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features/modernize #1

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Misaki merged 5 commits from features/modernize into main 2026-02-22 03:05:52 +00:00
Conversation 0 Commits 5 Files Changed 47 +246 -99
19 changed files with 246 additions and 99 deletions
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2
native/CMakeLists.txt
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@@ -1,7 +1,7 @@
set(CMAKE_EXPORT_COMPILE_COMMANDS ON) set(CMAKE_EXPORT_COMPILE_COMMANDS ON)
cmake_minimum_required(VERSION 3.10) cmake_minimum_required(VERSION 3.10)
set(CMAKE_C_STANDARD 11) set(CMAKE_C_STANDARD 23)
set(PROJECT_NAME SimpleRayTracer) set(PROJECT_NAME SimpleRayTracer)
project(${PROJECT_NAME} LANGUAGES C) project(${PROJECT_NAME} LANGUAGES C)

3
native/header/Algorithm/RayIntersection.h
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@@ -21,7 +21,8 @@ typedef struct
typedef struct typedef struct
{ {
vec3s point; vec3s point;
vec3s normal; // Should we remove normal, tangent, and uv from here and output u, v, w instead? vec3s normal;
vec3s geometric_normal;
vec3s tangent; vec3s tangent;
vec2s uv; vec2s uv;
mesh_model_handle_t model; mesh_model_handle_t model;

3
native/header/Common.h
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@@ -40,12 +40,11 @@ typedef enum
typedef struct typedef struct
{ {
vec3s wi; vec3s wi;
vec3s direct_lighting;
vec3s bsdf; vec3s bsdf;
vec3s lighting;
float pdf; float pdf;
float spread_angle; float spread_angle;
path_state state; path_state state;
bool is_delta;
} path_output; } path_output;
inline float random_float() inline float random_float()

52
native/header/Common/Collections.h
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@@ -21,35 +21,37 @@ typedef struct
{ \ { \
uint32_t length; \ uint32_t length; \
T* buffer; \ T* buffer; \
} name##_array_t; \ } name##_array_t;
static inline result_t name##_array_init(name##_array_t* array, uint32_t size) \
#define array_init(array, size) \
do \
{ \ { \
array->length = size; \ array.length = size; \
T* temp = (T*)malloc(sizeof(T) * size); \ array.buffer = malloc(sizeof(*array.buffer) * size); \
if (temp == NULL) \ } while (0)
#define array_free(array) \
do \
{ \ { \
return RESULT_OUT_OF_MEMORY; \ if (array.buffer != NULL) \
{ \
free(array.buffer); \
array.buffer = NULL; \
array.length = 0; \
} \ } \
array->buffer = temp; \ } while (0)
return RESULT_SUCCESS; \
} \ #define array_get(array, index) \
static inline void name##_array_free(name##_array_t* array) \ ((index) >= (array).length ? NULL : &(array).buffer[index])
#define list_init(list, capacity) \
do \
{ \ { \
if (array->buffer != NULL) \ capacity = capacity == 0 ? 1 : capacity; \
{ \ list.count = 0; \
free(array->buffer); \ list.capacity = capacity; \
array->buffer = NULL; \ list.buffer = (T*)malloc(sizeof(T) * capacity); \
array->length = 0; \ } while (0)
} \
} \
static inline T* name##_array_get(name##_array_t* array, uint32_t index) \
{ \
if (index >= array->length) \
{ \
return NULL; \
} \
return &array->buffer[index]; \
}
#define LIST_DEF(T, name) \ #define LIST_DEF(T, name) \
typedef struct \ typedef struct \

3
native/header/Lighting/Light.h
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@@ -5,9 +5,6 @@
#include "Rendering/Texture.h" #include "Rendering/Texture.h"
#include "cglm/struct/vec3.h" #include "cglm/struct/vec3.h"
struct scene_t;
struct bvh_tree_t;
typedef struct typedef struct
{ {
vec3s position; vec3s position;

1
native/header/Lighting/LightEvaluation.h
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@@ -7,6 +7,7 @@
#include "Rendering/Scene.h" #include "Rendering/Scene.h"
path_output evaluate_bsdf_directional( directional_light_t light, const light_shading_context_t* context, vec3s throughput, uint32_t sample_index); path_output evaluate_bsdf_directional( directional_light_t light, const light_shading_context_t* context, vec3s throughput, uint32_t sample_index);
path_output evaluate_bsdf_punctual_light(punctual_light_t light, const light_shading_context_t* context, vec3s throughput, uint32_t sample_index);
inline path_output evaluate_bsdf_sky(const light_collection_t* lights, const light_shading_context_t* context, vec3s throughput, uint32_t sample_index) inline path_output evaluate_bsdf_sky(const light_collection_t* lights, const light_shading_context_t* context, vec3s throughput, uint32_t sample_index)
{ {

