godot/scene/resources/curve.cpp

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2014-02-10 01:10:30 +00:00
/*************************************************************************/
/* curve.cpp */
/*************************************************************************/
/* This file is part of: */
/* GODOT ENGINE */
/* https://godotengine.org */
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/*************************************************************************/
/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
/* Copyright (c) 2014-2022 Godot Engine contributors (cf. AUTHORS.md). */
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/* */
/* Permission is hereby granted, free of charge, to any person obtaining */
/* a copy of this software and associated documentation files (the */
/* "Software"), to deal in the Software without restriction, including */
/* without limitation the rights to use, copy, modify, merge, publish, */
/* distribute, sublicense, and/or sell copies of the Software, and to */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions: */
/* */
/* The above copyright notice and this permission notice shall be */
/* included in all copies or substantial portions of the Software. */
/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
/* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */
/* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */
/* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */
/* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */
/*************************************************************************/
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#include "curve.h"
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#include "core/core_string_names.h"
#include "core/math/math_funcs.h"
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const char *Curve::SIGNAL_RANGE_CHANGED = "range_changed";
Curve::Curve() {
}
void Curve::set_point_count(int p_count) {
ERR_FAIL_COND(p_count < 0);
if (_points.size() >= p_count) {
_points.resize(p_count);
mark_dirty();
} else {
for (int i = p_count - _points.size(); i > 0; i--) {
_add_point(Vector2());
}
}
notify_property_list_changed();
}
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int Curve::_add_point(Vector2 p_position, real_t p_left_tangent, real_t p_right_tangent, TangentMode p_left_mode, TangentMode p_right_mode) {
// Add a point and preserve order
// Curve bounds is in 0..1
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if (p_position.x > MAX_X) {
p_position.x = MAX_X;
} else if (p_position.x < MIN_X) {
p_position.x = MIN_X;
}
int ret = -1;
if (_points.size() == 0) {
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_points.push_back(Point(p_position, p_left_tangent, p_right_tangent, p_left_mode, p_right_mode));
ret = 0;
} else if (_points.size() == 1) {
// TODO Is the `else` able to handle this block already?
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real_t diff = p_position.x - _points[0].position.x;
if (diff > 0) {
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_points.push_back(Point(p_position, p_left_tangent, p_right_tangent, p_left_mode, p_right_mode));
ret = 1;
} else {
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_points.insert(0, Point(p_position, p_left_tangent, p_right_tangent, p_left_mode, p_right_mode));
ret = 0;
}
} else {
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int i = get_index(p_position.x);
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if (i == 0 && p_position.x < _points[0].position.x) {
// Insert before anything else
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_points.insert(0, Point(p_position, p_left_tangent, p_right_tangent, p_left_mode, p_right_mode));
ret = 0;
} else {
// Insert between i and i+1
++i;
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_points.insert(i, Point(p_position, p_left_tangent, p_right_tangent, p_left_mode, p_right_mode));
ret = i;
}
}
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update_auto_tangents(ret);
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mark_dirty();
return ret;
}
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int Curve::add_point(Vector2 p_position, real_t p_left_tangent, real_t p_right_tangent, TangentMode p_left_mode, TangentMode p_right_mode) {
int ret = _add_point(p_position, p_left_tangent, p_right_tangent, p_left_mode, p_right_mode);
notify_property_list_changed();
return ret;
}
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int Curve::get_index(real_t p_offset) const {
// Lower-bound float binary search
int imin = 0;
int imax = _points.size() - 1;
while (imax - imin > 1) {
int m = (imin + imax) / 2;
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real_t a = _points[m].position.x;
real_t b = _points[m + 1].position.x;
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if (a < p_offset && b < p_offset) {
imin = m;
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} else if (a > p_offset) {
imax = m;
} else {
return m;
}
}
// Will happen if the offset is out of bounds
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if (p_offset > _points[imax].position.x) {
return imax;
}
return imin;
}
void Curve::clean_dupes() {
bool dirty = false;
for (int i = 1; i < _points.size(); ++i) {
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real_t diff = _points[i - 1].position.x - _points[i].position.x;
if (diff <= CMP_EPSILON) {
_points.remove_at(i);
--i;
dirty = true;
}
}
if (dirty) {
mark_dirty();
}
}
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void Curve::set_point_left_tangent(int p_index, real_t p_tangent) {
ERR_FAIL_INDEX(p_index, _points.size());
_points.write[p_index].left_tangent = p_tangent;
_points.write[p_index].left_mode = TANGENT_FREE;
mark_dirty();
}
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void Curve::set_point_right_tangent(int p_index, real_t p_tangent) {
ERR_FAIL_INDEX(p_index, _points.size());
_points.write[p_index].right_tangent = p_tangent;
_points.write[p_index].right_mode = TANGENT_FREE;
mark_dirty();
}
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void Curve::set_point_left_mode(int p_index, TangentMode p_mode) {
ERR_FAIL_INDEX(p_index, _points.size());
_points.write[p_index].left_mode = p_mode;
if (p_index > 0) {
if (p_mode == TANGENT_LINEAR) {
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Vector2 v = (_points[p_index - 1].position - _points[p_index].position).normalized();
_points.write[p_index].left_tangent = v.y / v.x;
