archive/blender-archive
Archived
1
1
Fork 0
Code Pull Requests Activity
This repository has been archived on 2023-10-09. You can view files and clone it, but cannot push or open issues or pull requests.
Files
905d1c71b9f3b0543357c0ea190d77faca40d54d
blender-archive/intern/cycles/kernel/integrator/shade_volume.h
Brecht Van Lommel 905d1c71b9 Cycles: record path guiding information for dedicated shadow ray 
A flag was not enough for this, we actually need to pass along the MIS weight,
so we can compute the direct contribution without the MIS weight.

Pull Request: blender/blender#108195
2023-05-23 16:48:30 +02:00

1230 lines
47 KiB
C++
Raw Blame History

/* SPDX-License-Identifier: Apache-2.0
* Copyright 2011-2022 Blender Foundation */
#pragma once
#include "kernel/film/data_passes.h"
#include "kernel/film/denoising_passes.h"
#include "kernel/film/light_passes.h"
#include "kernel/integrator/guiding.h"
#include "kernel/integrator/intersect_closest.h"
#include "kernel/integrator/path_state.h"
#include "kernel/integrator/shadow_linking.h"
#include "kernel/integrator/volume_shader.h"
#include "kernel/integrator/volume_stack.h"
#include "kernel/light/light.h"
#include "kernel/light/sample.h"
CCL_NAMESPACE_BEGIN
#ifdef __VOLUME__
/* Events for probabilistic scattering. */
typedef enum VolumeIntegrateEvent {
VOLUME_PATH_SCATTERED = 0,
VOLUME_PATH_ATTENUATED = 1,
VOLUME_PATH_MISSED = 2
} VolumeIntegrateEvent;
typedef struct VolumeIntegrateResult {
/* Throughput and offset for direct light scattering. */
bool direct_scatter;
Spectrum direct_throughput;
float direct_t;
ShaderVolumePhases direct_phases;
# ifdef __PATH_GUIDING__
VolumeSampleMethod direct_sample_method;
# endif
/* Throughput and offset for indirect light scattering. */
bool indirect_scatter;
Spectrum indirect_throughput;
float indirect_t;
ShaderVolumePhases indirect_phases;
} VolumeIntegrateResult;
/* Ignore paths that have volume throughput below this value, to avoid unnecessary work
* and precision issues.
* todo: this value could be tweaked or turned into a probability to avoid unnecessary
* work in volumes and subsurface scattering. */
# define VOLUME_THROUGHPUT_EPSILON 1e-6f
/* Volume shader properties
*
* extinction coefficient = absorption coefficient + scattering coefficient
* sigma_t = sigma_a + sigma_s */
typedef struct VolumeShaderCoefficients {
Spectrum sigma_t;
Spectrum sigma_s;
Spectrum emission;
} VolumeShaderCoefficients;
/* Evaluate shader to get extinction coefficient at P. */
ccl_device_inline bool shadow_volume_shader_sample(KernelGlobals kg,
IntegratorShadowState state,
ccl_private ShaderData *ccl_restrict sd,
ccl_private Spectrum *ccl_restrict extinction)
{
VOLUME_READ_LAMBDA(integrator_state_read_shadow_volume_stack(state, i))
volume_shader_eval<true>(kg, state, sd, PATH_RAY_SHADOW, volume_read_lambda_pass);
if (!(sd->flag & SD_EXTINCTION)) {
return false;
}
const float density = object_volume_density(kg, sd->object);
*extinction = sd->closure_transparent_extinction * density;
return true;
}
/* Evaluate shader to get absorption, scattering and emission at P. */
ccl_device_inline bool volume_shader_sample(KernelGlobals kg,
IntegratorState state,
ccl_private ShaderData *ccl_restrict sd,
ccl_private VolumeShaderCoefficients *coeff)
{
const uint32_t path_flag = INTEGRATOR_STATE(state, path, flag);
VOLUME_READ_LAMBDA(integrator_state_read_volume_stack(state, i))
volume_shader_eval<false>(kg, state, sd, path_flag, volume_read_lambda_pass);
if (!(sd->flag & (SD_EXTINCTION | SD_SCATTER | SD_EMISSION))) {
return false;
}
coeff->sigma_s = zero_spectrum();
coeff->sigma_t = (sd->flag & SD_EXTINCTION) ? sd->closure_transparent_extinction :
zero_spectrum();
coeff->emission = (sd->flag & SD_EMISSION) ? sd->closure_emission_background : zero_spectrum();
if (sd->flag & SD_SCATTER) {
for (int i = 0; i < sd->num_closure; i++) {
ccl_private const ShaderClosure *sc = &sd->closure[i];
if (CLOSURE_IS_VOLUME(sc->type)) {
coeff->sigma_s += sc->weight;
}
}
}
const float density = object_volume_density(kg, sd->object);
coeff->sigma_s *= density;
coeff->sigma_t *= density;
coeff->emission *= density;
return true;
}
ccl_device_forceinline void volume_step_init(KernelGlobals kg,
ccl_private const RNGState *rng_state,
const float object_step_size,
const float tmin,
const float tmax,
ccl_private float *step_size,
ccl_private float *step_shade_offset,
ccl_private float *steps_offset,
ccl_private int *max_steps)
{
if (object_step_size == FLT_MAX) {
/* Homogeneous volume. */
*step_size = tmax - tmin;
*step_shade_offset = 0.0f;
*steps_offset = 1.0f;
*max_steps = 1;
}
else {
/* Heterogeneous volume. */
*max_steps = kernel_data.integrator.volume_max_steps;
const float t = tmax - tmin;
float step = min(object_step_size, t);
/* compute exact steps in advance for malloc */
if (t > *max_steps * step) {
step = t / (float)*max_steps;
}
*step_size = step;
/* Perform shading at this offset within a step, to integrate over
* over the entire step segment. */
*step_shade_offset = path_state_rng_1D(kg, rng_state, PRNG_VOLUME_SHADE_OFFSET);
/* Shift starting point of all segment by this random amount to avoid
* banding artifacts from the volume bounding shape. */
*steps_offset = path_state_rng_1D(kg, rng_state, PRNG_VOLUME_OFFSET);
}
}
/* Volume Shadows
*
* These functions are used to attenuate shadow rays to lights. Both absorption
* and scattering will block light, represented by the extinction coefficient. */
# if 0
/* homogeneous volume: assume shader evaluation at the starts gives
* the extinction coefficient for the entire line segment */
ccl_device void volume_shadow_homogeneous(KernelGlobals kg, IntegratorState state,
ccl_private Ray *ccl_restrict ray,
ccl_private ShaderData *ccl_restrict sd,
ccl_global Spectrum *ccl_restrict throughput)
{
Spectrum sigma_t = zero_spectrum();
if (shadow_volume_shader_sample(kg, state, sd, &sigma_t)) {
*throughput *= volume_color_transmittance(sigma_t, ray->tmax - ray->tmin);
}
}
# endif
/* heterogeneous volume: integrate stepping through the volume until we
* reach the end, get absorbed entirely, or run out of iterations */
ccl_device void volume_shadow_heterogeneous(KernelGlobals kg,
IntegratorShadowState state,
ccl_private Ray *ccl_restrict ray,
ccl_private ShaderData *ccl_restrict sd,
ccl_private Spectrum *ccl_restrict throughput,
const float object_step_size)
{
/* Load random number state. */
RNGState rng_state;
shadow_path_state_rng_load(state, &rng_state);
Spectrum tp = *throughput;
/* Prepare for stepping.
