kannonier8/blender
1
0
Fork 0
forked from bartvdbraak/blender
Code Pull Requests Activity
84ad20acef
blender/intern/cycles/kernel/split/kernel_lamp_emission.h
Sergey Sharybin 84ad20acef Fix T44833: Can't use ccl_local space in non-kernel functions 
This commit re-shuffles code in split kernel once again and makes it so common
parts which is in the headers is only responsible to making all the work needed
for specified ray index. Getting ray index, checking for it's validity and
enqueuing tasks are now happening in the device specified part of the kernel.

This actually makes sense because enqueuing is indeed device-specified and i.e.
with CUDA we'll want to enqueue kernels from kernel and avoid CPU roundtrip.

TODO:
- Kernel comments are still placed in the common header files, but since queue
  related stuff is not passed to those functions those comments might need to
  be split as well.

  Just currently read them considering that they're also covering the way how
  all devices are invoking the common code path.

- Arguments might need to be wrapped into KernelGlobals, so we don't ened to
  pass all them around as function arguments.
2015-05-26 22:54:02 +05:00

177 lines
7.2 KiB
C
Raw Blame History

/*
* Copyright 2011-2015 Blender Foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "kernel_split_common.h"
/* Note on kernel_lamp_emission
* This is the 3rd kernel in the ray-tracing logic. This is the second of the
* path-iteration kernels. This kernel takes care of the indirect lamp emission logic.
* This kernel operates on QUEUE_ACTIVE_AND_REGENERATED_RAYS. It processes rays of state RAY_ACTIVE
* and RAY_HIT_BACKGROUND.
* We will empty QUEUE_ACTIVE_AND_REGENERATED_RAYS queue in this kernel.
* The input/output of the kernel is as follows,
* Throughput_coop ------------------------------------|--- kernel_lamp_emission --|--- PathRadiance_coop
* Ray_coop -------------------------------------------| |--- Queue_data(QUEUE_ACTIVE_AND_REGENERATED_RAYS)
* PathState_coop -------------------------------------| |--- Queue_index(QUEUE_ACTIVE_AND_REGENERATED_RAYS)
* kg (globals + data) --------------------------------| |
* Intersection_coop ----------------------------------| |
* ray_state ------------------------------------------| |
* Queue_data (QUEUE_ACTIVE_AND_REGENERATED_RAYS) -----| |
* Queue_index (QUEUE_ACTIVE_AND_REGENERATED_RAYS) ----| |
* queuesize ------------------------------------------| |
* use_queues_flag ------------------------------------| |
* sw -------------------------------------------------| |
* sh -------------------------------------------------| |
* parallel_samples -----------------------------------| |
*
* note : shader_data is neither input nor output. Its just filled and consumed in the same, kernel_lamp_emission, kernel.
*/
ccl_device void kernel_lamp_emission(
ccl_global char *globals,
ccl_constant KernelData *data,
ccl_global char *shader_data, /* Required for lamp emission */
ccl_global float3 *throughput_coop, /* Required for lamp emission */
PathRadiance *PathRadiance_coop, /* Required for lamp emission */
ccl_global Ray *Ray_coop, /* Required for lamp emission */
ccl_global PathState *PathState_coop, /* Required for lamp emission */
Intersection *Intersection_coop, /* Required for lamp emission */
ccl_global char *ray_state, /* Denotes the state of each ray */
int sw, int sh,
ccl_global char *use_queues_flag, /* Used to decide if this kernel should use
* queues to fetch ray index
*/
int parallel_samples, /* Number of samples to be processed in parallel */
int ray_index)
{