1
native/header/Material/Material.h
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@@ -17,6 +17,7 @@ typedef struct
vec3s position; vec3s position;
vec3s normal; vec3s normal;
vec3s geometric_normal;
vec3s tangent; vec3s tangent;
vec3s wo; vec3s wo;
vec3s throughput; vec3s throughput;

6
native/header/Material/Shading.h
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@@ -1,6 +0,0 @@
#ifndef SHADING_CONTEXT_H
#define SHADING_CONTEXT_H
#endif // SHADING_CONTEXT_H

2
native/header/Rendering/Scene.h
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@@ -56,7 +56,7 @@ bool scene_build_bvh(scene_t* scene);
void scene_free(scene_t* scene); void scene_free(scene_t* scene);
// Mesh model/instance API (simple first, flexible later). // Mesh model/instance API (simple first, flexible later).
mesh_model_handle_t scene_add_mesh_model(scene_t* scene, uint64_t triangle_reserve); mesh_model_handle_t scene_add_mesh_model(scene_t* scene, uint32_t triangle_reserve);
mesh_instance_handle_t scene_add_mesh_instance(scene_t* scene, mesh_model_handle_t model, mat4s local_to_world); mesh_instance_handle_t scene_add_mesh_instance(scene_t* scene, mesh_model_handle_t model, mat4s local_to_world);
void scene_remove_mesh_instance(scene_t* scene, mesh_instance_handle_t instance); void scene_remove_mesh_instance(scene_t* scene, mesh_instance_handle_t instance);
void scene_set_mesh_instance_transform(scene_t* scene, mesh_instance_handle_t instance, mat4s local_to_world); void scene_set_mesh_instance_transform(scene_t* scene, mesh_instance_handle_t instance, mat4s local_to_world);

2
native/header/Rendering/Texture.h
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@@ -71,11 +71,11 @@ typedef struct
} texture_sample_context_t; } texture_sample_context_t;
texture_handle_t texture_load(const char* filename, bool srgb, bool mipmap, stride_t stride, texture_slot_map_t* textures); texture_handle_t texture_load(const char* filename, bool srgb, bool mipmap, stride_t stride, texture_slot_map_t* textures);
void texture_free(texture_t* texture);
vec4s texture_get_pixel(const texture_t* texture, vec2s uv, uint8_t lod); vec4s texture_get_pixel(const texture_t* texture, vec2s uv, uint8_t lod);
float texture_get_sample_lod(const texture_t* texture, const texture_sample_context_t* sample_context); float texture_get_sample_lod(const texture_t* texture, const texture_sample_context_t* sample_context);
vec4s texture_sample(const texture_t* texture, const texture_sample_context_t* sample_context, vec2s uv); vec4s texture_sample(const texture_t* texture, const texture_sample_context_t* sample_context, vec2s uv);
vec4s texture_sample_lod(const texture_t* texture, vec2s uv, float lod); vec4s texture_sample_lod(const texture_t* texture, vec2s uv, float lod);
void texture_free(texture_t* texture);
inline bool is_texture_entity_valid(texture_handle_t entity) inline bool is_texture_entity_valid(texture_handle_t entity)
{ {

7
native/source/Algorithm/PathTracing.c
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@@ -57,6 +57,7 @@ static inline shading_context_t make_shading_context(const scene_t* scene,
.position = hit->point, .position = hit->point,
.normal = hit->normal, .normal = hit->normal,
.geometric_normal = hit->geometric_normal,
.tangent = hit->tangent, .tangent = hit->tangent,
.uv = hit->uv, .uv = hit->uv,
.wo = wo, .wo = wo,
@@ -184,7 +185,7 @@ static void trace_lighting_aovs(const scene_t* scene,
} }
} }
vec3s env_contrib = glms_vec3_scale(sky_output.direct_lighting, w); vec3s env_contrib = glms_vec3_scale(sky_output.lighting, w);
aov_accumulate_nee(out, aov_flags, env_contrib, depth); aov_accumulate_nee(out, aov_flags, env_contrib, depth);
break; break;
} }
@@ -223,12 +224,12 @@ static void trace_lighting_aovs(const scene_t* scene,
} }
path_output material_output = render_material(hit_material, &shading_context); path_output material_output = render_material(hit_material, &shading_context);
if (glms_vec3_isinf(material_output.direct_lighting) || glms_vec3_isnan(material_output.direct_lighting)) if (glms_vec3_isinf(material_output.lighting) || glms_vec3_isnan(material_output.lighting))
{ {
break; break;
} }
aov_accumulate_nee(out, aov_flags, material_output.direct_lighting, depth); aov_accumulate_nee(out, aov_flags, material_output.lighting, depth);
if (material_output.pdf < FLT_EPSILON) if (material_output.pdf < FLT_EPSILON)
{ {