* For shadows we do not offset all segments, since the starting point is
* already a random distance inside the volume. It also appears to create
* banding artifacts for unknown reasons. */
int max_steps;
float step_size, step_shade_offset, unused;
volume_step_init(kg,
&rng_state,
object_step_size,
ray->tmin,
ray->tmax,
&step_size,
&step_shade_offset,
&unused,
&max_steps);
const float steps_offset = 1.0f;
/* compute extinction at the start */
float t = ray->tmin;
Spectrum sum = zero_spectrum();
for (int i = 0; i < max_steps; i++) {
/* advance to new position */
float new_t = min(ray->tmax, ray->tmin + (i + steps_offset) * step_size);
float dt = new_t - t;
float3 new_P = ray->P + ray->D * (t + dt * step_shade_offset);
Spectrum sigma_t = zero_spectrum();
/* compute attenuation over segment */
sd->P = new_P;
if (shadow_volume_shader_sample(kg, state, sd, &sigma_t)) {
/* Compute `expf()` only for every Nth step, to save some calculations
* because `exp(a)*exp(b) = exp(a+b)`, also do a quick #VOLUME_THROUGHPUT_EPSILON
* check then. */
sum += (-sigma_t * dt);
if ((i & 0x07) == 0) { /* TODO: Other interval? */
tp = *throughput * exp(sum);
/* stop if nearly all light is blocked */
if (reduce_max(tp) < VOLUME_THROUGHPUT_EPSILON)
break;
}
}
/* stop if at the end of the volume */
t = new_t;
if (t == ray->tmax) {
/* Update throughput in case we haven't done it above */
tp = *throughput * exp(sum);
break;
}
}
*throughput = tp;
}
/* Equi-angular sampling as in:
* "Importance Sampling Techniques for Path Tracing in Participating Media" */
/* Below this pdf we ignore samples, as they tend to lead to very long distances.
* This can cause performance issues with BVH traversal in OptiX, leading it to
* traverse many nodes. Since these contribute very little to the image, just ignore
* those samples. */
# define VOLUME_SAMPLE_PDF_CUTOFF 1e-8f
ccl_device float volume_equiangular_sample(ccl_private const Ray *ccl_restrict ray,
const float3 light_P,
const float xi,
ccl_private float *pdf)
{
const float tmin = ray->tmin;
const float tmax = ray->tmax;
const float delta = dot((light_P - ray->P), ray->D);
const float D = safe_sqrtf(len_squared(light_P - ray->P) - delta * delta);
if (UNLIKELY(D == 0.0f)) {
*pdf = 0.0f;
return 0.0f;
}
const float theta_a = atan2f(tmin - delta, D);
const float theta_b = atan2f(tmax - delta, D);
const float t_ = D * tanf((xi * theta_b) + (1 - xi) * theta_a);
if (UNLIKELY(theta_b == theta_a)) {
*pdf = 0.0f;
return 0.0f;
}
*pdf = D / ((theta_b - theta_a) * (D * D + t_ * t_));
return clamp(delta + t_, tmin, tmax); /* clamp is only for float precision errors */
}
ccl_device float volume_equiangular_pdf(ccl_private const Ray *ccl_restrict ray,
const float3 light_P,
const float sample_t)
{
const float delta = dot((light_P - ray->P), ray->D);
const float D = safe_sqrtf(len_squared(light_P - ray->P) - delta * delta);
if (UNLIKELY(D == 0.0f)) {
return 0.0f;
}
const float tmin = ray->tmin;
const float tmax = ray->tmax;
const float t_ = sample_t - delta;
const float theta_a = atan2f(tmin - delta, D);
const float theta_b = atan2f(tmax - delta, D);
if (UNLIKELY(theta_b == theta_a)) {
return 0.0f;
}
const float pdf = D / ((theta_b - theta_a) * (D * D + t_ * t_));
return pdf;
}
ccl_device float volume_equiangular_cdf(ccl_private const Ray *ccl_restrict ray,
const float3 light_P,
const float sample_t)
{
float delta = dot((light_P - ray->P), ray->D);
float D = safe_sqrtf(len_squared(light_P - ray->P) - delta * delta);
if (UNLIKELY(D == 0.0f)) {
return 0.0f;
}
const float tmin = ray->tmin;
const float tmax = ray->tmax;
const float t_ = sample_t - delta;
const float theta_a = atan2f(tmin - delta, D);
const float theta_b = atan2f(tmax - delta, D);
if (UNLIKELY(theta_b == theta_a)) {
return 0.0f;
}
const float theta_sample = atan2f(t_, D);
const float cdf = (theta_sample - theta_a) / (theta_b - theta_a);
return cdf;
}
/* Distance sampling */
ccl_device float volume_distance_sample(float max_t,
Spectrum sigma_t,
int channel,
float xi,
ccl_private Spectrum *transmittance,
ccl_private Spectrum *pdf)
{
/* xi is [0, 1[ so log(0) should never happen, division by zero is
* avoided because sample_sigma_t > 0 when SD_SCATTER is set */
float sample_sigma_t = volume_channel_get(sigma_t, channel);
Spectrum full_transmittance = volume_color_transmittance(sigma_t, max_t);
float sample_transmittance = volume_channel_get(full_transmittance, channel);