}
}
mark_dirty();
}
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void Curve::set_point_right_mode(int p_index, TangentMode p_mode) {
ERR_FAIL_INDEX(p_index, _points.size());
_points.write[p_index].right_mode = p_mode;
if (p_index + 1 < _points.size()) {
if (p_mode == TANGENT_LINEAR) {
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Vector2 v = (_points[p_index + 1].position - _points[p_index].position).normalized();
_points.write[p_index].right_tangent = v.y / v.x;
}
}
mark_dirty();
}
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real_t Curve::get_point_left_tangent(int p_index) const {
ERR_FAIL_INDEX_V(p_index, _points.size(), 0);
return _points[p_index].left_tangent;
}
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real_t Curve::get_point_right_tangent(int p_index) const {
ERR_FAIL_INDEX_V(p_index, _points.size(), 0);
return _points[p_index].right_tangent;
}
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Curve::TangentMode Curve::get_point_left_mode(int p_index) const {
ERR_FAIL_INDEX_V(p_index, _points.size(), TANGENT_FREE);
return _points[p_index].left_mode;
}
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Curve::TangentMode Curve::get_point_right_mode(int p_index) const {
ERR_FAIL_INDEX_V(p_index, _points.size(), TANGENT_FREE);
return _points[p_index].right_mode;
}
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void Curve::_remove_point(int p_index) {
ERR_FAIL_INDEX(p_index, _points.size());
_points.remove_at(p_index);
mark_dirty();
}
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void Curve::remove_point(int p_index) {
_remove_point(p_index);
notify_property_list_changed();
}
void Curve::clear_points() {
_points.clear();
mark_dirty();
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notify_property_list_changed();
}
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void Curve::set_point_value(int p_index, real_t p_position) {
ERR_FAIL_INDEX(p_index, _points.size());
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_points.write[p_index].position.y = p_position;
update_auto_tangents(p_index);
mark_dirty();
}
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int Curve::set_point_offset(int p_index, real_t p_offset) {
ERR_FAIL_INDEX_V(p_index, _points.size(), -1);
Point p = _points[p_index];
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_remove_point(p_index);
int i = _add_point(Vector2(p_offset, p.position.y));
_points.write[i].left_tangent = p.left_tangent;
_points.write[i].right_tangent = p.right_tangent;
_points.write[i].left_mode = p.left_mode;
_points.write[i].right_mode = p.right_mode;
if (p_index != i) {
update_auto_tangents(p_index);
}
update_auto_tangents(i);
return i;
}
Vector2 Curve::get_point_position(int p_index) const {
ERR_FAIL_INDEX_V(p_index, _points.size(), Vector2(0, 0));
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return _points[p_index].position;
}
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Curve::Point Curve::get_point(int p_index) const {
ERR_FAIL_INDEX_V(p_index, _points.size(), Point());
return _points[p_index];
}
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void Curve::update_auto_tangents(int p_index) {
Point &p = _points.write[p_index];
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if (p_index > 0) {
if (p.left_mode == TANGENT_LINEAR) {
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Vector2 v = (_points[p_index - 1].position - p.position).normalized();
p.left_tangent = v.y / v.x;
}
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if (_points[p_index - 1].right_mode == TANGENT_LINEAR) {
Vector2 v = (_points[p_index - 1].position - p.position).normalized();
_points.write[p_index - 1].right_tangent = v.y / v.x;
}
}
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if (p_index + 1 < _points.size()) {
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if (p.right_mode == TANGENT_LINEAR) {
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Vector2 v = (_points[p_index + 1].position - p.position).normalized();
p.right_tangent = v.y / v.x;
}
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if (_points[p_index + 1].left_mode == TANGENT_LINEAR) {
Vector2 v = (_points[p_index + 1].position - p.position).normalized();
_points.write[p_index + 1].left_tangent = v.y / v.x;
}
}
}
#define MIN_Y_RANGE 0.01
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void Curve::set_min_value(real_t p_min) {
if (_minmax_set_once & 0b11 && p_min > _max_value - MIN_Y_RANGE) {
_min_value = _max_value - MIN_Y_RANGE;
} else {
_minmax_set_once |= 0b10; // first bit is "min set"
_min_value = p_min;
}
// Note: min and max are indicative values,
// it's still possible that existing points are out of range at this point.
emit_signal(SNAME(SIGNAL_RANGE_CHANGED));
}
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void Curve::set_max_value(real_t p_max) {
if (_minmax_set_once & 0b11 && p_max < _min_value + MIN_Y_RANGE) {
_max_value = _min_value + MIN_Y_RANGE;
} else {
_minmax_set_once |= 0b01; // second bit is "max set"
_max_value = p_max;
}
emit_signal(SNAME(SIGNAL_RANGE_CHANGED));
}
real_t Curve::sample(real_t p_offset) const {
if (_points.size() == 0) {
return 0;
}
if (_points.size() == 1) {
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return _points[0].position.y;
}
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int i = get_index(p_offset);
if (i == _points.size() - 1) {
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return _points[i].position.y;
}
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real_t local = p_offset - _points[i].position.x;
if (i == 0 && local <= 0) {
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return _points[0].position.y;
}
return sample_local_nocheck(i, local);
}
real_t Curve::sample_local_nocheck(int p_index, real_t p_local_offset) const {
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const Point a = _points[p_index];
const Point b = _points[p_index + 1];
/* Cubic bézier
*
* ac-----bc
* / \
* / \ Here with a.right_tangent > 0
* / \ and b.left_tangent < 0
* / \
* a b
*
* |-d1--|-d2--|-d3--|
*
* d1 == d2 == d3 == d / 3
*/
// Control points are chosen at equal distances
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real_t d = b.position.x - a.position.x;
if (Math::is_zero_approx(d)) {
return b.position.y;
}
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p_local_offset /= d;
d /= 3.0;
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real_t yac = a.position.y + d * a.right_tangent;