13
native/source/Algorithm/RayIntersection.c
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@@ -151,6 +151,7 @@ hit_result_t ray_intersect_triangle(const ray_t* ray, const triangle_t* triangle
normal = glms_vec3_add(normal, glms_vec3_scale(triangle->vertices[2].normal, v)); normal = glms_vec3_add(normal, glms_vec3_scale(triangle->vertices[2].normal, v));
normal = glms_vec3_dot(normal, direction) < 0.0f ? normal : glms_vec3_negate(normal); normal = glms_vec3_dot(normal, direction) < 0.0f ? normal : glms_vec3_negate(normal);
result.normal = glms_vec3_normalize(normal); result.normal = glms_vec3_normalize(normal);
result.geometric_normal = triangle->face_normal;
vec3s tangent = glms_vec3_scale(triangle->vertices[0].tangent, w); vec3s tangent = glms_vec3_scale(triangle->vertices[0].tangent, w);
tangent = glms_vec3_add(tangent, glms_vec3_scale(triangle->vertices[1].tangent, u)); tangent = glms_vec3_add(tangent, glms_vec3_scale(triangle->vertices[1].tangent, u));
@@ -308,7 +309,7 @@ void ray_intersect_bvh_any(const ray_t* ray, const bvh_node_t* bvh_nodes, const
{ {
for (uint32_t i = 0; i < node->primitive_count; i++) for (uint32_t i = 0; i < node->primitive_count; i++)
{ {
uint64_t triangle_index = primitive_indices[node->start_index + i]; uint32_t triangle_index = primitive_indices[node->start_index + i];
hit_result_t hit_result = ray_intersect_triangle(ray, &all_triangles->buffer[triangle_index]); hit_result_t hit_result = ray_intersect_triangle(ray, &all_triangles->buffer[triangle_index]);
if (hit_result.hit) if (hit_result.hit)
{ {
@@ -322,8 +323,8 @@ void ray_intersect_bvh_any(const ray_t* ray, const bvh_node_t* bvh_nodes, const
else else
{ {
// Internal node: traverse children in nearfirst order // Internal node: traverse children in nearfirst order
uint64_t left_child_index = node->left_child_offset; uint32_t left_child_index = node->left_child_offset;
uint64_t right_child_index = node->right_child_offset; uint32_t right_child_index = node->right_child_offset;
const bvh_node_t* left_child = &bvh_nodes[left_child_index]; const bvh_node_t* left_child = &bvh_nodes[left_child_index];
const bvh_node_t* right_child = &bvh_nodes[right_child_index]; const bvh_node_t* right_child = &bvh_nodes[right_child_index];
@@ -376,7 +377,7 @@ hit_result_t ray_intersect_scene_closest(const ray_t* ray, const scene_t* scene)
{ {
typedef struct typedef struct
{ {
uint64_t node_index; uint32_t node_index;
float enter; float enter;
} tlas_stack_entry_t; } tlas_stack_entry_t;
@@ -467,8 +468,8 @@ hit_result_t ray_intersect_scene_closest(const ray_t* ray, const scene_t* scene)
continue; continue;
} }
uint64_t left = node->left_child_offset; uint32_t left = node->left_child_offset;
uint64_t right = node->right_child_offset; uint32_t right = node->right_child_offset;
float left_enter, left_exit, right_enter, right_exit; float left_enter, left_exit, right_enter, right_exit;
bool hit_left = ray_intersect_aabb(ray, scene->tlas.nodes[left].bounds, &left_enter, &left_exit); bool hit_left = ray_intersect_aabb(ray, scene->tlas.nodes[left].bounds, &left_enter, &left_exit);