float sample_t = min(max_t, -logf(1.0f - xi * (1.0f - sample_transmittance)) / sample_sigma_t);
*transmittance = volume_color_transmittance(sigma_t, sample_t);
*pdf = safe_divide_color(sigma_t * *transmittance, one_spectrum() - full_transmittance);
/* todo: optimization: when taken together with hit/miss decision,
* the full_transmittance cancels out drops out and xi does not
* need to be remapped */
return sample_t;
}
ccl_device Spectrum volume_distance_pdf(float max_t, Spectrum sigma_t, float sample_t)
{
Spectrum full_transmittance = volume_color_transmittance(sigma_t, max_t);
Spectrum transmittance = volume_color_transmittance(sigma_t, sample_t);
return safe_divide_color(sigma_t * transmittance, one_spectrum() - full_transmittance);
}
/* Emission */
ccl_device Spectrum volume_emission_integrate(ccl_private VolumeShaderCoefficients *coeff,
int closure_flag,
Spectrum transmittance,
float t)
{
/* integral E * exp(-sigma_t * t) from 0 to t = E * (1 - exp(-sigma_t * t))/sigma_t
* this goes to E * t as sigma_t goes to zero
*
* todo: we should use an epsilon to avoid precision issues near zero sigma_t */
Spectrum emission = coeff->emission;
if (closure_flag & SD_EXTINCTION) {
Spectrum sigma_t = coeff->sigma_t;
FOREACH_SPECTRUM_CHANNEL (i) {
GET_SPECTRUM_CHANNEL(emission, i) *= (GET_SPECTRUM_CHANNEL(sigma_t, i) > 0.0f) ?
(1.0f - GET_SPECTRUM_CHANNEL(transmittance, i)) /
GET_SPECTRUM_CHANNEL(sigma_t, i) :
t;
}
}
else
emission *= t;
return emission;
}
/* Volume Integration */
typedef struct VolumeIntegrateState {
/* Volume segment extents. */
float tmin;
float tmax;
/* If volume is absorption-only up to this point, and no probabilistic
* scattering or termination has been used yet. */
bool absorption_only;
/* Random numbers for scattering. */
float rscatter;
float rphase;
/* Multiple importance sampling. */
VolumeSampleMethod direct_sample_method;
bool use_mis;
float distance_pdf;
float equiangular_pdf;
} VolumeIntegrateState;
ccl_device_forceinline void volume_integrate_step_scattering(
ccl_private const ShaderData *sd,
ccl_private const Ray *ray,
const float3 equiangular_light_P,
ccl_private const VolumeShaderCoefficients &ccl_restrict coeff,
const Spectrum transmittance,
ccl_private VolumeIntegrateState &ccl_restrict vstate,
ccl_private VolumeIntegrateResult &ccl_restrict result)
{
/* Pick random color channel, we use the Veach one-sample
* model with balance heuristic for the channels. */
const Spectrum albedo = safe_divide_color(coeff.sigma_s, coeff.sigma_t);
Spectrum channel_pdf;
const int channel = volume_sample_channel(
albedo, result.indirect_throughput, vstate.rphase, &channel_pdf);
/* Equiangular sampling for direct lighting. */
if (vstate.direct_sample_method == VOLUME_SAMPLE_EQUIANGULAR && !result.direct_scatter) {
if (result.direct_t >= vstate.tmin && result.direct_t <= vstate.tmax &&
vstate.equiangular_pdf > VOLUME_SAMPLE_PDF_CUTOFF)
{
const float new_dt = result.direct_t - vstate.tmin;
const Spectrum new_transmittance = volume_color_transmittance(coeff.sigma_t, new_dt);
result.direct_scatter = true;
result.direct_throughput *= coeff.sigma_s * new_transmittance / vstate.equiangular_pdf;
volume_shader_copy_phases(&result.direct_phases, sd);
/* Multiple importance sampling. */
if (vstate.use_mis) {
const float distance_pdf = vstate.distance_pdf *
dot(channel_pdf, coeff.sigma_t * new_transmittance);
const float mis_weight = 2.0f * power_heuristic(vstate.equiangular_pdf, distance_pdf);
result.direct_throughput *= mis_weight;
}
}
else {
result.direct_throughput *= transmittance;
vstate.distance_pdf *= dot(channel_pdf, transmittance);
}
}
/* Distance sampling for indirect and optional direct lighting. */
if (!result.indirect_scatter) {
/* decide if we will scatter or continue */
const float sample_transmittance = volume_channel_get(transmittance, channel);
if (1.0f - vstate.rscatter >= sample_transmittance) {
/* compute sampling distance */
const float sample_sigma_t = volume_channel_get(coeff.sigma_t, channel);
const float new_dt = -logf(1.0f - vstate.rscatter) / sample_sigma_t;
const float new_t = vstate.tmin + new_dt;
/* transmittance and pdf */
const Spectrum new_transmittance = volume_color_transmittance(coeff.sigma_t, new_dt);
const float distance_pdf = dot(channel_pdf, coeff.sigma_t * new_transmittance);
if (vstate.distance_pdf * distance_pdf > VOLUME_SAMPLE_PDF_CUTOFF) {
/* throughput */
result.indirect_scatter = true;
result.indirect_t = new_t;
