void WorldRenderer::RenderWorld(const corgi::CameraInterface& camera,
fplbase::Renderer& renderer, World* world) {
mat4 camera_transform = camera.GetTransformMatrix();
renderer.set_color(mathfu::kOnes4f);
renderer.DepthTest(true);
renderer.set_model_view_projection(camera_transform);
assert(textured_shadowed_shader_);
textured_shadowed_shader_->SetUniform("view_projection", camera_transform);
textured_shadowed_shader_->SetUniform("light_view_projection",
light_camera_.GetTransformMatrix());
textured_shadowed_shader_->SetUniform(
"shadow_intensity",
world->config->rendering_config()->shadow_intensity());
float shadow_intensity =
world->config->rendering_config()->shadow_intensity();
float ambient_intensity = 1.0f - shadow_intensity;
vec4 ambient =
vec4(ambient_intensity, ambient_intensity, ambient_intensity, 1.0f);
float diffuse_intensity = shadow_intensity;
vec4 diffuse =
vec4(diffuse_intensity, diffuse_intensity, diffuse_intensity, 1.0f);
textured_lit_cutout_shader_->SetUniform("ambient_material", ambient);
textured_lit_cutout_shader_->SetUniform("diffuse_material", diffuse);
textured_lit_shader_->SetUniform("ambient_material", ambient);
textured_lit_shader_->SetUniform("diffuse_material", diffuse);
textured_lit_bank_shader_->SetUniform("ambient_material", ambient);
textured_lit_bank_shader_->SetUniform("diffuse_material", diffuse);
textured_skinned_lit_shader_->SetUniform("ambient_material", ambient);
textured_skinned_lit_shader_->SetUniform("diffuse_material", diffuse);
float texture_repeats = world->config->river_config()->texture_repeats();
float river_offset = world->river_component.river_offset();
river_shader_->SetUniform("river_offset", river_offset);
river_shader_->SetUniform("texture_repeats", texture_repeats);
SetFogUniforms(textured_shadowed_shader_, world);
SetFogUniforms(textured_lit_shader_, world);
SetFogUniforms(textured_lit_bank_shader_, world);
SetFogUniforms(textured_skinned_lit_shader_, world);
shadow_map_.BindAsTexture(kShadowMapTextureID);
if (!world->skip_rendermesh_rendering) {
for (int pass = 0; pass < corgi::RenderPass_Count; pass++) {
world->render_mesh_component.RenderPass(pass, camera, renderer);
}
}
if (world->draw_debug_physics) {
world->physics_component.DebugDrawWorld(&renderer, camera_transform);
}
}
void WorldRenderer::CreateShadowMap(const corgi::CameraInterface& camera,
fplbase::Renderer& renderer, World* world) {
float shadow_map_resolution = static_cast<float>(
world->config->rendering_config()->shadow_map_resolution());
float shadow_map_zoom = world->config->rendering_config()->shadow_map_zoom();
float shadow_map_offset =
world->config->rendering_config()->shadow_map_offset();
vec3 light_position =
LoadVec3(world->config->rendering_config()->light_position());
SetLightPosition(light_position);
light_camera_.set_viewport_angle(kShadowMapViewportAngle / shadow_map_zoom);
light_camera_.set_viewport_resolution(
vec2(shadow_map_resolution, shadow_map_resolution));
vec3 light_camera_focus =
camera.position() + camera.facing() * shadow_map_offset;
light_camera_focus.z() = 0;
vec3 light_facing = light_camera_focus - light_camera_.position();
light_camera_.set_facing(light_facing.Normalized());
// Shadow map needs to be cleared to near-white, since that's
// the maximum (furthest) depth.
