those variables. Perhaps something to consider would be to put each snippet into its own function which calls another function between the pre and post strings to do further processing. The pipeline cache for generated programs was previously shared with the fragment shader cache because the state that affects vertex shaders was a subset of the state that affects fragment shaders. This is no longer the case because there is a separate state mask for vertex snippets so the program cache now has its own hash table. Reviewed-by: Robert Bragg <robert@linux.intel.com>
2011-11-17 11:52:21 -05:00
}