result.indirect_throughput *= coeff.sigma_s * new_transmittance / distance_pdf;
volume_shader_copy_phases(&result.indirect_phases, sd);
if (vstate.direct_sample_method != VOLUME_SAMPLE_EQUIANGULAR) {
/* If using distance sampling for direct light, just copy parameters
* of indirect light since we scatter at the same point then. */
result.direct_scatter = true;
result.direct_t = result.indirect_t;
result.direct_throughput = result.indirect_throughput;
volume_shader_copy_phases(&result.direct_phases, sd);
/* Multiple importance sampling. */
if (vstate.use_mis) {
const float equiangular_pdf = volume_equiangular_pdf(ray, equiangular_light_P, new_t);
const float mis_weight = power_heuristic(vstate.distance_pdf * distance_pdf,
equiangular_pdf);
result.direct_throughput *= 2.0f * mis_weight;
}
}
}
}
else {
/* throughput */
const float pdf = dot(channel_pdf, transmittance);
result.indirect_throughput *= transmittance / pdf;
if (vstate.direct_sample_method != VOLUME_SAMPLE_EQUIANGULAR) {
vstate.distance_pdf *= pdf;
}
/* remap rscatter so we can reuse it and keep thing stratified */
vstate.rscatter = 1.0f - (1.0f - vstate.rscatter) / sample_transmittance;
}
}
}
/* heterogeneous volume distance sampling: integrate stepping through the
* volume until we reach the end, get absorbed entirely, or run out of
* iterations. this does probabilistically scatter or get transmitted through
* for path tracing where we don't want to branch. */
ccl_device_forceinline void volume_integrate_heterogeneous(
KernelGlobals kg,
IntegratorState state,
ccl_private Ray *ccl_restrict ray,
ccl_private ShaderData *ccl_restrict sd,
ccl_private const RNGState *rng_state,
ccl_global float *ccl_restrict render_buffer,
const float object_step_size,
const VolumeSampleMethod direct_sample_method,
const float3 equiangular_light_P,
ccl_private VolumeIntegrateResult &result)
{
PROFILING_INIT(kg, PROFILING_SHADE_VOLUME_INTEGRATE);
/* Prepare for stepping.
* Using a different step offset for the first step avoids banding artifacts. */
int max_steps;
float step_size, step_shade_offset, steps_offset;
volume_step_init(kg,
rng_state,
object_step_size,
ray->tmin,
ray->tmax,
&step_size,
&step_shade_offset,
&steps_offset,
&max_steps);
/* Initialize volume integration state. */
VolumeIntegrateState vstate ccl_optional_struct_init;
vstate.tmin = ray->tmin;
vstate.tmax = ray->tmin;
vstate.absorption_only = true;
vstate.rscatter = path_state_rng_1D(kg, rng_state, PRNG_VOLUME_SCATTER_DISTANCE);
vstate.rphase = path_state_rng_1D(kg, rng_state, PRNG_VOLUME_PHASE_CHANNEL);
/* Multiple importance sampling: pick between equiangular and distance sampling strategy. */
vstate.direct_sample_method = direct_sample_method;
vstate.use_mis = (direct_sample_method == VOLUME_SAMPLE_MIS);
if (vstate.use_mis) {
if (vstate.rscatter < 0.5f) {
vstate.rscatter *= 2.0f;
vstate.direct_sample_method = VOLUME_SAMPLE_DISTANCE;
}
else {
vstate.rscatter = (vstate.rscatter - 0.5f) * 2.0f;
vstate.direct_sample_method = VOLUME_SAMPLE_EQUIANGULAR;
}
}
vstate.equiangular_pdf = 0.0f;
vstate.distance_pdf = 1.0f;
/* Initialize volume integration result. */
const Spectrum throughput = INTEGRATOR_STATE(state, path, throughput);
result.direct_throughput = throughput;
result.indirect_throughput = throughput;
/* Equiangular sampling: compute distance and PDF in advance. */
if (vstate.direct_sample_method == VOLUME_SAMPLE_EQUIANGULAR) {
result.direct_t = volume_equiangular_sample(
ray, equiangular_light_P, vstate.rscatter, &vstate.equiangular_pdf);
}
# ifdef __PATH_GUIDING__
result.direct_sample_method = vstate.direct_sample_method;
# endif
# ifdef __DENOISING_FEATURES__
const bool write_denoising_features = (INTEGRATOR_STATE(state, path, flag) &
PATH_RAY_DENOISING_FEATURES);
Spectrum accum_albedo = zero_spectrum();
# endif
Spectrum accum_emission = zero_spectrum();
for (int i = 0; i < max_steps; i++) {
/* Advance to new position */
vstate.tmax = min(ray->tmax, ray->tmin + (i + steps_offset) * step_size);
const float shade_t = vstate.tmin + (vstate.tmax - vstate.tmin) * step_shade_offset;
sd->P = ray->P + ray->D * shade_t;
/* compute segment */
VolumeShaderCoefficients coeff ccl_optional_struct_init;
if (volume_shader_sample(kg, state, sd, &coeff)) {
const int closure_flag = sd->flag;
/* Evaluate transmittance over segment. */
const float dt = (vstate.tmax - vstate.tmin);
const Spectrum transmittance = (closure_flag & SD_EXTINCTION) ?