shadow_map_.SetAsRenderTarget();
renderer.ClearFrameBuffer(kShadowMapClearColor);
renderer.SetCulling(fplbase::Renderer::kCullBack);
depth_shader_->Set(renderer);
// Generate the shadow map:
// TODO - modify this so that shadowcast is its own render pass
for (int pass = 0; pass < corgi::RenderPass_Count; pass++) {
world->render_mesh_component.RenderPass(pass, light_camera_,
renderer, depth_shader_);
}
}
void TouchscreenButton::DebugRender(const vec3& position,
const vec3& texture_size,
fplbase::Renderer& renderer) const {
#if defined(DEBUG_RENDER_BOUNDS)
if (debug_shader_ && draw_bounds_) {
const vec2 window_size = vec2(renderer.window_size());
static const float kButtonZDepth = 0.0f;
static const fplbase::Attribute kFormat[] = {fplbase::kPosition3f,
fplbase::kEND
};
static const unsigned short kIndices[] = {0, 1, 1, 3, 2, 3, 2, 0};
const vec3 bottom_left = position - (texture_size / 2.0f);
const vec3 top_right = position + (texture_size / 2.0f);
// vertex format is [x, y, z]
float vertices[] = {
bottom_left.x(), bottom_left.y(), bottom_left.z(), top_right.x(),
bottom_left.y(), bottom_left.z(), bottom_left.x(), top_right.y(),
top_right.z(), top_right.x(), top_right.y(), top_right.z(),
};
renderer.set_color(vec4(1.0f, 0.0f, 1.0f, 1.0f));
debug_shader_->Set(renderer);
fplbase::Mesh::RenderArray(fplbase::Mesh::kLines, 8,
kFormat, sizeof(float) * 3,
reinterpret_cast<const char*>(vertices),
kIndices);
renderer.set_color(vec4(1.0f, 1.0f, 0.0f, 1.0f));
debug_shader_->Set(renderer);
static unsigned short indicesButtonDef[] = {1, 0, 1, 2, 2, 3, 3, 0};
float verticesButtonDef[] = {
button_def()->top_left()->x() * window_size.x(),
button_def()->top_left()->y() * window_size.y(),
kButtonZDepth,
button_def()->top_left()->x() * window_size.x(),
button_def()->bottom_right()->y() * window_size.y(),
kButtonZDepth,
button_def()->bottom_right()->x() * window_size.x(),
button_def()->bottom_right()->y() * window_size.y(),
kButtonZDepth,
button_def()->bottom_right()->x() * window_size.x(),
button_def()->top_left()->y() * window_size.y(),
kButtonZDepth,
};
fplbase::Mesh::RenderArray(fplbase::Mesh::kLines, 8, kFormat,
sizeof(float) * 3,
reinterpret_cast<const char*>(verticesButtonDef),
indicesButtonDef);
}
#else
(void)position;
(void)texture_size;
(void)renderer;
#endif // DEBUG_RENDER_BOUNDS
}
void WorldRenderer::CreateShadowMap(const corgi::CameraInterface &camera,
fplbase::Renderer &renderer, World *world) {
PushDebugMarker("CreateShadowMap");
PushDebugMarker("Setup");
float shadow_map_resolution = static_cast<float>(
world->config->rendering_config()->shadow_map_resolution());
float shadow_map_zoom = world->config->rendering_config()->shadow_map_zoom();
float shadow_map_offset =
world->config->rendering_config()->shadow_map_offset();
LightComponent *light_component =
world->entity_manager.GetComponent<LightComponent>();
const EntityRef &main_light_entity = light_component->begin()->entity;
const TransformData *light_transform =
world->entity_manager.GetComponentData<TransformData>(main_light_entity);
vec3 light_position = light_transform->position;
SetLightPosition(light_position);
float viewport_angle =
world->config->rendering_config()->shadow_map_viewport_angle() *
kDegreesToRadians;
light_camera_.set_viewport_angle(viewport_angle / shadow_map_zoom);
light_camera_.set_viewport_resolution(
vec2(shadow_map_resolution, shadow_map_resolution));
vec3 light_camera_focus =
camera.position() + camera.facing() * shadow_map_offset;
light_camera_focus.z = 0;
vec3 light_facing = light_camera_focus - light_camera_.position();
light_camera_.set_facing(light_facing.Normalized());
// Shadow map needs to be cleared to near-white, since that's
// the maximum (furthest) depth.