4
native/source/Geometry/Mesh.c
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@@ -35,7 +35,7 @@ mesh_model_handle_t mesh_load(const char* filename, scene_t* scene)
} }
// Reserve a model sized for the imported geometry. // Reserve a model sized for the imported geometry.
uint64_t triangle_reserve = 0; uint32_t triangle_reserve = 0;
for (uint32_t i = 0; i < mesh_scene->mNumMeshes; i++) for (uint32_t i = 0; i < mesh_scene->mNumMeshes; i++)
{ {
const struct aiMesh* mesh = mesh_scene->mMeshes[i]; const struct aiMesh* mesh = mesh_scene->mMeshes[i];
@@ -45,7 +45,7 @@ mesh_model_handle_t mesh_load(const char* filename, scene_t* scene)
} }
// Each face is expected to be a triangle; we still validate per face below. // Each face is expected to be a triangle; we still validate per face below.
triangle_reserve += (uint64_t)mesh->mNumFaces; triangle_reserve += (uint32_t)mesh->mNumFaces;
} }
mesh_model_handle_t handle = scene_add_mesh_model(scene, triangle_reserve); mesh_model_handle_t handle = scene_add_mesh_model(scene, triangle_reserve);

55
native/source/Lighting/LightEvaluation.c
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@@ -51,8 +51,61 @@ path_output evaluate_bsdf_directional(directional_light_t light, const light_sha
vec3s light_radiance = glms_vec3_scale(light.color, light.intensity); vec3s light_radiance = glms_vec3_scale(light.color, light.intensity);
vec3s light_contribute = glms_vec3_scale( throughput, fmaxf(0.0f, n_dot_l)); // we always assume pdf = 1.0f for directional light vec3s light_contribute = glms_vec3_scale( throughput, fmaxf(0.0f, n_dot_l)); // we always assume pdf = 1.0f for directional light
output.direct_lighting = glms_vec3_mul(light_radiance, light_contribute); output.lighting = glms_vec3_mul(light_radiance, light_contribute);
output.wi = wi; output.wi = wi;
output.state = PS_SUCCESS; output.state = PS_SUCCESS;
return output; return output;
} }
// TODO: Support light size and soft shadows
// TODO: Support different light types (spot, area)
path_output evaluate_bsdf_punctual_light(punctual_light_t light, const light_shading_context_t* context, vec3s throughput, uint32_t sample_index)
{
path_output output = {0.0f};
output.state = PS_TERMINATE;
output.pdf = 1.0f;
if (context == NULL)
{
return output;
}
if (light.intensity <= 0.0f)
{
return output;
}
vec3s light_dir = glms_vec3_normalize(glms_vec3_sub(light.position, context->position));
float distance_squared = glms_vec3_dot(glms_vec3_sub(light.position, context->position), glms_vec3_sub(light.position, context->position));
float n_dot_l = glms_vec3_dot(context->normal, light_dir);
if (n_dot_l <= 0.0f)
{
return output;
}
ray_t shadow_ray = ray_create(offset_ray_origin(context->position, context->normal, context->wo), light_dir, 0.0f, 0.0f);
hit_result_t shadow_hit = {0};
if (context->scene != NULL)
{
shadow_hit = ray_intersect_scene_any(&shadow_ray, context->scene);
}
else if (context->bvh_tree != NULL)
{
ray_intersect_bvh_any(&shadow_ray, context->bvh_tree->nodes, context->bvh_tree->primitive_indices, context->bvh_tree->triangles, 0, &shadow_hit);
}
if (shadow_hit.hit && shadow_hit.distance * shadow_hit.distance < distance_squared - FLT_EPSILON)
{
return output;
}
vec3s light_radiance = glms_vec3_scale(light.color, light.intensity / distance_squared);
vec3s light_contribute = glms_vec3_scale(throughput, fmaxf(0.0f, n_dot_l)); // we always assume pdf = 1.0f for punctual light
output.lighting = glms_vec3_mul(light_radiance, light_contribute);
output.wi = light_dir;
output.state = PS_SUCCESS;
return output;
}