volume_color_transmittance(coeff.sigma_t, dt) :
one_spectrum();
/* Emission. */
if (closure_flag & SD_EMISSION) {
/* Only write emission before indirect light scatter position, since we terminate
* stepping at that point if we have already found a direct light scatter position. */
if (!result.indirect_scatter) {
const Spectrum emission = volume_emission_integrate(
&coeff, closure_flag, transmittance, dt);
accum_emission += result.indirect_throughput * emission;
guiding_record_volume_emission(kg, state, emission);
}
}
if (closure_flag & SD_EXTINCTION) {
if ((closure_flag & SD_SCATTER) || !vstate.absorption_only) {
# ifdef __DENOISING_FEATURES__
/* Accumulate albedo for denoising features. */
if (write_denoising_features && (closure_flag & SD_SCATTER)) {
const Spectrum albedo = safe_divide_color(coeff.sigma_s, coeff.sigma_t);
accum_albedo += result.indirect_throughput * albedo * (one_spectrum() - transmittance);
}
# endif
/* Scattering and absorption. */
volume_integrate_step_scattering(
sd, ray, equiangular_light_P, coeff, transmittance, vstate, result);
}
else {
/* Absorption only. */
result.indirect_throughput *= transmittance;
result.direct_throughput *= transmittance;
}
/* Stop if nearly all light blocked. */
if (!result.indirect_scatter) {
if (reduce_max(result.indirect_throughput) < VOLUME_THROUGHPUT_EPSILON) {
result.indirect_throughput = zero_spectrum();
break;
}
}
else if (!result.direct_scatter) {
if (reduce_max(result.direct_throughput) < VOLUME_THROUGHPUT_EPSILON) {
break;
}
}
}
/* If we have scattering data for both direct and indirect, we're done. */
if (result.direct_scatter && result.indirect_scatter) {
break;
}
}
/* Stop if at the end of the volume. */
vstate.tmin = vstate.tmax;
if (vstate.tmin == ray->tmax) {
break;
}
}
/* Write accumulated emission. */
if (!is_zero(accum_emission)) {
if (light_link_object_match(kg, light_link_receiver_forward(kg, state), sd->object)) {
film_write_volume_emission(
kg, state, accum_emission, render_buffer, object_lightgroup(kg, sd->object));
}
}
# ifdef __DENOISING_FEATURES__
/* Write denoising features. */
if (write_denoising_features) {
film_write_denoising_features_volume(
kg, state, accum_albedo, result.indirect_scatter, render_buffer);
}
# endif /* __DENOISING_FEATURES__ */
}
/* Path tracing: sample point on light for equiangular sampling. */
ccl_device_forceinline bool integrate_volume_equiangular_sample_light(
KernelGlobals kg,
IntegratorState state,
ccl_private const Ray *ccl_restrict ray,
ccl_private const ShaderData *ccl_restrict sd,
ccl_private const RNGState *ccl_restrict rng_state,
ccl_private float3 *ccl_restrict P)
{
/* Test if there is a light or BSDF that needs direct light. */
if (!kernel_data.integrator.use_direct_light) {
return false;
}
/* Sample position on a light. */
const uint32_t path_flag = INTEGRATOR_STATE(state, path, flag);
const uint bounce = INTEGRATOR_STATE(state, path, bounce);
const float3 rand_light = path_state_rng_3D(kg, rng_state, PRNG_LIGHT);
LightSample ls ccl_optional_struct_init;
if (!light_sample_from_volume_segment(kg,
rand_light.z,
rand_light.x,
rand_light.y,
sd->time,
sd->P,
ray->D,
ray->tmax - ray->tmin,
light_link_receiver_nee(kg, sd),
bounce,
path_flag,
&ls))
{
return false;
}
if (ls.shader & SHADER_EXCLUDE_SCATTER) {
return false;
}
if (ls.t == FLT_MAX) {
return false;
}
*P = ls.P;
return true;
}
/* Path tracing: sample point on light and evaluate light shader, then
* queue shadow ray to be traced. */
ccl_device_forceinline void integrate_volume_direct_light(
KernelGlobals kg,
IntegratorState state,
ccl_private const ShaderData *ccl_restrict sd,
ccl_private const RNGState *ccl_restrict rng_state,
const float3 P,
ccl_private const ShaderVolumePhases *ccl_restrict phases,
# ifdef __PATH_GUIDING__
ccl_private const Spectrum unlit_throughput,
# endif
ccl_private const Spectrum throughput)
{
PROFILING_INIT(kg, PROFILING_SHADE_VOLUME_DIRECT_LIGHT);
if (!kernel_data.integrator.use_direct_light) {
return;
}
/* Sample position on the same light again, now from the shading point where we scattered.
*
* Note that this means we sample the light tree twice when equiangular sampling is used.
* We could consider sampling the light tree just once and use the same light position again.
*
* This would make the PDFs for MIS weights more complicated due to having to account for
* both distance/equiangular and direct/indirect light sampling, but could be more accurate.
* Additionally we could end up behind the light or outside a spot light cone, which might
* waste a sample. Though on the other hand it would be possible to prevent that with
* equiangular sampling restricted to a smaller sub-segment where the light has influence. */
LightSample ls ccl_optional_struct_init;
{
const uint32_t path_flag = INTEGRATOR_STATE(state, path, flag);
const uint bounce = INTEGRATOR_STATE(state, path, bounce);
const float3 rand_light = path_state_rng_3D(kg, rng_state, PRNG_LIGHT);
if (!light_sample_from_position(kg,
rng_state,
rand_light.z,
rand_light.x,
rand_light.y,
sd->time,
P,
zero_float3(),
light_link_receiver_nee(kg, sd),
SD_BSDF_HAS_TRANSMISSION,
bounce,
path_flag,
&ls))
{
return;
}
}
if (ls.shader & SHADER_EXCLUDE_SCATTER) {
return;
}
/* Evaluate light shader.