real_t ybc = b.position.y - d * b.left_tangent;
real_t y = Math::bezier_interpolate(a.position.y, yac, ybc, b.position.y, p_local_offset);
return y;
}
void Curve::mark_dirty() {
_baked_cache_dirty = true;
emit_signal(CoreStringNames::get_singleton()->changed);
}
Array Curve::get_data() const {
Array output;
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const unsigned int ELEMS = 5;
output.resize(_points.size() * ELEMS);
for (int j = 0; j < _points.size(); ++j) {
const Point p = _points[j];
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int i = j * ELEMS;
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output[i] = p.position;
output[i + 1] = p.left_tangent;
output[i + 2] = p.right_tangent;
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output[i + 3] = p.left_mode;
output[i + 4] = p.right_mode;
}
return output;
}
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void Curve::set_data(const Array p_input) {
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const unsigned int ELEMS = 5;
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ERR_FAIL_COND(p_input.size() % ELEMS != 0);
_points.clear();
// Validate input
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for (int i = 0; i < p_input.size(); i += ELEMS) {
ERR_FAIL_COND(p_input[i].get_type() != Variant::VECTOR2);
ERR_FAIL_COND(!p_input[i + 1].is_num());
ERR_FAIL_COND(p_input[i + 2].get_type() != Variant::FLOAT);
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ERR_FAIL_COND(p_input[i + 3].get_type() != Variant::INT);
int left_mode = p_input[i + 3];
ERR_FAIL_COND(left_mode < 0 || left_mode >= TANGENT_MODE_COUNT);
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ERR_FAIL_COND(p_input[i + 4].get_type() != Variant::INT);
int right_mode = p_input[i + 4];
ERR_FAIL_COND(right_mode < 0 || right_mode >= TANGENT_MODE_COUNT);
}
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_points.resize(p_input.size() / ELEMS);
for (int j = 0; j < _points.size(); ++j) {
Point &p = _points.write[j];
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int i = j * ELEMS;
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p.position = p_input[i];
p.left_tangent = p_input[i + 1];
p.right_tangent = p_input[i + 2];
int left_mode = p_input[i + 3];
int right_mode = p_input[i + 4];
p.left_mode = (TangentMode)left_mode;
p.right_mode = (TangentMode)right_mode;
}
mark_dirty();
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notify_property_list_changed();
}
void Curve::bake() {
_baked_cache.clear();
_baked_cache.resize(_bake_resolution);
for (int i = 1; i < _bake_resolution - 1; ++i) {
real_t x = i / static_cast<real_t>(_bake_resolution);
real_t y = sample(x);
_baked_cache.write[i] = y;
}
if (_points.size() != 0) {
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_baked_cache.write[0] = _points[0].position.y;
_baked_cache.write[_baked_cache.size() - 1] = _points[_points.size() - 1].position.y;
}
_baked_cache_dirty = false;
}
void Curve::set_bake_resolution(int p_resolution) {
ERR_FAIL_COND(p_resolution < 1);
ERR_FAIL_COND(p_resolution > 1000);
_bake_resolution = p_resolution;
_baked_cache_dirty = true;
}
real_t Curve::sample_baked(real_t p_offset) const {
if (_baked_cache_dirty) {
// Last-second bake if not done already
const_cast<Curve *>(this)->bake();
}
// Special cases if the cache is too small
if (_baked_cache.size() == 0) {
if (_points.size() == 0) {
return 0;
}
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return _points[0].position.y;
} else if (_baked_cache.size() == 1) {
return _baked_cache[0];
}
// Get interpolation index
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real_t fi = p_offset * _baked_cache.size();
int i = Math::floor(fi);
if (i < 0) {
i = 0;
fi = 0;
} else if (i >= _baked_cache.size()) {
i = _baked_cache.size() - 1;
fi = 0;
}
// Sample
if (i + 1 < _baked_cache.size()) {
real_t t = fi - i;
return Math::lerp(_baked_cache[i], _baked_cache[i + 1], t);
} else {
return _baked_cache[_baked_cache.size() - 1];
}
}
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void Curve::ensure_default_setup(real_t p_min, real_t p_max) {
if (_points.size() == 0 && _min_value == 0 && _max_value == 1) {
add_point(Vector2(0, 1));
add_point(Vector2(1, 1));
set_min_value(p_min);
set_max_value(p_max);
}
}
bool Curve::_set(const StringName &p_name, const Variant &p_value) {
Vector<String> components = String(p_name).split("/", true, 2);
if (components.size() >= 2 && components[0].begins_with("point_") && components[0].trim_prefix("point_").is_valid_int()) {
int point_index = components[0].trim_prefix("point_").to_int();
String property = components[1];
if (property == "position") {
Vector2 position = p_value.operator Vector2();
set_point_offset(point_index, position.x);
set_point_value(point_index, position.y);
return true;
} else if (property == "left_tangent") {
set_point_left_tangent(point_index, p_value);
return true;
} else if (property == "left_mode") {
int mode = p_value;
set_point_left_mode(point_index, (TangentMode)mode);
return true;
} else if (property == "right_tangent") {
set_point_right_tangent(point_index, p_value);
return true;
} else if (property == "right_mode") {
int mode = p_value;
set_point_right_mode(point_index, (TangentMode)mode);
return true;
}
}
return false;
}
bool Curve::_get(const StringName &p_name, Variant &r_ret) const {
Vector<String> components = String(p_name).split("/", true, 2);
if (components.size() >= 2 && components[0].begins_with("point_") && components[0].trim_prefix("point_").is_valid_int()) {
int point_index = components[0].trim_prefix("point_").to_int();
String property = components[1];
if (property == "position") {
r_ret = get_point_position(point_index);
return true;
} else if (property == "left_tangent") {
r_ret = get_point_left_tangent(point_index);
return true;
} else if (property == "left_mode") {
r_ret = get_point_left_mode(point_index);
return true;
} else if (property == "right_tangent") {
r_ret = get_point_right_tangent(point_index);
return true;
} else if (property == "right_mode") {
r_ret = get_point_right_mode(point_index);
return true;
}
}
return false;
}
void Curve::_get_property_list(List<PropertyInfo> *p_list) const {
for (int i = 0; i < _points.size(); i++) {
PropertyInfo pi = PropertyInfo(Variant::VECTOR2, vformat("point_%d/position", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
if (i != 0) {
pi = PropertyInfo(Variant::FLOAT, vformat("point_%d/left_tangent", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