12
native/source/Lighting/SkyLight.c
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@@ -40,7 +40,7 @@ path_output evaluate_bsdf_const_sky(const void* data, const light_shading_contex
// cosine-weighted hemisphere around the last shading normal. // cosine-weighted hemisphere around the last shading normal.
if (context == NULL || (context->scene == NULL && context->bvh_tree == NULL)) if (context == NULL || (context->scene == NULL && context->bvh_tree == NULL))
{ {
output.direct_lighting = glms_vec3_mul(sky_light, throughput); output.lighting = glms_vec3_mul(sky_light, throughput);
// If a normal wasn't provided, fall back to a normal-independent uniform sphere PDF. // If a normal wasn't provided, fall back to a normal-independent uniform sphere PDF.
float n2 = (context != NULL) ? glms_vec3_norm2(context->normal) : 0.0f; float n2 = (context != NULL) ? glms_vec3_norm2(context->normal) : 0.0f;
@@ -89,7 +89,7 @@ path_output evaluate_bsdf_const_sky(const void* data, const light_shading_contex
return output; return output;
} }
output.direct_lighting = glms_vec3_scale(glms_vec3_mul(sky_light, throughput), cos_theta / pdf); output.lighting = glms_vec3_scale(glms_vec3_mul(sky_light, throughput), cos_theta / pdf);
output.wi = wi; output.wi = wi;
output.state = PS_SUCCESS; output.state = PS_SUCCESS;
@@ -348,7 +348,7 @@ path_output evaluate_bsdf_hdr_sky(const void* data, const light_shading_context_
} }
vec4s sky_light = texture_sample_lod(get_texture(context->textures, sky_data->texture), uv, lod); vec4s sky_light = texture_sample_lod(get_texture(context->textures, sky_data->texture), uv, lod);
output.direct_lighting = glms_vec3_scale(glms_vec3_mul(glms_vec3(sky_light), throughput), sky_data->intensity); output.lighting = glms_vec3_scale(glms_vec3_mul(glms_vec3(sky_light), throughput), sky_data->intensity);
// Return the correct environment PDF for MIS when the BSDF-sampled ray escapes to the sky. // Return the correct environment PDF for MIS when the BSDF-sampled ray escapes to the sky.
output.pdf = hdr_sky_pdf_direction(sky_data, context->wo); output.pdf = hdr_sky_pdf_direction(sky_data, context->wo);
return output; return output;
@@ -400,9 +400,11 @@ path_output evaluate_bsdf_hdr_sky(const void* data, const light_shading_context_
return output; return output;
} }
// TODO: Both texture sampling and PDF calculation can be bilinear interpolated for better quality
// This requires us to change the uv from always being at the center of the texel to being continuous
vec2s uv = (vec2s){u, v}; vec2s uv = (vec2s){u, v};
const texture_t* hdri = get_texture(context->textures, sky_data->texture); const texture_t* hdri = get_texture(context->textures, sky_data->texture);
vec4s pixel = texture_get_pixel(hdri, uv, 0); vec4s pixel = texture_sample_lod(hdri, uv, 0);
vec3s sky_light = glms_vec3_scale(glms_vec3(pixel), sky_data->intensity); vec3s sky_light = glms_vec3_scale(glms_vec3(pixel), sky_data->intensity);
float mass = sky_data->pdf_uv_mass[y_idx * sky_data->width + x_idx]; float mass = sky_data->pdf_uv_mass[y_idx * sky_data->width + x_idx];
@@ -412,7 +414,7 @@ path_output evaluate_bsdf_hdr_sky(const void* data, const light_shading_context_
return output; return output;
} }
output.direct_lighting = glms_vec3_scale(glms_vec3_mul(sky_light, throughput), n_dot_l / pdf); output.lighting = glms_vec3_scale(glms_vec3_mul(sky_light, throughput), n_dot_l / pdf);
output.wi = wi; output.wi = wi;
output.pdf = pdf; output.pdf = pdf;
output.state = PS_SUCCESS; output.state = PS_SUCCESS;