*
* TODO: can we reuse sd memory? In theory we can move this after
* integrate_surface_bounce, evaluate the BSDF, and only then evaluate
* the light shader. This could also move to its own kernel, for
* non-constant light sources. */
ShaderDataTinyStorage emission_sd_storage;
ccl_private ShaderData *emission_sd = AS_SHADER_DATA(&emission_sd_storage);
const Spectrum light_eval = light_sample_shader_eval(kg, state, emission_sd, &ls, sd->time);
if (is_zero(light_eval)) {
return;
}
/* Evaluate BSDF. */
BsdfEval phase_eval ccl_optional_struct_init;
float phase_pdf = volume_shader_phase_eval(kg, state, sd, phases, ls.D, &phase_eval);
if (ls.shader & SHADER_USE_MIS) {
float mis_weight = light_sample_mis_weight_nee(kg, ls.pdf, phase_pdf);
bsdf_eval_mul(&phase_eval, mis_weight);
}
bsdf_eval_mul(&phase_eval, light_eval / ls.pdf);
/* Path termination. */
const float terminate = path_state_rng_light_termination(kg, rng_state);
if (light_sample_terminate(kg, &ls, &phase_eval, terminate)) {
return;
}
/* Create shadow ray. */
Ray ray ccl_optional_struct_init;
light_sample_to_volume_shadow_ray(kg, sd, &ls, P, &ray);
/* Branch off shadow kernel. */
IntegratorShadowState shadow_state = integrator_shadow_path_init(
kg, state, DEVICE_KERNEL_INTEGRATOR_INTERSECT_SHADOW, false);
/* Write shadow ray and associated state to global memory. */
integrator_state_write_shadow_ray(shadow_state, &ray);
integrator_state_write_shadow_ray_self(kg, shadow_state, &ray);
/* Copy state from main path to shadow path. */
const uint16_t bounce = INTEGRATOR_STATE(state, path, bounce);
const uint16_t transparent_bounce = INTEGRATOR_STATE(state, path, transparent_bounce);
uint32_t shadow_flag = INTEGRATOR_STATE(state, path, flag);
const Spectrum throughput_phase = throughput * bsdf_eval_sum(&phase_eval);
if (kernel_data.kernel_features & KERNEL_FEATURE_LIGHT_PASSES) {
PackedSpectrum pass_diffuse_weight;
PackedSpectrum pass_glossy_weight;
if (shadow_flag & PATH_RAY_ANY_PASS) {
/* Indirect bounce, use weights from earlier surface or volume bounce. */
pass_diffuse_weight = INTEGRATOR_STATE(state, path, pass_diffuse_weight);
pass_glossy_weight = INTEGRATOR_STATE(state, path, pass_glossy_weight);
}
else {
/* Direct light, no diffuse/glossy distinction needed for volumes. */
shadow_flag |= PATH_RAY_VOLUME_PASS;
pass_diffuse_weight = one_spectrum();
pass_glossy_weight = zero_spectrum();
}
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, pass_diffuse_weight) = pass_diffuse_weight;
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, pass_glossy_weight) = pass_glossy_weight;
}
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, render_pixel_index) = INTEGRATOR_STATE(
state, path, render_pixel_index);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, rng_offset) = INTEGRATOR_STATE(
state, path, rng_offset);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, rng_hash) = INTEGRATOR_STATE(
state, path, rng_hash);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, sample) = INTEGRATOR_STATE(
state, path, sample);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, flag) = shadow_flag;
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, bounce) = bounce;
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, transparent_bounce) = transparent_bounce;
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, diffuse_bounce) = INTEGRATOR_STATE(
state, path, diffuse_bounce);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, glossy_bounce) = INTEGRATOR_STATE(
state, path, glossy_bounce);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, transmission_bounce) = INTEGRATOR_STATE(
state, path, transmission_bounce);
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, throughput) = throughput_phase;
/* Write Lightgroup, +1 as lightgroup is int but we need to encode into a uint8_t. */
INTEGRATOR_STATE_WRITE(
shadow_state, shadow_path, lightgroup) = (ls.type != LIGHT_BACKGROUND) ?
ls.group + 1 :
kernel_data.background.lightgroup + 1;
# ifdef __PATH_GUIDING__
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, unlit_throughput) = unlit_throughput;
INTEGRATOR_STATE_WRITE(shadow_state, shadow_path, path_segment) = INTEGRATOR_STATE(
state, guiding, path_segment);
INTEGRATOR_STATE(shadow_state, shadow_path, guiding_mis_weight) = 0.0f;
# endif
integrator_state_copy_volume_stack_to_shadow(kg, shadow_state, state);
}
/* Path tracing: scatter in new direction using phase function */
ccl_device_forceinline bool integrate_volume_phase_scatter(
KernelGlobals kg,
IntegratorState state,
ccl_private ShaderData *sd,
ccl_private const RNGState *rng_state,
ccl_private const ShaderVolumePhases *phases)
{
PROFILING_INIT(kg, PROFILING_SHADE_VOLUME_INDIRECT_LIGHT);
float2 rand_phase = path_state_rng_2D(kg, rng_state, PRNG_VOLUME_PHASE);
ccl_private const ShaderVolumeClosure *svc = volume_shader_phase_pick(phases, &rand_phase);
/* Phase closure, sample direction. */
float phase_pdf = 0.0f, unguided_phase_pdf = 0.0f;