pi = PropertyInfo(Variant::INT, vformat("point_%d/left_mode", i), PROPERTY_HINT_ENUM, "Free,Linear");
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
if (i != _points.size() - 1) {
pi = PropertyInfo(Variant::FLOAT, vformat("point_%d/right_tangent", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
pi = PropertyInfo(Variant::INT, vformat("point_%d/right_mode", i), PROPERTY_HINT_ENUM, "Free,Linear");
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
}
}
void Curve::_bind_methods() {
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ClassDB::bind_method(D_METHOD("get_point_count"), &Curve::get_point_count);
ClassDB::bind_method(D_METHOD("set_point_count", "count"), &Curve::set_point_count);
ClassDB::bind_method(D_METHOD("add_point", "position", "left_tangent", "right_tangent", "left_mode", "right_mode"), &Curve::add_point, DEFVAL(0), DEFVAL(0), DEFVAL(TANGENT_FREE), DEFVAL(TANGENT_FREE));
ClassDB::bind_method(D_METHOD("remove_point", "index"), &Curve::remove_point);
ClassDB::bind_method(D_METHOD("clear_points"), &Curve::clear_points);
ClassDB::bind_method(D_METHOD("get_point_position", "index"), &Curve::get_point_position);
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ClassDB::bind_method(D_METHOD("set_point_value", "index", "y"), &Curve::set_point_value);
ClassDB::bind_method(D_METHOD("set_point_offset", "index", "offset"), &Curve::set_point_offset);
ClassDB::bind_method(D_METHOD("sample", "offset"), &Curve::sample);
ClassDB::bind_method(D_METHOD("sample_baked", "offset"), &Curve::sample_baked);
ClassDB::bind_method(D_METHOD("get_point_left_tangent", "index"), &Curve::get_point_left_tangent);
ClassDB::bind_method(D_METHOD("get_point_right_tangent", "index"), &Curve::get_point_right_tangent);
ClassDB::bind_method(D_METHOD("get_point_left_mode", "index"), &Curve::get_point_left_mode);
ClassDB::bind_method(D_METHOD("get_point_right_mode", "index"), &Curve::get_point_right_mode);
ClassDB::bind_method(D_METHOD("set_point_left_tangent", "index", "tangent"), &Curve::set_point_left_tangent);
ClassDB::bind_method(D_METHOD("set_point_right_tangent", "index", "tangent"), &Curve::set_point_right_tangent);
ClassDB::bind_method(D_METHOD("set_point_left_mode", "index", "mode"), &Curve::set_point_left_mode);
ClassDB::bind_method(D_METHOD("set_point_right_mode", "index", "mode"), &Curve::set_point_right_mode);
ClassDB::bind_method(D_METHOD("get_min_value"), &Curve::get_min_value);
ClassDB::bind_method(D_METHOD("set_min_value", "min"), &Curve::set_min_value);
ClassDB::bind_method(D_METHOD("get_max_value"), &Curve::get_max_value);
ClassDB::bind_method(D_METHOD("set_max_value", "max"), &Curve::set_max_value);
ClassDB::bind_method(D_METHOD("clean_dupes"), &Curve::clean_dupes);
ClassDB::bind_method(D_METHOD("bake"), &Curve::bake);
ClassDB::bind_method(D_METHOD("get_bake_resolution"), &Curve::get_bake_resolution);
ClassDB::bind_method(D_METHOD("set_bake_resolution", "resolution"), &Curve::set_bake_resolution);
ClassDB::bind_method(D_METHOD("_get_data"), &Curve::get_data);
ClassDB::bind_method(D_METHOD("_set_data", "data"), &Curve::set_data);
ADD_PROPERTY(PropertyInfo(Variant::FLOAT, "min_value", PROPERTY_HINT_RANGE, "-1024,1024,0.01"), "set_min_value", "get_min_value");
ADD_PROPERTY(PropertyInfo(Variant::FLOAT, "max_value", PROPERTY_HINT_RANGE, "-1024,1024,0.01"), "set_max_value", "get_max_value");
ADD_PROPERTY(PropertyInfo(Variant::INT, "bake_resolution", PROPERTY_HINT_RANGE, "1,1000,1"), "set_bake_resolution", "get_bake_resolution");
ADD_PROPERTY(PropertyInfo(Variant::INT, "_data", PROPERTY_HINT_NONE, "", PROPERTY_USAGE_NO_EDITOR | PROPERTY_USAGE_INTERNAL), "_set_data", "_get_data");
ADD_ARRAY_COUNT("Points", "point_count", "set_point_count", "get_point_count", "point_");
ADD_SIGNAL(MethodInfo(SIGNAL_RANGE_CHANGED));
BIND_ENUM_CONSTANT(TANGENT_FREE);
BIND_ENUM_CONSTANT(TANGENT_LINEAR);
BIND_ENUM_CONSTANT(TANGENT_MODE_COUNT);
}
int Curve2D::get_point_count() const {
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return points.size();
}
void Curve2D::set_point_count(int p_count) {
ERR_FAIL_COND(p_count < 0);
if (points.size() >= p_count) {
points.resize(p_count);
mark_dirty();
} else {
for (int i = p_count - points.size(); i > 0; i--) {
_add_point(Vector2());
}
}
notify_property_list_changed();
}
void Curve2D::_add_point(const Vector2 &p_position, const Vector2 &p_in, const Vector2 &p_out, int p_atpos) {
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Point n;
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n.position = p_position;
n.in = p_in;
n.out = p_out;
if (p_atpos >= 0 && p_atpos < points.size()) {
points.insert(p_atpos, n);
} else {
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points.push_back(n);
}
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mark_dirty();
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}
void Curve2D::add_point(const Vector2 &p_position, const Vector2 &p_in, const Vector2 &p_out, int p_atpos) {
_add_point(p_position, p_in, p_out, p_atpos);
notify_property_list_changed();
}
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void Curve2D::set_point_position(int p_index, const Vector2 &p_position) {
ERR_FAIL_INDEX(p_index, points.size());
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points.write[p_index].position = p_position;
mark_dirty();
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}
Vector2 Curve2D::get_point_position(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), Vector2());
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return points[p_index].position;
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}
void Curve2D::set_point_in(int p_index, const Vector2 &p_in) {
ERR_FAIL_INDEX(p_index, points.size());
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points.write[p_index].in = p_in;
mark_dirty();
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}
Vector2 Curve2D::get_point_in(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), Vector2());
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return points[p_index].in;
}
void Curve2D::set_point_out(int p_index, const Vector2 &p_out) {
ERR_FAIL_INDEX(p_index, points.size());
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points.write[p_index].out = p_out;
mark_dirty();
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}
Vector2 Curve2D::get_point_out(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), Vector2());
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return points[p_index].out;
