#include "EntityCollision.hpp"
#include "WorldCollision.hpp"
#include "../app/Assets.hpp"
+#include "../geometry/const.hpp"
+#include "../geometry/distance.hpp"
#include "../graphics/Format.hpp"
#include "../graphics/Viewport.hpp"
#include <glm/gtx/euler_angles.hpp>
#include <glm/gtx/io.hpp>
#include <glm/gtx/quaternion.hpp>
+#include <glm/gtx/rotate_vector.hpp>
#include <glm/gtx/transform.hpp>
, id(-1)
, name("anonymous")
, bounds()
+, radius(0.0f)
, state()
, heading(0.0f, 0.0f, -1.0f)
, max_vel(5.0f)
}
void Entity::Position(const glm::ivec3 &c, const glm::vec3 &b) noexcept {
- state.chunk_pos = c;
- state.block_pos = b;
+ state.pos.chunk = c;
+ state.pos.block = b;
}
void Entity::Position(const glm::vec3 &pos) noexcept {
- state.block_pos = pos;
+ state.pos.block = pos;
state.AdjustPosition();
}
void Entity::SetHead(float p, float y) noexcept {
state.pitch = p;
state.yaw = y;
- // TODO: I feel like this could be delayed
- UpdateModel();
}
glm::mat4 Entity::Transform(const glm::ivec3 &reference) const noexcept {
- return glm::translate(glm::vec3((state.chunk_pos - reference) * Chunk::Extent())) * model_transform;
+ return glm::translate(glm::vec3((state.pos.chunk - reference) * ExactLocation::Extent())) * model_transform;
}
glm::mat4 Entity::ViewTransform(const glm::ivec3 &reference) const noexcept {
return Transform(reference) * view_transform;
}
-Ray Entity::Aim(const Chunk::Pos &chunk_offset) const noexcept {
+Ray Entity::Aim(const ExactLocation::Coarse &chunk_offset) const noexcept {
glm::mat4 transform = ViewTransform(chunk_offset);
return Ray{ glm::vec3(transform[3]), -glm::vec3(transform[2]) };
}
-void Entity::UpdateModel() noexcept {
- state.AdjustHeading();
- state.orient = glm::quat(glm::vec3(0.0f, state.yaw, 0.0f));
- if (model) {
- model.EyesState().orientation = glm::quat(glm::vec3(state.pitch, 0.0f, 0.0f));
- }
-}
-
void Entity::Update(float dt) {
UpdateTransforms();
UpdateHeading();
if (HasController()) {
GetController().Update(*this, dt);
}
+ UpdateModel(dt);
}
void Entity::UpdateTransforms() noexcept {
// model transform is the one given by current state
- model_transform = state.Transform(state.chunk_pos);
+ model_transform = state.Transform(state.pos.chunk);
// view transform is either the model's eyes transform or,
// should the entity have no model, the pitch (yaw already is
// in model transform)
if (model) {
view_transform = model.EyesTransform();
} else {
- view_transform = glm::eulerAngleX(state.pitch);
+ view_transform = toMat4(glm::quat(glm::vec3(state.pitch, state.yaw, 0.0f)));
}
}
}
}
+void Entity::UpdateModel(float dt) noexcept {
+ // first, sanitize the pitch and yaw fields of state (our input)
+ // those indicate the head orientation in the entity's local cosystem
+ state.AdjustHeading();
+ // TODO: this flickers horrible and also shouldn't be based on velocity, but on control force
+ //OrientBody(dt);
+ OrientHead(dt);
+}
+
+void Entity::OrientBody(float dt) noexcept {
+ // maximum body rotation per second (due to velocity orientation) (90°)
+ constexpr float max_body_turn_per_second = PI_0p5;
+ const float max_body_turn = max_body_turn_per_second * dt;
+ // minimum speed to apply body correction
+ constexpr float min_speed = 0.0625f;
+ // use local Y as up
+ const glm::vec3 up(model_transform[1]);
+ if (speed > min_speed) {
+ // check if our orientation and velocity are aligned
+ const glm::vec3 forward(-model_transform[2]);
+ // facing is local -Z rotated about local Y by yaw and transformed into world space
+ const glm::vec3 facing(normalize(glm::vec3(glm::vec4(rotateY(glm::vec3(0.0f, 0.0f, -1.0f), state.yaw), 0.0f) * transpose(model_transform))));
+ // only adjust if velocity isn't almost parallel to up
+ float vel_dot_up = dot(Velocity(), up);
+ if (std::abs(1.0f - std::abs(vel_dot_up)) > std::numeric_limits<float>::epsilon()) {
+ // get direction of velocity projected onto model plane
+ glm::vec3 direction(normalize(Velocity() - (Velocity() * vel_dot_up)));
+ // if velocity points away from our facing (with a little bias), flip it around
+ // (the entity is "walking backwards")
+ if (dot(facing, direction) < -0.1f) {
+ direction = -direction;
+ }
+ // calculate the difference between forward and direction