30
native/source/Material/StandardLit.c
View File

@@ -93,7 +93,7 @@ static void get_surface_data(const shading_context_t* context, const standard_li
} }
} }
static vec3s evaluate_bsdf_standard_lit(const shading_context_t* context, standard_lit_surface_data_t* surface_data, vec3s wi) static vec3s evaluate_bsdf_standard_lit(const shading_context_t* context, const standard_lit_surface_data_t* surface_data, vec3s wi)
{ {
vec3s n = surface_data->normal; vec3s n = surface_data->normal;
vec3s v = glms_vec3_negate(context->wo); vec3s v = glms_vec3_negate(context->wo);
@@ -188,6 +188,14 @@ static float sample_bsdf_pdf(const standard_lit_surface_data_t* surface_data, ve
return w_ss * pdf_spec + w_cos * pdf_cos; return w_ss * pdf_spec + w_cos * pdf_cos;
} }
static void accumulate_lighting(path_output* output, const path_output* light_output, const shading_context_t* context, vec3s V, const standard_lit_surface_data_t* surface_data)
{
vec3s bsdf_dir_light = evaluate_bsdf_standard_lit(context, surface_data, light_output->wi);
float pdf_bsdf = sample_bsdf_pdf(surface_data, V, light_output->wi);
vec3s light_contribute = weight_nee_light(bsdf_dir_light, light_output->lighting, pdf_bsdf, light_output->pdf);
output->lighting = glms_vec3_add(output->lighting, light_contribute);
}
path_output standard_lit_render_loop(const standard_lit_properties_t* properties, const shading_context_t* context) path_output standard_lit_render_loop(const standard_lit_properties_t* properties, const shading_context_t* context)
{ {
standard_lit_surface_data_t surface_data; // Assuming you reuse your struct standard_lit_surface_data_t surface_data; // Assuming you reuse your struct
@@ -243,10 +251,17 @@ path_output standard_lit_render_loop(const standard_lit_properties_t* properties
path_output light_output = evaluate_bsdf_directional(context->lights->directional_lights.buffer[i], &light_context, context->throughput, context->sample_index); path_output light_output = evaluate_bsdf_directional(context->lights->directional_lights.buffer[i], &light_context, context->throughput, context->sample_index);
if (light_output.state == PS_SUCCESS) if (light_output.state == PS_SUCCESS)
{ {
vec3s bsdf_dir_light = evaluate_bsdf_standard_lit(context, &surface_data, light_output.wi); accumulate_lighting(&output, &light_output, context, V, &surface_data);
float pdf_bsdf = sample_bsdf_pdf(&surface_data, V, light_output.wi); }
vec3s light_contribute = weight_nee_light(bsdf_dir_light, light_output.direct_lighting, pdf_bsdf, light_output.pdf); }
output.direct_lighting = glms_vec3_add(output.direct_lighting, light_contribute);
// Punctual Lights
for (uint32_t i = 0; i < context->lights->punctual_lights.count; i++)
{
path_output light_output = evaluate_bsdf_punctual_light(context->lights->punctual_lights.buffer[i], &light_context, context->throughput, context->sample_index);
if (light_output.state == PS_SUCCESS)
{
accumulate_lighting(&output, &light_output, context, V, &surface_data);
} }
} }
@@ -254,10 +269,7 @@ path_output standard_lit_render_loop(const standard_lit_properties_t* properties
path_output sky_output = evaluate_bsdf_sky(context->lights, &light_context, context->throughput, context->sample_index); path_output sky_output = evaluate_bsdf_sky(context->lights, &light_context, context->throughput, context->sample_index);
if (sky_output.state == PS_SUCCESS) if (sky_output.state == PS_SUCCESS)
{ {
vec3s bsdf_sky_light = evaluate_bsdf_standard_lit(context, &surface_data, sky_output.wi); accumulate_lighting(&output, &sky_output, context, V, &surface_data);
float pdf_bsdf = sample_bsdf_pdf(&surface_data, V, sky_output.wi);
vec3s sky_light = weight_nee_light(bsdf_sky_light, sky_output.direct_lighting, pdf_bsdf, sky_output.pdf);
output.direct_lighting = glms_vec3_add(output.direct_lighting, sky_light);
} }
// ---------------------------------------------------- // ----------------------------------------------------

10
native/source/Rendering/Scene.c
View File

@@ -48,7 +48,7 @@ static bool scene_rebuild_tlas(scene_t* scene)
} }
// Build list of active instances. // Build list of active instances.
uint64_t active_count = 0; uint32_t active_count = 0;
for (uint32_t i = 0; i < scene->mesh_instances.capacity; ++i) for (uint32_t i = 0; i < scene->mesh_instances.capacity; ++i)
{ {
if (scene->mesh_instances.occupied[i]) if (scene->mesh_instances.occupied[i])
@@ -64,13 +64,13 @@ static bool scene_rebuild_tlas(scene_t* scene)
return true; return true;
} }
uint64_t* indices = (uint64_t*)malloc(sizeof(uint64_t) * active_count); uint32_t* indices = (uint32_t*)malloc(sizeof(uint32_t) * active_count);
if (indices == NULL) if (indices == NULL)
{ {
return false; return false;
} }
uint64_t cursor = 0; uint32_t cursor = 0;
for (uint32_t i = 0; i < scene->mesh_instances.capacity; ++i) for (uint32_t i = 0; i < scene->mesh_instances.capacity; ++i)
{ {
if (scene->mesh_instances.occupied[i]) if (scene->mesh_instances.occupied[i])
@@ -115,6 +115,8 @@ static bool scene_rebuild_tlas(scene_t* scene)
return true; return true;
} }
ARRAY_DEF(int, test)
bool scene_init(scene_t* scene, uint32_t triangle_count, uint32_t texture_count, uint32_t material_count, uint32_t punctual_light_count) bool scene_init(scene_t* scene, uint32_t triangle_count, uint32_t texture_count, uint32_t material_count, uint32_t punctual_light_count)
{ {
scene_t temp = {0}; scene_t temp = {0};
@@ -232,7 +234,7 @@ void scene_free(scene_t* scene)
light_collection_free(&scene->lights); light_collection_free(&scene->lights);
} }
mesh_model_handle_t scene_add_mesh_model(scene_t* scene, uint64_t triangle_reserve) mesh_model_handle_t scene_add_mesh_model(scene_t* scene, uint32_t triangle_reserve)
{ {
if (scene == NULL) if (scene == NULL)
{ {