}
void Curve2D::_remove_point(int p_index) {
ERR_FAIL_INDEX(p_index, points.size());
points.remove_at(p_index);
mark_dirty();
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}
void Curve2D::remove_point(int p_index) {
_remove_point(p_index);
notify_property_list_changed();
}
void Curve2D::clear_points() {
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if (!points.is_empty()) {
points.clear();
mark_dirty();
notify_property_list_changed();
}
}
Vector2 Curve2D::sample(int p_index, const real_t p_offset) const {
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int pc = points.size();
ERR_FAIL_COND_V(pc == 0, Vector2());
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if (p_index >= pc - 1) {
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return points[pc - 1].position;
} else if (p_index < 0) {
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return points[0].position;
}
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Vector2 p0 = points[p_index].position;
Vector2 p1 = p0 + points[p_index].out;
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Vector2 p3 = points[p_index + 1].position;
Vector2 p2 = p3 + points[p_index + 1].in;
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return p0.bezier_interpolate(p1, p2, p3, p_offset);
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}
Vector2 Curve2D::samplef(real_t p_findex) const {
if (p_findex < 0) {
p_findex = 0;
} else if (p_findex >= points.size()) {
p_findex = points.size();
}
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return sample((int)p_findex, Math::fmod(p_findex, (real_t)1.0));
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}
void Curve2D::mark_dirty() {
baked_cache_dirty = true;
emit_signal(CoreStringNames::get_singleton()->changed);
}
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void Curve2D::_bake_segment2d(RBMap<real_t, Vector2> &r_bake, real_t p_begin, real_t p_end, const Vector2 &p_a, const Vector2 &p_out, const Vector2 &p_b, const Vector2 &p_in, int p_depth, int p_max_depth, real_t p_tol) const {
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real_t mp = p_begin + (p_end - p_begin) * 0.5;
Vector2 beg = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_begin);
Vector2 mid = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, mp);
Vector2 end = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_end);
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Vector2 na = (mid - beg).normalized();
Vector2 nb = (end - mid).normalized();
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real_t dp = na.dot(nb);
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if (dp < Math::cos(Math::deg_to_rad(p_tol))) {
r_bake[mp] = mid;
}
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if (p_depth < p_max_depth) {
_bake_segment2d(r_bake, p_begin, mp, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_tol);
_bake_segment2d(r_bake, mp, p_end, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_tol);
}
}
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void Curve2D::_bake_segment2d_even_length(RBMap<real_t, Vector2> &r_bake, real_t p_begin, real_t p_end, const Vector2 &p_a, const Vector2 &p_out, const Vector2 &p_b, const Vector2 &p_in, int p_depth, int p_max_depth, real_t p_length) const {
Vector2 beg = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_begin);
Vector2 end = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_end);
real_t length = beg.distance_to(end);
if (length > p_length && p_depth < p_max_depth) {
real_t mp = (p_begin + p_end) * 0.5;
Vector2 mid = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, mp);
r_bake[mp] = mid;
_bake_segment2d_even_length(r_bake, p_begin, mp, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_length);
_bake_segment2d_even_length(r_bake, mp, p_end, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_length);
}
}
Vector2 Curve2D::_calculate_tangent(const Vector2 &p_begin, const Vector2 &p_control_1, const Vector2 &p_control_2, const Vector2 &p_end, const real_t p_t) {
// Handle corner cases.
if (Math::is_zero_approx(p_t - 0.0f) && p_control_1.is_equal_approx(p_begin)) {
return (p_end - p_begin).normalized();
}
if (Math::is_zero_approx(p_t - 1.0f) && p_control_2.is_equal_approx(p_end)) {
return (p_end - p_begin).normalized();
}
return p_begin.bezier_derivative(p_control_1, p_control_2, p_end, p_t).normalized();
}
void Curve2D::_bake() const {
if (!baked_cache_dirty) {
return;
}
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baked_max_ofs = 0;
baked_cache_dirty = false;
if (points.size() == 0) {
baked_point_cache.clear();
baked_dist_cache.clear();
baked_forward_vector_cache.clear();
return;
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}
if (points.size() == 1) {
baked_point_cache.resize(1);
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baked_point_cache.set(0, points[0].position);
baked_dist_cache.resize(1);
baked_dist_cache.set(0, 0.0);
baked_forward_vector_cache.resize(1);
baked_forward_vector_cache.set(0, Vector2(0.0, 0.1));
return;
}
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// Tessellate curve to (almost) even length segments
{
Vector<RBMap<real_t, Vector2>> midpoints = _tessellate_even_length(10, bake_interval);
int pc = 1;
for (int i = 0; i < points.size() - 1; i++) {
pc++;
pc += midpoints[i].size();
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}
baked_point_cache.resize(pc);
baked_dist_cache.resize(pc);
baked_forward_vector_cache.resize(pc);
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Vector2 *bpw = baked_point_cache.ptrw();
Vector2 *bfw = baked_forward_vector_cache.ptrw();
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// Collect positions and sample tilts and tangents for each baked points.
bpw[0] = points[0].position;
bfw[0] = _calculate_tangent(points[0].position, points[0].position + points[0].out, points[1].position + points[1].in, points[1].position, 0.0);
int pidx = 0;
for (int i = 0; i < points.size() - 1; i++) {
for (const KeyValue<real_t, Vector2> &E : midpoints[i]) {
pidx++;
bpw[pidx] = E.value;
bfw[pidx] = _calculate_tangent(points[i].position, points[i].position + points[i].out, points[i + 1].position + points[i + 1].in, points[i + 1].position, E.key);
}
pidx++;
bpw[pidx] = points[i + 1].position;
bfw[pidx] = _calculate_tangent(points[i].position, points[i].position + points[i].out, points[i + 1].position + points[i + 1].in, points[i + 1].position, 1.0);
}
// Recalculate the baked distances.