BsdfEval phase_eval ccl_optional_struct_init;
float3 phase_wo ccl_optional_struct_init;
float sampled_roughness = 1.0f;
int label;
# if defined(__PATH_GUIDING__) && PATH_GUIDING_LEVEL >= 4
if (kernel_data.integrator.use_guiding) {
label = volume_shader_phase_guided_sample(kg,
state,
sd,
svc,
rand_phase,
&phase_eval,
&phase_wo,
&phase_pdf,
&unguided_phase_pdf,
&sampled_roughness);
if (phase_pdf == 0.0f || bsdf_eval_is_zero(&phase_eval)) {
return false;
}
INTEGRATOR_STATE_WRITE(state, path, unguided_throughput) *= phase_pdf / unguided_phase_pdf;
}
else
# endif
{
label = volume_shader_phase_sample(
kg, sd, phases, svc, rand_phase, &phase_eval, &phase_wo, &phase_pdf, &sampled_roughness);
if (phase_pdf == 0.0f || bsdf_eval_is_zero(&phase_eval)) {
return false;
}
unguided_phase_pdf = phase_pdf;
}
/* Setup ray. */
INTEGRATOR_STATE_WRITE(state, ray, P) = sd->P;
INTEGRATOR_STATE_WRITE(state, ray, D) = normalize(phase_wo);
INTEGRATOR_STATE_WRITE(state, ray, tmin) = 0.0f;
INTEGRATOR_STATE_WRITE(state, ray, tmax) = FLT_MAX;
# ifdef __RAY_DIFFERENTIALS__
INTEGRATOR_STATE_WRITE(state, ray, dP) = differential_make_compact(sd->dP);
# endif
// Save memory by storing last hit prim and object in isect
INTEGRATOR_STATE_WRITE(state, isect, prim) = sd->prim;
INTEGRATOR_STATE_WRITE(state, isect, object) = sd->object;
const Spectrum phase_weight = bsdf_eval_sum(&phase_eval) / phase_pdf;
/* Add phase function sampling data to the path segment. */
guiding_record_volume_bounce(
kg, state, sd, phase_weight, phase_pdf, normalize(phase_wo), sampled_roughness);
/* Update throughput. */
const Spectrum throughput = INTEGRATOR_STATE(state, path, throughput);
const Spectrum throughput_phase = throughput * phase_weight;
INTEGRATOR_STATE_WRITE(state, path, throughput) = throughput_phase;
if (kernel_data.kernel_features & KERNEL_FEATURE_LIGHT_PASSES) {
if (INTEGRATOR_STATE(state, path, bounce) == 0) {
INTEGRATOR_STATE_WRITE(state, path, pass_diffuse_weight) = one_spectrum();
INTEGRATOR_STATE_WRITE(state, path, pass_glossy_weight) = zero_spectrum();
}
}
/* Update path state */
INTEGRATOR_STATE_WRITE(state, path, mis_ray_pdf) = phase_pdf;
INTEGRATOR_STATE_WRITE(state, path, mis_origin_n) = zero_float3();
INTEGRATOR_STATE_WRITE(state, path, min_ray_pdf) = fminf(
unguided_phase_pdf, INTEGRATOR_STATE(state, path, min_ray_pdf));
# ifdef __LIGHT_LINKING__
if (kernel_data.kernel_features & KERNEL_FEATURE_LIGHT_LINKING) {
INTEGRATOR_STATE_WRITE(state, path, mis_ray_object) = sd->object;
}
# endif
path_state_next(kg, state, label, sd->flag);
return true;
}
/* get the volume attenuation and emission over line segment defined by
* ray, with the assumption that there are no surfaces blocking light
* between the endpoints. distance sampling is used to decide if we will
* scatter or not. */
ccl_device VolumeIntegrateEvent volume_integrate(KernelGlobals kg,
IntegratorState state,
ccl_private Ray *ccl_restrict ray,
ccl_global float *ccl_restrict render_buffer)
{
ShaderData sd;
shader_setup_from_volume(kg, &sd, ray);
/* Load random number state. */
RNGState rng_state;
path_state_rng_load(state, &rng_state);
/* Sample light ahead of volume stepping, for equiangular sampling. */
/* TODO: distant lights are ignored now, but could instead use even distribution. */
const bool need_light_sample = !(INTEGRATOR_STATE(state, path, flag) & PATH_RAY_TERMINATE);
float3 equiangular_P = zero_float3();
const bool have_equiangular_sample = need_light_sample &&
integrate_volume_equiangular_sample_light(
kg, state, ray, &sd, &rng_state, &equiangular_P);
VolumeSampleMethod direct_sample_method = (have_equiangular_sample) ?
volume_stack_sample_method(kg, state) :
VOLUME_SAMPLE_DISTANCE;
/* Step through volume. */
VOLUME_READ_LAMBDA(integrator_state_read_volume_stack(state, i))
const float step_size = volume_stack_step_size(kg, volume_read_lambda_pass);
# if defined(__PATH_GUIDING__) && PATH_GUIDING_LEVEL >= 1
/* The current path throughput which is used later to calculate per-segment throughput. */
const float3 initial_throughput = INTEGRATOR_STATE(state, path, throughput);
/* The path throughput used to calculate the throughput for direct light. */
float3 unlit_throughput = initial_throughput;
/* If a new path segment is generated at the direct scatter position. */
bool guiding_generated_new_segment = false;
float rand_phase_guiding = 0.5f;
# endif
/* TODO: expensive to zero closures? */
VolumeIntegrateResult result = {};
volume_integrate_heterogeneous(kg,
state,
ray,
&sd,
&rng_state,
render_buffer,
step_size,
direct_sample_method,
equiangular_P,
result);
/* Perform path termination. The intersect_closest will have already marked this path
* to be terminated. That will shading evaluating to leave out any scattering closures,
* but emission and absorption are still handled for multiple importance sampling. */
const uint32_t path_flag = INTEGRATOR_STATE(state, path, flag);
const float continuation_probability = (path_flag & PATH_RAY_TERMINATE_IN_NEXT_VOLUME) ?