2
native/source/Rendering/Texture.c
View File

@@ -362,7 +362,7 @@ float texture_get_sample_lod(const texture_t* texture, const texture_sample_cont
// 4. Convert to LOD // 4. Convert to LOD
// LOD 0 = 1 texel. LOD 1 = 2 texels. LOD 2 = 4 texels. // LOD 0 = 1 texel. LOD 1 = 2 texels. LOD 2 = 4 texels.
// log2(texels_covered) gives the mip level. // log2(texels_covered) gives the mip level.
return log2f(texels_covered) * 0.5f; return log2f(texels_covered) * 0.5f; // TODO: Apply EWA for better quality
} }
static vec4s nearest_filter(const texture_t* texture, vec2s uv, uint8_t lod) static vec4s nearest_filter(const texture_t* texture, vec2s uv, uint8_t lod)

115
native/source/main.c
View File

@@ -1,7 +1,6 @@
#include <time.h> #include <time.h>
#include <omp.h> #include <omp.h>
#include <stdint.h> #include <stdint.h>
#include <svpng.inc>
#include "Algorithm/Sobol.h" #include "Algorithm/Sobol.h"
#include "Geometry/GeometryUtilities.h" #include "Geometry/GeometryUtilities.h"
@@ -15,7 +14,14 @@
#define TITLE "Path Tracing" #define TITLE "Path Tracing"
#define SCENE_PATH "./assets/sponza.fbx" #define SCENE_PATH "./assets/sponza.fbx"
#define HDRI_PATH "C:/Users/Misaki/Downloads/shanghai_bund_1k.hdr" #define HDRI_PATH "./assets/hdri/golden_gate_hills_1k.hdr"
#define SAVE_OUTPUT
#ifdef SAVE_OUTPUT
#include <svpng.inc>
#define OUTPUT_PATH "./output.png"
#endif
static bool scene_setup(scene_t* scene) static bool scene_setup(scene_t* scene)
{ {
@@ -33,21 +39,54 @@ static bool scene_setup(scene_t* scene)
#endif #endif
// TODO: Standardize light unit // TODO: Standardize light unit
directional_light_t sun_light = // directional_light_t sun_light =
{ // {
.direction = glms_vec3_normalize((vec3s){0.6f, 1.0f, 0.25f}), // .direction = glms_vec3_normalize((vec3s){0.6f, 1.0f, 0.25f}),
.color = (vec3s){1.0f, 0.93f, 0.87f}, // .color = (vec3s){1.0f, 0.93f, 0.87f},
.intensity = 0.0f, // .intensity = 1.0f,
.angular_diameter = 0.53f // .angular_diameter = 0.53f
}; // };
light_handle_t sun = light_add_directional_light(&scene->lights, &sun_light); // light_handle_t sun = light_add_directional_light(&scene->lights, &sun_light);
// punctual_light_t point_light1 =
// {
// .position = (vec3s){1.0f, 5.0f, 0.0f},
// .color = (vec3s){1.0f, 1.0f, 1.0f},
// .intensity = 10.0f,
// };
// punctual_light_t point_light2 =
// {
// .position = (vec3s){1.0f, 5.0f, 2.5f},
// .color = (vec3s){1.0f, 1.0f, 1.0f},
// .intensity = 50.0f,
// };
// punctual_light_t point_light3 =
// {
// .position = (vec3s){1.0f, 5.0f, 2.5f},
// .color = (vec3s){1.0f, 1.0f, 1.0f},
// .intensity = 50.0f,
// };
// punctual_light_t point_light4 =
// {
// .position = (vec3s){1.0f, 5.0f, 2.5f},
// .color = (vec3s){1.0f, 1.0f, 1.0f},
// .intensity = 50.0f,
// };
// light_add_punctual_light(&scene->lights, &point_light1);
// light_add_punctual_light(&scene->lights, &point_light2);
// light_add_punctual_light(&scene->lights, &point_light3);
// light_add_punctual_light(&scene->lights, &point_light4);
#if 0 #if 0