real_t *bdw = baked_dist_cache.ptrw();
bdw[0] = 0.0;
for (int i = 0; i < pc - 1; i++) {
bdw[i + 1] = bdw[i] + bpw[i].distance_to(bpw[i + 1]);
}
baked_max_ofs = bdw[pc - 1];
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}
}
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real_t Curve2D::get_baked_length() const {
if (baked_cache_dirty) {
_bake();
}
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return baked_max_ofs;
}
Curve2D::Interval Curve2D::_find_interval(real_t p_offset) const {
Interval interval = {
-1,
0.0
};
ERR_FAIL_COND_V_MSG(baked_cache_dirty, interval, "Backed cache is dirty");
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int pc = baked_point_cache.size();
ERR_FAIL_COND_V_MSG(pc < 2, interval, "Less than two points in cache");
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int start = 0;
int end = pc;
int idx = (end + start) / 2;
// Binary search to find baked points.
while (start < idx) {
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real_t offset = baked_dist_cache[idx];
if (p_offset <= offset) {
end = idx;
} else {
start = idx;
}
idx = (end + start) / 2;
}
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real_t offset_begin = baked_dist_cache[idx];
real_t offset_end = baked_dist_cache[idx + 1];
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real_t idx_interval = offset_end - offset_begin;
ERR_FAIL_COND_V_MSG(p_offset < offset_begin || p_offset > offset_end, interval, "Offset out of range.");
interval.idx = idx;
if (idx_interval < FLT_EPSILON) {
interval.frac = 0.5; // For a very short interval, 0.5 is a reasonable choice.
ERR_FAIL_V_MSG(interval, "Zero length interval.");
}
interval.frac = (p_offset - offset_begin) / idx_interval;
return interval;
}
Vector2 Curve2D::_sample_baked(Interval p_interval, bool p_cubic) const {
// Assuming p_interval is valid.
ERR_FAIL_INDEX_V_MSG(p_interval.idx, baked_point_cache.size(), Vector2(), "Invalid interval");
int idx = p_interval.idx;
real_t frac = p_interval.frac;
const Vector2 *r = baked_point_cache.ptr();
int pc = baked_point_cache.size();
if (p_cubic) {
Vector2 pre = idx > 0 ? r[idx - 1] : r[idx];
Vector2 post = (idx < (pc - 2)) ? r[idx + 2] : r[idx + 1];
return r[idx].cubic_interpolate(r[idx + 1], pre, post, frac);
} else {
return r[idx].lerp(r[idx + 1], frac);
}
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}
Transform2D Curve2D::_sample_posture(Interval p_interval) const {
// Assuming that p_interval is valid.
ERR_FAIL_INDEX_V_MSG(p_interval.idx, baked_point_cache.size(), Transform2D(), "Invalid interval");
int idx = p_interval.idx;
real_t frac = p_interval.frac;
Vector2 forward_begin = baked_forward_vector_cache[idx];
Vector2 forward_end = baked_forward_vector_cache[idx + 1];
// Build frames at both ends of the interval, then interpolate.
const Vector2 forward = forward_begin.slerp(forward_end, frac).normalized();
const Vector2 side = Vector2(-forward.y, forward.x);
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return Transform2D(side, forward, Vector2(0.0, 0.0));
}
Vector2 Curve2D::sample_baked(real_t p_offset, bool p_cubic) const {
if (baked_cache_dirty) {
_bake();
}
// Validate: Curve may not have baked points.
int pc = baked_point_cache.size();
ERR_FAIL_COND_V_MSG(pc == 0, Vector2(), "No points in Curve2D.");
if (pc == 1) {
return baked_point_cache[0];
}
p_offset = CLAMP(p_offset, 0.0, get_baked_length()); // PathFollower implement wrapping logic.
Curve2D::Interval interval = _find_interval(p_offset);
return _sample_baked(interval, p_cubic);
}
Transform2D Curve2D::sample_baked_with_rotation(real_t p_offset, bool p_cubic) const {
if (baked_cache_dirty) {
_bake();
}
// Validate: Curve may not have baked points.
const int point_count = baked_point_cache.size();
ERR_FAIL_COND_V_MSG(point_count == 0, Transform2D(), "No points in Curve3D.");
if (point_count == 1) {
Transform2D t;
t.set_origin(baked_point_cache.get(0));
ERR_FAIL_V_MSG(t, "Only 1 point in Curve2D.");
}
p_offset = CLAMP(p_offset, 0.0, get_baked_length()); // PathFollower implement wrapping logic.
// 0. Find interval for all sampling steps.
Curve2D::Interval interval = _find_interval(p_offset);
// 1. Sample position.
Vector2 pos = _sample_baked(interval, p_cubic);
// 2. Sample rotation frame.
Transform2D frame = _sample_posture(interval);
frame.set_origin(pos);
return frame;
}
PackedVector2Array Curve2D::get_baked_points() const {
if (baked_cache_dirty) {
_bake();
}
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return baked_point_cache;
}
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void Curve2D::set_bake_interval(real_t p_tolerance) {
bake_interval = p_tolerance;
mark_dirty();
}
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real_t Curve2D::get_bake_interval() const {
return bake_interval;
}
Vector2 Curve2D::get_closest_point(const Vector2 &p_to_point) const {
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// Brute force method.
if (baked_cache_dirty) {
_bake();
}
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// Validate: Curve may not have baked points.
int pc = baked_point_cache.size();
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ERR_FAIL_COND_V_MSG(pc == 0, Vector2(), "No points in Curve2D.");
if (pc == 1) {
return baked_point_cache.get(0);
}
const Vector2 *r = baked_point_cache.ptr();
Vector2 nearest;
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real_t nearest_dist = -1.0f;
for (int i = 0; i < pc - 1; i++) {
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const real_t interval = baked_dist_cache[i + 1] - baked_dist_cache[i];
Vector2 origin = r[i];
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Vector2 direction = (r[i + 1] - origin) / interval;
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real_t d = CLAMP((p_to_point - origin).dot(direction), 0.0f, interval);
Vector2 proj = origin + direction * d;
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real_t dist = proj.distance_squared_to(p_to_point);
if (nearest_dist < 0.0f || dist < nearest_dist) {
nearest = proj;
nearest_dist = dist;
}
}
return nearest;
}
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real_t Curve2D::get_closest_offset(const Vector2 &p_to_point) const {
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// Brute force method.
if (baked_cache_dirty) {
_bake();
}
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// Validate: Curve may not have baked points.