shadow_map_.SetAsRenderTarget();
renderer.ClearFrameBuffer(kShadowMapClearColor);
renderer.SetCulling(fplbase::kCullingModeBack);
depth_shader_->Set(renderer);
depth_skinned_shader_->Set(renderer);
// Generate the shadow map:
// TODO - modify this so that shadowcast is its own render pass
PopDebugMarker(); // Setup
for (int pass = 0; pass < corgi::RenderPass_Count; pass++) {
PushDebugMarker("RenderPass");
world->render_mesh_component.RenderPass(pass, light_camera_, renderer,
ShaderIndex_Depth);
PopDebugMarker();
}
fplbase::RenderTarget::ScreenRenderTarget(renderer).SetAsRenderTarget();
PopDebugMarker(); // CreateShadowMap
}
void TouchscreenButton::Render(fplbase::Renderer& renderer) {
static const float kButtonZDepth = 0.0f;
if (!is_visible_) {
return;
}
renderer.set_color(vec4(color_));
auto mat = (button_.is_down() && down_material_ != nullptr)
? down_material_
: up_current_ < up_materials_.size()
? up_materials_[up_current_]
: nullptr;
if (!mat) return; // This is an invisible button.
const vec2 window_size = vec2(renderer.window_size());
const float texture_scale =
window_size.y() * one_over_cannonical_window_height_;
vec2 base_size = LoadVec2(
is_highlighted_ ? button_def_->draw_scale_highlighted()
: (button_.is_down() ? button_def_->draw_scale_pressed()
: button_def_->draw_scale_normal()));
auto pulse = sinf(static_cast<float>(elapsed_time_) / 100.0f);
if (is_highlighted_) {
base_size += mathfu::kOnes2f * pulse * 0.05f;
}
vec3 texture_size =
texture_scale * vec3(mat->textures()[0]->size().x() * base_size.x(),
-mat->textures()[0]->size().y() * base_size.y(), 0);
vec3 position = vec3(button_def()->texture_position()->x() * window_size.x(),
button_def()->texture_position()->y() * window_size.y(),
kButtonZDepth);
renderer.set_color(mathfu::kOnes4f);
if (is_active_ || inactive_shader_ == nullptr) {
shader_->Set(renderer);
} else {
inactive_shader_->Set(renderer);
}
mat->Set(renderer);
fplbase::Mesh::RenderAAQuadAlongX(position - (texture_size / 2.0f),
position + (texture_size / 2.0f), vec2(0, 1),
vec2(1, 0));
#if defined(DEBUG_RENDER_BOUNDS)
DebugRender(position, texture_size, renderer);
#endif // DEBUG_RENDER_BOUNDS
}
static void RenderSettingsGear(fplbase::Renderer& renderer, World* world) {
vec2i res = renderer.window_size();
renderer.set_model_view_projection(mathfu::mat4::Ortho(
0.0f, static_cast<float>(res.x), static_cast<float>(res.y), 0.0f,
-1.0f, 1.0f));
renderer.set_color(mathfu::kOnes4f);
auto shader = world->asset_manager->LoadShader("shaders/textured");
world->cardboard_settings_gear->Set(renderer);
shader->Set(renderer);
fplbase::Mesh::RenderAAQuadAlongX(
vec3((res.x - kGearSize) / 2.0f, res.y - kGearSize, 0.0f),
vec3((res.x + kGearSize) / 2.0f, res.y, 0.0f));
}
void RenderMeshComponent::RenderAllEntities(fplbase::Renderer& renderer,
const CameraInterface& camera) {
// Make sure we only draw the front-facing polygons:
renderer.SetCulling(fplbase::Renderer::kCullBack);
// Render the actual game:
for (int pass = 0; pass < RenderPass_Count; pass++) {
RenderPass(pass, camera, renderer);
}
}
void StaticImage::Render(fplbase::Renderer& renderer) {
if (!Valid()) return;
if (!is_visible_) return;
renderer.set_color(vec4(color_));
auto material = materials_[current_material_index_];
const vec2 window_size = vec2(renderer.window_size());
const float texture_scale =
window_size.y() * one_over_cannonical_window_height_;
const vec2 texture_size =
texture_scale * vec2(material->textures()[0]->size()) * vec2(scale_);
const vec2 position_percent = vec2(texture_position_);
const vec2 position = window_size * position_percent;
const vec3 position3d(position.x(), position.y(), image_def_->z_depth());
const vec3 texture_size3d(texture_size.x(), -texture_size.y(), 0.0f);
shader_->Set(renderer);
material->Set(renderer);
fplbase::Mesh::RenderAAQuadAlongX(position3d - texture_size3d * 0.5f,
position3d + texture_size3d * 0.5f, vec2(0, 1),
vec2(1, 0));
}
// Draw the shadow map in the world, so we can see it.