+ const float absolute_difference = std::acos(dot(forward, direction));
+ // if direction is clockwise with respect to up vector, invert the angle
+ const float relative_difference = dot(cross(forward, direction), up) < 0.0f
+ ? -absolute_difference
+ : absolute_difference;
+ // only correct by half the difference max
+ const float correction = glm::clamp(relative_difference * 0.5f, -max_body_turn, max_body_turn);
+ if (ID() == 1) {
+ std::cout << "orientation before: " << state.orient << std::endl;
+ std::cout << "up: " << up << std::endl;
+ std::cout << "forward: " << forward << std::endl;
+ std::cout << "facing: " << facing << std::endl;
+ std::cout << "direction: " << direction << std::endl;
+ std::cout << "difference: " << glm::degrees(relative_difference) << "°" << std::endl;
+ std::cout << "correction: " << glm::degrees(correction) << "°" << std::endl;
+ std::cout << std::endl;
+ }
+ // now rotate body by correction and head by -correction
+ state.orient = rotate(state.orient, correction, up);
+ state.yaw -= correction;
+ }
+ }
+}
+
+void Entity::OrientHead(float dt) noexcept {
+ // maximum yaw of head (90°)
+ constexpr float max_head_yaw = PI_0p5;
+ // use local Y as up
+ const glm::vec3 up(model_transform[1]);
+ // if yaw is bigger than max, rotate the body to accomodate
+ if (std::abs(state.yaw) > max_head_yaw) {
+ float deviation = state.yaw < 0.0f ? state.yaw + max_head_yaw : state.yaw - max_head_yaw;
+ // rotate the entity by deviation about local Y
+ state.orient = rotate(state.orient, deviation, up);
+ // and remove from head yaw
+ state.yaw -= deviation;
+ // shouldn't be necessary if max_head_yaw is < PI, but just to be sure :p
+ state.AdjustHeading();
+ }
+ // update model if any
+ if (model) {
+ model.EyesState().orientation = glm::quat(glm::vec3(state.pitch, state.yaw, 0.0f));
+ }
+}
+
EntityController::~EntityController() {
EntityState::EntityState()
-: chunk_pos(0)
-, block_pos(0.0f)
+: pos()
, velocity(0.0f)
, orient(1.0f, 0.0f, 0.0f, 0.0f)
, pitch(0.0f)
}
void EntityState::AdjustPosition() noexcept {
- while (block_pos.x >= Chunk::width) {
- block_pos.x -= Chunk::width;
- ++chunk_pos.x;
- }
- while (block_pos.x < 0) {
- block_pos.x += Chunk::width;
- --chunk_pos.x;
- }
- while (block_pos.y >= Chunk::height) {
- block_pos.y -= Chunk::height;
- ++chunk_pos.y;
- }
- while (block_pos.y < 0) {
- block_pos.y += Chunk::height;
- --chunk_pos.y;
- }
- while (block_pos.z >= Chunk::depth) {
- block_pos.z -= Chunk::depth;
- ++chunk_pos.z;
- }
- while (block_pos.z < 0) {
- block_pos.z += Chunk::depth;
- --chunk_pos.z;
- }
+ pos.Correct();
}
void EntityState::AdjustHeading() noexcept {
bool World::Intersection(
const Ray &ray,
const glm::mat4 &M,
- const Chunk::Pos &reference,
+ const ExactLocation::Coarse &reference,
WorldCollision &coll
) {
candidates.clear();
}
bool World::Intersection(const Entity &e, const EntityState &s, std::vector<WorldCollision> &col) {
- AABB box = e.Bounds();
- Chunk::Pos reference = s.chunk_pos;
+ // TODO: make special case for entities here and in Chunk::Intersection so entity's bounding radius
+ // doesn't have to be calculated over and over again (sqrt)
+ glm::ivec3 reference = s.pos.chunk;
glm::mat4 M = s.Transform(reference);
- return Intersection(box, M, reference, col);
+
+ bool any = false;
+ for (Chunk &cur_chunk : chunks) {
+ if (manhattan_radius(cur_chunk.Position() - reference) > 1) {
+ // chunk is not one of the 3x3x3 surrounding the entity
+ // since there's no entity which can extent over 16 blocks, they can be skipped
+ continue;
+ }
+ if (cur_chunk.Intersection(e, M, cur_chunk.Transform(reference), col)) {
+ any = true;
+ }
+ }
+ return any;
}
bool World::Intersection(
f.position = sixth * ((a.position + 2.0f * (b.position + c.position)) + d.position);
f.velocity = sixth * ((a.velocity + 2.0f * (b.velocity + c.velocity)) + d.velocity);
- state.block_pos += f.position * dt;
+ state.pos.block += f.position * dt;
state.velocity += f.velocity * dt;
state.AdjustPosition();
const EntityDerivative &delta
) {
EntityState next(cur);
- next.block_pos += delta.position * dt;
+ next.pos.block += delta.position * dt;
next.velocity += delta.velocity * dt;
next.AdjustPosition();