int pc = baked_point_cache.size();
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ERR_FAIL_COND_V_MSG(pc == 0, 0.0f, "No points in Curve2D.");
if (pc == 1) {
return 0.0f;
}
const Vector2 *r = baked_point_cache.ptr();
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real_t nearest = 0.0f;
real_t nearest_dist = -1.0f;
real_t offset = 0.0f;
for (int i = 0; i < pc - 1; i++) {
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offset = baked_dist_cache[i];
const real_t interval = baked_dist_cache[i + 1] - baked_dist_cache[i];
Vector2 origin = r[i];
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Vector2 direction = (r[i + 1] - origin) / interval;
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real_t d = CLAMP((p_to_point - origin).dot(direction), 0.0f, interval);
Vector2 proj = origin + direction * d;
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real_t dist = proj.distance_squared_to(p_to_point);
if (nearest_dist < 0.0f || dist < nearest_dist) {
nearest = offset + d;
nearest_dist = dist;
}
}
return nearest;
}
Dictionary Curve2D::_get_data() const {
Dictionary dc;
PackedVector2Array d;
d.resize(points.size() * 3);
Vector2 *w = d.ptrw();
for (int i = 0; i < points.size(); i++) {
w[i * 3 + 0] = points[i].in;
w[i * 3 + 1] = points[i].out;
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w[i * 3 + 2] = points[i].position;
}
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dc["points"] = d;
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return dc;
}
void Curve2D::_set_data(const Dictionary &p_data) {
ERR_FAIL_COND(!p_data.has("points"));
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PackedVector2Array rp = p_data["points"];
int pc = rp.size();
ERR_FAIL_COND(pc % 3 != 0);
points.resize(pc / 3);
const Vector2 *r = rp.ptr();
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for (int i = 0; i < points.size(); i++) {
points.write[i].in = r[i * 3 + 0];
points.write[i].out = r[i * 3 + 1];
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points.write[i].position = r[i * 3 + 2];
}
mark_dirty();
notify_property_list_changed();
}
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PackedVector2Array Curve2D::tessellate(int p_max_stages, real_t p_tolerance) const {
PackedVector2Array tess;
if (points.size() == 0) {
return tess;
}
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// The current implementation requires a sorted map.
Vector<RBMap<real_t, Vector2>> midpoints;
midpoints.resize(points.size() - 1);
int pc = 1;
for (int i = 0; i < points.size() - 1; i++) {
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_bake_segment2d(midpoints.write[i], 0, 1, points[i].position, points[i].out, points[i + 1].position, points[i + 1].in, 0, p_max_stages, p_tolerance);
pc++;
pc += midpoints[i].size();
}
tess.resize(pc);
Vector2 *bpw = tess.ptrw();
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bpw[0] = points[0].position;
int pidx = 0;
for (int i = 0; i < points.size() - 1; i++) {
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for (const KeyValue<real_t, Vector2> &E : midpoints[i]) {
pidx++;
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bpw[pidx] = E.value;
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}
pidx++;
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bpw[pidx] = points[i + 1].position;
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}
return tess;
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}
Vector<RBMap<real_t, Vector2>> Curve2D::_tessellate_even_length(int p_max_stages, real_t p_length) const {
Vector<RBMap<real_t, Vector2>> midpoints;
ERR_FAIL_COND_V_MSG(points.size() < 2, midpoints, "Curve must have at least 2 control point");
midpoints.resize(points.size() - 1);
for (int i = 0; i < points.size() - 1; i++) {
_bake_segment2d_even_length(midpoints.write[i], 0, 1, points[i].position, points[i].out, points[i + 1].position, points[i + 1].in, 0, p_max_stages, p_length);
}
return midpoints;
}
PackedVector2Array Curve2D::tessellate_even_length(int p_max_stages, real_t p_length) const {
PackedVector2Array tess;
Vector<RBMap<real_t, Vector2>> midpoints = _tessellate_even_length(p_max_stages, p_length);
if (midpoints.size() == 0) {
return tess;
}
int pc = 1;
for (int i = 0; i < points.size() - 1; i++) {
pc++;
pc += midpoints[i].size();
}
tess.resize(pc);
Vector2 *bpw = tess.ptrw();
bpw[0] = points[0].position;
int pidx = 0;
for (int i = 0; i < points.size() - 1; i++) {
for (const KeyValue<real_t, Vector2> &E : midpoints[i]) {
pidx++;
bpw[pidx] = E.value;
}
pidx++;
bpw[pidx] = points[i + 1].position;
}
return tess;
}
bool Curve2D::_set(const StringName &p_name, const Variant &p_value) {
Vector<String> components = String(p_name).split("/", true, 2);
if (components.size() >= 2 && components[0].begins_with("point_") && components[0].trim_prefix("point_").is_valid_int()) {
int point_index = components[0].trim_prefix("point_").to_int();
String property = components[1];
if (property == "position") {
set_point_position(point_index, p_value);
return true;
} else if (property == "in") {
set_point_in(point_index, p_value);
return true;
} else if (property == "out") {
set_point_out(point_index, p_value);
return true;
}
}
return false;
}
bool Curve2D::_get(const StringName &p_name, Variant &r_ret) const {
Vector<String> components = String(p_name).split("/", true, 2);
if (components.size() >= 2 && components[0].begins_with("point_") && components[0].trim_prefix("point_").is_valid_int()) {
int point_index = components[0].trim_prefix("point_").to_int();
String property = components[1];
if (property == "position") {
r_ret = get_point_position(point_index);
return true;
} else if (property == "in") {
r_ret = get_point_in(point_index);
return true;
} else if (property == "out") {
r_ret = get_point_out(point_index);
return true;
}
}
return false;
}
void Curve2D::_get_property_list(List<PropertyInfo> *p_list) const {
for (int i = 0; i < points.size(); i++) {
PropertyInfo pi = PropertyInfo(Variant::VECTOR2, vformat("point_%d/position", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