void WorldRenderer::DebugShowShadowMap(const corgi::CameraInterface& camera,
fplbase::Renderer& renderer) {
fplbase::RenderTarget::ScreenRenderTarget(renderer).SetAsRenderTarget();
static const mat4 kDebugTextureWorldTransform =
mat4::FromScaleVector(mathfu::vec3(10.0f, 10.0f, 10.0f));
const mat4 mvp = camera.GetTransformMatrix() * kDebugTextureWorldTransform;
const mat4 world_matrix_inverse = kDebugTextureWorldTransform.Inverse();
renderer.set_camera_pos(world_matrix_inverse * camera.position());
renderer.set_light_pos(world_matrix_inverse * light_camera_.position());
renderer.set_model_view_projection(mvp);
renderer.set_color(vec4(1.0f, 1.0f, 1.0f, 1.0f));
shadow_map_.BindAsTexture(0);
textured_shader_->Set(renderer);
// Render a large quad in the world, with the shadowmap texture on it:
fplbase::Mesh::RenderAAQuadAlongX(vec3(0.0f, 0.0f, 0.0f),
vec3(10.0f, 0.0f, 10.0f),
vec2(1.0f, 0.0f), vec2(0.0f, 1.0f));
}
void RenderWorld(fplbase::Renderer& renderer, World* world, Camera& camera,
Camera* cardboard_camera, fplbase::InputSystem* input_system) {
vec2 window_size = vec2(renderer.window_size());
world->river_component.UpdateRiverMeshes();
if (world->rendering_mode() == kRenderingStereoscopic) {
window_size.x = window_size.x / 2;
cardboard_camera->set_viewport_resolution(window_size);
}
camera.set_viewport_resolution(window_size);
if (world->rendering_mode() == kRenderingStereoscopic) {
// This takes care of setting/clearing the framebuffer for us.
RenderStereoscopic(renderer, world, camera, cardboard_camera, input_system);
} else {
// Always clear the framebuffer, even though we overwrite it with the
// skybox, since it's a speedup on tile-based architectures, see .e.g.:
// http://www.seas.upenn.edu/~pcozzi/OpenGLInsights/OpenGLInsights-TileBasedArchitectures.pdf
renderer.ClearFrameBuffer(mathfu::kZeros4f);
if (world->RenderingOptionEnabled(kShadowEffect)) {
world->world_renderer->RenderShadowMap(camera, renderer, world);
}
world->world_renderer->RenderWorld(camera, renderer, world);
}
}
void WorldRenderer::RenderWorld(const corgi::CameraInterface &camera,
fplbase::Renderer &renderer, World *world) {
PushDebugMarker("Render World");
PushDebugMarker("Scene Setup");
if (world->RenderingOptionsDirty()) {
RefreshGlobalShaderDefines(world);
}
mat4 camera_transform = camera.GetTransformMatrix();
renderer.set_color(mathfu::kOnes4f);
renderer.SetDepthFunction(fplbase::kDepthFunctionLess);
renderer.set_model_view_projection(camera_transform);
float texture_repeats =
world->CurrentLevel()->river_config()->texture_repeats();
float river_offset = world->river_component.river_offset();
if (world->RenderingOptionEnabled(kShadowEffect)) {
world->asset_manager->ForEachShaderWithDefine(
kDefinesText[kShadowEffect], [&](fplbase::Shader *shader) {
shader->SetUniform("view_projection", camera_transform);
shader->SetUniform("light_view_projection",
light_camera_.GetTransformMatrix());
});
}
world->asset_manager->ForEachShaderWithDefine(
"WATER", [&](fplbase::Shader *shader) {
shader->SetUniform("river_offset", river_offset);
shader->SetUniform("texture_repeats", texture_repeats);
});
world->asset_manager->ForEachShaderWithDefine(
kDefinesText[kPhongShading],
[&](fplbase::Shader *shader) { SetLightingUniforms(shader, world); });
world->asset_manager->ForEachShaderWithDefine(
"FOG_EFFECT",
[&](fplbase::Shader *shader) { SetFogUniforms(shader, world); });
shadow_map_.BindAsTexture(kShadowMapTextureID);
PopDebugMarker(); // Scene Setup
if (!world->skip_rendermesh_rendering) {
for (int pass = 0; pass < corgi::RenderPass_Count; pass++) {
PushDebugMarker("RenderPass");
world->render_mesh_component.RenderPass(pass, camera, renderer);
PopDebugMarker();
}
}
if (world->draw_debug_physics) {
PushDebugMarker("Debug Draw World");
world->physics_component.DebugDrawWorld(&renderer, camera_transform);
PopDebugMarker();
}
PushDebugMarker("Text");
world->render_3d_text_component.RenderAllEntities(camera);
PopDebugMarker();
PopDebugMarker(); // Render World
}
static float AspectRatio(const fplbase::Renderer& renderer) {
return static_cast<float>(renderer.window_size().x) /
renderer.window_size().y;
}
// Render a single render-pass, by ID.