0.0f :
INTEGRATOR_STATE(
state, path, continuation_probability);
if (continuation_probability == 0.0f) {
return VOLUME_PATH_MISSED;
}
/* Direct light. */
if (result.direct_scatter) {
const float3 direct_P = ray->P + result.direct_t * ray->D;
# ifdef __PATH_GUIDING__
if (kernel_data.integrator.use_guiding) {
# if PATH_GUIDING_LEVEL >= 1
if (result.direct_sample_method == VOLUME_SAMPLE_DISTANCE) {
/* If the direct scatter event is generated using VOLUME_SAMPLE_DISTANCE the direct event
* will happen at the same position as the indirect event and the direct light contribution
* will contribute to the position of the next path segment. */
float3 transmittance_weight = spectrum_to_rgb(
safe_divide_color(result.indirect_throughput, initial_throughput));
guiding_record_volume_transmission(kg, state, transmittance_weight);
guiding_record_volume_segment(kg, state, direct_P, sd.wi);
guiding_generated_new_segment = true;
unlit_throughput = result.indirect_throughput / continuation_probability;
rand_phase_guiding = path_state_rng_1D(kg, &rng_state, PRNG_VOLUME_PHASE_GUIDING_DISTANCE);
}
else {
/* If the direct scatter event is generated using VOLUME_SAMPLE_EQUIANGULAR the direct
* event will happen at a separate position as the indirect event and the direct light
* contribution will contribute to the position of the current/previous path segment. The
* unlit_throughput has to be adjusted to include the scattering at the previous segment.
*/
float3 scatterEval = one_float3();
if (state->guiding.path_segment) {
pgl_vec3f scatteringWeight = state->guiding.path_segment->scatteringWeight;
scatterEval = make_float3(scatteringWeight.x, scatteringWeight.y, scatteringWeight.z);
}
unlit_throughput /= scatterEval;
unlit_throughput *= continuation_probability;
rand_phase_guiding = path_state_rng_1D(
kg, &rng_state, PRNG_VOLUME_PHASE_GUIDING_EQUIANGULAR);
}
# endif
# if PATH_GUIDING_LEVEL >= 4
volume_shader_prepare_guiding(
kg, state, &sd, rand_phase_guiding, direct_P, ray->D, &result.direct_phases);
# endif
}
# endif
result.direct_throughput /= continuation_probability;
integrate_volume_direct_light(kg,
state,
&sd,
&rng_state,
direct_P,
&result.direct_phases,
# ifdef __PATH_GUIDING__
unlit_throughput,
# endif
result.direct_throughput);
}
/* Indirect light.
*
* Only divide throughput by continuation_probability if we scatter. For the attenuation
* case the next surface will already do this division. */
if (result.indirect_scatter) {
# if defined(__PATH_GUIDING__) && PATH_GUIDING_LEVEL >= 1
if (!guiding_generated_new_segment) {
float3 transmittance_weight = spectrum_to_rgb(
safe_divide_color(result.indirect_throughput, initial_throughput));
guiding_record_volume_transmission(kg, state, transmittance_weight);
}
# endif
result.indirect_throughput /= continuation_probability;
}
INTEGRATOR_STATE_WRITE(state, path, throughput) = result.indirect_throughput;
if (result.indirect_scatter) {
sd.P = ray->P + result.indirect_t * ray->D;
# if defined(__PATH_GUIDING__)
# if PATH_GUIDING_LEVEL >= 1
if (!guiding_generated_new_segment) {
guiding_record_volume_segment(kg, state, sd.P, sd.wi);
}
# endif
# if PATH_GUIDING_LEVEL >= 4
/* If the direct scatter event was generated using VOLUME_SAMPLE_EQUIANGULAR we need to
* initialize the guiding distribution at the indirect scatter position. */
if (result.direct_sample_method == VOLUME_SAMPLE_EQUIANGULAR) {
rand_phase_guiding = path_state_rng_1D(kg, &rng_state, PRNG_VOLUME_PHASE_GUIDING_DISTANCE);
volume_shader_prepare_guiding(
kg, state, &sd, rand_phase_guiding, sd.P, ray->D, &result.indirect_phases);
}
# endif
# endif
if (integrate_volume_phase_scatter(kg, state, &sd, &rng_state, &result.indirect_phases)) {
return VOLUME_PATH_SCATTERED;
}
else {
return VOLUME_PATH_MISSED;
}
}
else {
# if defined(__PATH_GUIDING__)
/* No guiding if we don't scatter. */
state->guiding.use_volume_guiding = false;
# endif
return VOLUME_PATH_ATTENUATED;
}
}
#endif
ccl_device void integrator_shade_volume(KernelGlobals kg,
IntegratorState state,
ccl_global float *ccl_restrict render_buffer)
{
PROFILING_INIT(kg, PROFILING_SHADE_VOLUME_SETUP);
#ifdef __VOLUME__
/* Setup shader data. */
Ray ray ccl_optional_struct_init;
integrator_state_read_ray(state, &ray);
Intersection isect ccl_optional_struct_init;
integrator_state_read_isect(state, &isect);
/* Set ray length to current segment. */
ray.tmax = (isect.prim != PRIM_NONE) ? isect.t : FLT_MAX;
/* Clean volume stack for background rays. */
if (isect.prim == PRIM_NONE) {
volume_stack_clean(kg, state);
}
const VolumeIntegrateEvent event = volume_integrate(kg, state, &ray, render_buffer);
if (event == VOLUME_PATH_MISSED) {
/* End path. */
integrator_path_terminate(kg, state, DEVICE_KERNEL_INTEGRATOR_SHADE_VOLUME);
return;
}
if (event == VOLUME_PATH_ATTENUATED) {
/* Continue to background, light or surface. */
integrator_intersect_next_kernel_after_volume<DEVICE_KERNEL_INTEGRATOR_SHADE_VOLUME>(
kg, state, &isect, render_buffer);
return;
}
# ifdef __SHADOW_LINKING__
if (shadow_linking_schedule_intersection_kernel<DEVICE_KERNEL_INTEGRATOR_SHADE_VOLUME>(kg,
state)) {
return;
}
# endif /* __SHADOW_LINKING__ */
/* Queue intersect_closest kernel. */
integrator_path_next(kg,
state,
DEVICE_KERNEL_INTEGRATOR_SHADE_VOLUME,
DEVICE_KERNEL_INTEGRATOR_INTERSECT_CLOSEST);
#endif /* __VOLUME__ */
}
CCL_NAMESPACE_END
View Git Blame Copy Permalink