scene->lights.sky_light = sky_create_constant_sky(&(constant_sky_data_t) scene->lights.sky_light = sky_create_constant_sky(&(constant_sky_data_t)
{ {
.color = (vec3s){1.0f, 1.0f, 1.0f}, .color = (vec3s){1.0f, 1.0f, 1.0f},
.intensity = 1.0f, .intensity = 0.0f,
}); });
#else #else
texture_handle_t hdri = texture_load(HDRI_PATH, false, false, FLOAT_32, &scene->textures); texture_handle_t hdri = texture_load(HDRI_PATH, false, false, FLOAT_32, &scene->textures);
@@ -65,7 +104,7 @@ static bool scene_setup(scene_t* scene)
static bool load_assets(scene_t* scene) static bool load_assets(scene_t* scene)
{ {
#if 0 #if 1
mesh_model_handle_t model_handle = mesh_load(SCENE_PATH, scene); mesh_model_handle_t model_handle = mesh_load(SCENE_PATH, scene);
if (!IS_VALID_HANDLE(model_handle)) if (!IS_VALID_HANDLE(model_handle))
{ {
@@ -211,6 +250,46 @@ static int run_main_loop(render_job_t* job, uint8_t aov_index)
return 0; return 0;
} }
static void save_render_output_png(const render_target_t* render_target, const char* output_path)
{
#ifdef SAVE_OUTPUT
if (render_target == NULL || render_target->buffer == NULL)
{
return;
}
uint8_t* png_buffer = (uint8_t*)malloc(render_target->width * render_target->height * 3);
if (png_buffer == NULL)
{
return;
}
for (uint32_t y = 0; y < render_target->height; y++)
{
for (uint32_t x = 0; x < render_target->width; x++)
{
vec4s pixel = render_target_get_pixel(render_target, x, y);
pixel = aces_tone_map(pixel);
pixel = gamma_correct(pixel, 2.2f);
size_t index = (size_t)(y * render_target->width + x) * 3;
png_buffer[index + 0] = (uint8_t)(fminf(fmaxf(pixel.x, 0.0f), 1.0f) * 255.0f);
png_buffer[index + 1] = (uint8_t)(fminf(fmaxf(pixel.y, 0.0f), 1.0f) * 255.0f);
png_buffer[index + 2] = (uint8_t)(fminf(fmaxf(pixel.z, 0.0f), 1.0f) * 255.0f);
}
}
FILE* fp = fopen(output_path, "wb");
if (fp != NULL)
{
svpng(fp, render_target->width, render_target->height, png_buffer, 0);
fclose(fp);
}
free(png_buffer);
#endif
}
// int main() // int main()
int WINAPI wWinMain(_In_ HINSTANCE hInstance, _In_opt_ HINSTANCE hPrevInstance, _In_ PWSTR pCmdLine, _In_ int nCmdShow) int WINAPI wWinMain(_In_ HINSTANCE hInstance, _In_opt_ HINSTANCE hPrevInstance, _In_ PWSTR pCmdLine, _In_ int nCmdShow)
{ {
@@ -226,12 +305,12 @@ int WINAPI wWinMain(_In_ HINSTANCE hInstance, _In_opt_ HINSTANCE hPrevInstance,
render_job_t* job = NULL; render_job_t* job = NULL;
rendering_config_t config = { rendering_config_t config = {
.width = 1920 / 2, .width = 1920 / 1,
.height = 1080 / 2, .height = 1080 / 1,
.sample_count = 16 * 4, .sample_count = 16 * 1,
.max_depth = 4, .max_depth = 4,
.bucket_size = 64, .bucket_size = 128,
.rendering_mode = RENDER_PROGRESSIVE, .rendering_mode = RENDER_TILE_BASED,
.aov_flags = AOV_BEAUTY, .aov_flags = AOV_BEAUTY,
}; };
@@ -244,6 +323,8 @@ int WINAPI wWinMain(_In_ HINSTANCE hInstance, _In_opt_ HINSTANCE hPrevInstance,
int result = run_main_loop(job, AOV_BEAUTY_INDEX); int result = run_main_loop(job, AOV_BEAUTY_INDEX);
save_render_output_png(job->aov_target[AOV_BEAUTY_INDEX], OUTPUT_PATH);
window_close(); window_close();
shutdown_renderer(job, &scene); shutdown_renderer(job, &scene);