void RenderMeshComponent::RenderPass(int pass_id, const CameraInterface& camera,
fplbase::Renderer& renderer,
const fplbase::Shader* shader_override) {
mat4 camera_vp = camera.GetTransformMatrix();
for (size_t i = 0; i < pass_render_list_[pass_id].size(); i++) {
EntityRef& entity = pass_render_list_[pass_id][i].entity;
RenderMeshData* rendermesh_data = Data<RenderMeshData>(entity);
TransformData* transform_data = Data<TransformData>(entity);
AnimationData* anim_data = Data<AnimationData>(entity);
// TODO: anim_data will set uniforms for an array of matricies. Each
// matrix represents one bone position.
const bool has_anim = anim_data != nullptr && anim_data->motivator.Valid();
const int num_mesh_bones = rendermesh_data->mesh->num_bones();
const int num_anim_bones =
has_anim ? anim_data->motivator.DefiningAnim()->NumBones() : 0;
const bool has_one_bone_anim =
has_anim && (num_mesh_bones <= 1 || num_anim_bones == 1);
const mat4 world_transform =
has_one_bone_anim
? transform_data->world_transform *
mat4::FromAffineTransform(
anim_data->motivator.GlobalTransforms()[0])
: transform_data->world_transform;
const mat4 mvp = camera_vp * world_transform;
const mat4 world_matrix_inverse = world_transform.Inverse();
renderer.set_light_pos(world_matrix_inverse * light_position_);
renderer.set_color(rendermesh_data->tint);
renderer.set_model(world_transform);
// If the mesh has a skeleton, we need to update the bone positions.
// The positions are normally supplied by the animation, but if they are
// not, use the default pose in the RenderMesh.
if (num_mesh_bones > 1) {
const bool use_default_pose =
num_anim_bones != num_mesh_bones || rendermesh_data->default_pose;
const mathfu::AffineTransform* bone_transforms =
use_default_pose ? rendermesh_data->mesh->bone_global_transforms()
: anim_data->motivator.GlobalTransforms();
rendermesh_data->mesh->GatherShaderTransforms(
bone_transforms, rendermesh_data->shader_transforms);
renderer.SetBoneTransforms(rendermesh_data->shader_transforms,
rendermesh_data->num_shader_transforms);
}
if (!camera.IsStereo()) {
renderer.set_camera_pos(world_matrix_inverse * camera.position());
renderer.set_model_view_projection(mvp);
if (!shader_override && rendermesh_data->shader) {
rendermesh_data->shader->Set(renderer);
} else {
shader_override->Set(renderer);
}
rendermesh_data->mesh->Render(renderer);
} else {
const fplbase::Shader* shader = nullptr;
if (!shader_override && rendermesh_data->shader) {
shader = rendermesh_data->shader;
} else {
shader = shader_override;
}
mathfu::vec4i viewport[2] = {camera.viewport(0), camera.viewport(1)};
mat4 camera_vp_stereo = camera.GetTransformMatrix(1);
mat4 mvp_matrices[2] = {mvp, camera_vp_stereo * world_transform};
vec3 camera_positions[2] = {world_matrix_inverse * camera.position(0),
world_matrix_inverse * camera.position(1)};
rendermesh_data->mesh->RenderStereo(renderer, shader, viewport,
mvp_matrices, camera_positions);
}
}
}