if(IS_STATE(ray_state, ray_index, RAY_ACTIVE) || IS_STATE(ray_state, ray_index, RAY_HIT_BACKGROUND)) {
KernelGlobals *kg = (KernelGlobals *)globals;
ShaderData *sd = (ShaderData *)shader_data;
PathRadiance *L = &PathRadiance_coop[ray_index];
float3 throughput = throughput_coop[ray_index];
Ray ray = Ray_coop[ray_index];
PathState state = PathState_coop[ray_index];
#ifdef __LAMP_MIS__
if(kernel_data.integrator.use_lamp_mis && !(state.flag & PATH_RAY_CAMERA)) {
/* ray starting from previous non-transparent bounce */
Ray light_ray;
light_ray.P = ray.P - state.ray_t*ray.D;
state.ray_t += Intersection_coop[ray_index].t;
light_ray.D = ray.D;
light_ray.t = state.ray_t;
light_ray.time = ray.time;
light_ray.dD = ray.dD;
light_ray.dP = ray.dP;
/* intersect with lamp */
float3 emission;
if(indirect_lamp_emission(kg, &state, &light_ray, &emission, sd)) {
path_radiance_accum_emission(L, throughput, emission, state.bounce);
}
}
#endif
/* __VOLUME__ feature is disabled */
#if 0
#ifdef __VOLUME__
/* volume attenuation, emission, scatter */
if(state.volume_stack[0].shader != SHADER_NONE) {
Ray volume_ray = ray;
volume_ray.t = (hit)? isect.t: FLT_MAX;
bool heterogeneous = volume_stack_is_heterogeneous(kg, state.volume_stack);
#ifdef __VOLUME_DECOUPLED__
int sampling_method = volume_stack_sampling_method(kg, state.volume_stack);
bool decoupled = kernel_volume_use_decoupled(kg, heterogeneous, true, sampling_method);
if(decoupled) {
/* cache steps along volume for repeated sampling */
VolumeSegment volume_segment;
ShaderData volume_sd;
shader_setup_from_volume(kg, &volume_sd, &volume_ray, state.bounce, state.transparent_bounce);
kernel_volume_decoupled_record(kg, &state,
&volume_ray, &volume_sd, &volume_segment, heterogeneous);
volume_segment.sampling_method = sampling_method;
/* emission */
if(volume_segment.closure_flag & SD_EMISSION)
path_radiance_accum_emission(&L, throughput, volume_segment.accum_emission, state.bounce);
/* scattering */
VolumeIntegrateResult result = VOLUME_PATH_ATTENUATED;
if(volume_segment.closure_flag & SD_SCATTER) {
bool all = false;
/* direct light sampling */
kernel_branched_path_volume_connect_light(kg, rng, &volume_sd,
throughput, &state, &L, 1.0f, all, &volume_ray, &volume_segment);
/* indirect sample. if we use distance sampling and take just
* one sample for direct and indirect light, we could share
* this computation, but makes code a bit complex */
float rphase = path_state_rng_1D_for_decision(kg, rng, &state, PRNG_PHASE);
float rscatter = path_state_rng_1D_for_decision(kg, rng, &state, PRNG_SCATTER_DISTANCE);
result = kernel_volume_decoupled_scatter(kg,
&state, &volume_ray, &volume_sd, &throughput,
rphase, rscatter, &volume_segment, NULL, true);
}
if(result != VOLUME_PATH_SCATTERED)
throughput *= volume_segment.accum_transmittance;
/* free cached steps */
kernel_volume_decoupled_free(kg, &volume_segment);
if(result == VOLUME_PATH_SCATTERED) {
if(kernel_path_volume_bounce(kg, rng, &volume_sd, &throughput, &state, &L, &ray))
continue;
else
break;
}
}
else
#endif
{
/* integrate along volume segment with distance sampling */
ShaderData volume_sd;
VolumeIntegrateResult result = kernel_volume_integrate(
kg, &state, &volume_sd, &volume_ray, &L, &throughput, rng, heterogeneous);
#ifdef __VOLUME_SCATTER__
if(result == VOLUME_PATH_SCATTERED) {
/* direct lighting */
kernel_path_volume_connect_light(kg, rng, &volume_sd, throughput, &state, &L);
/* indirect light bounce */
if(kernel_path_volume_bounce(kg, rng, &volume_sd, &throughput, &state, &L, &ray))
continue;
else
break;
}
#endif
}
}
#endif
#endif
}
}
View Git Blame Copy Permalink