if (i != 0) {
pi = PropertyInfo(Variant::VECTOR2, vformat("point_%d/in", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
if (i != points.size() - 1) {
pi = PropertyInfo(Variant::VECTOR2, vformat("point_%d/out", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
}
}
void Curve2D::_bind_methods() {
ClassDB::bind_method(D_METHOD("get_point_count"), &Curve2D::get_point_count);
ClassDB::bind_method(D_METHOD("set_point_count", "count"), &Curve2D::set_point_count);
ClassDB::bind_method(D_METHOD("add_point", "position", "in", "out", "index"), &Curve2D::add_point, DEFVAL(Vector2()), DEFVAL(Vector2()), DEFVAL(-1));
ClassDB::bind_method(D_METHOD("set_point_position", "idx", "position"), &Curve2D::set_point_position);
ClassDB::bind_method(D_METHOD("get_point_position", "idx"), &Curve2D::get_point_position);
ClassDB::bind_method(D_METHOD("set_point_in", "idx", "position"), &Curve2D::set_point_in);
ClassDB::bind_method(D_METHOD("get_point_in", "idx"), &Curve2D::get_point_in);
ClassDB::bind_method(D_METHOD("set_point_out", "idx", "position"), &Curve2D::set_point_out);
ClassDB::bind_method(D_METHOD("get_point_out", "idx"), &Curve2D::get_point_out);
ClassDB::bind_method(D_METHOD("remove_point", "idx"), &Curve2D::remove_point);
ClassDB::bind_method(D_METHOD("clear_points"), &Curve2D::clear_points);
ClassDB::bind_method(D_METHOD("sample", "idx", "t"), &Curve2D::sample);
ClassDB::bind_method(D_METHOD("samplef", "fofs"), &Curve2D::samplef);
//ClassDB::bind_method(D_METHOD("bake","subdivs"),&Curve2D::bake,DEFVAL(10));
ClassDB::bind_method(D_METHOD("set_bake_interval", "distance"), &Curve2D::set_bake_interval);
ClassDB::bind_method(D_METHOD("get_bake_interval"), &Curve2D::get_bake_interval);
ClassDB::bind_method(D_METHOD("get_baked_length"), &Curve2D::get_baked_length);
ClassDB::bind_method(D_METHOD("sample_baked", "offset", "cubic"), &Curve2D::sample_baked, DEFVAL(0.0), DEFVAL(false));
ClassDB::bind_method(D_METHOD("sample_baked_with_rotation", "offset", "cubic"), &Curve2D::sample_baked_with_rotation, DEFVAL(0.0), DEFVAL(false));
ClassDB::bind_method(D_METHOD("get_baked_points"), &Curve2D::get_baked_points);
ClassDB::bind_method(D_METHOD("get_closest_point", "to_point"), &Curve2D::get_closest_point);
ClassDB::bind_method(D_METHOD("get_closest_offset", "to_point"), &Curve2D::get_closest_offset);
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ClassDB::bind_method(D_METHOD("tessellate", "max_stages", "tolerance_degrees"), &Curve2D::tessellate, DEFVAL(5), DEFVAL(4));
ClassDB::bind_method(D_METHOD("tessellate_even_length", "max_stages", "tolerance_length"), &Curve2D::tessellate_even_length, DEFVAL(5), DEFVAL(20.0));
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ClassDB::bind_method(D_METHOD("_get_data"), &Curve2D::_get_data);
ClassDB::bind_method(D_METHOD("_set_data", "data"), &Curve2D::_set_data);
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ADD_PROPERTY(PropertyInfo(Variant::FLOAT, "bake_interval", PROPERTY_HINT_RANGE, "0.01,512,0.01"), "set_bake_interval", "get_bake_interval");
ADD_PROPERTY(PropertyInfo(Variant::INT, "_data", PROPERTY_HINT_NONE, "", PROPERTY_USAGE_NO_EDITOR | PROPERTY_USAGE_INTERNAL), "_set_data", "_get_data");
ADD_ARRAY_COUNT("Points", "point_count", "set_point_count", "get_point_count", "point_");
}
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Curve2D::Curve2D() {}
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/***********************************************************************************/
/***********************************************************************************/
/***********************************************************************************/
/***********************************************************************************/
/***********************************************************************************/
/***********************************************************************************/
int Curve3D::get_point_count() const {
return points.size();
}
void Curve3D::set_point_count(int p_count) {
ERR_FAIL_COND(p_count < 0);
if (points.size() >= p_count) {
points.resize(p_count);
mark_dirty();
} else {
for (int i = p_count - points.size(); i > 0; i--) {
_add_point(Vector3());
}
}
notify_property_list_changed();
}
void Curve3D::_add_point(const Vector3 &p_position, const Vector3 &p_in, const Vector3 &p_out, int p_atpos) {
Point n;
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n.position = p_position;
n.in = p_in;
n.out = p_out;
if (p_atpos >= 0 && p_atpos < points.size()) {
points.insert(p_atpos, n);
} else {
points.push_back(n);
}
mark_dirty();
}
void Curve3D::add_point(const Vector3 &p_position, const Vector3 &p_in, const Vector3 &p_out, int p_atpos) {
_add_point(p_position, p_in, p_out, p_atpos);
notify_property_list_changed();
}
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void Curve3D::set_point_position(int p_index, const Vector3 &p_position) {
ERR_FAIL_INDEX(p_index, points.size());
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points.write[p_index].position = p_position;
mark_dirty();
}
Vector3 Curve3D::get_point_position(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), Vector3());
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return points[p_index].position;
}
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void Curve3D::set_point_tilt(int p_index, real_t p_tilt) {
ERR_FAIL_INDEX(p_index, points.size());
points.write[p_index].tilt = p_tilt;
mark_dirty();
}
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real_t Curve3D::get_point_tilt(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), 0);
return points[p_index].tilt;
}
void Curve3D::set_point_in(int p_index, const Vector3 &p_in) {
ERR_FAIL_INDEX(p_index, points.size());
points.write[p_index].in = p_in;
mark_dirty();
}
Vector3 Curve3D::get_point_in(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), Vector3());
return points[p_index].in;
}
void Curve3D::set_point_out(int p_index, const Vector3 &p_out) {
ERR_FAIL_INDEX(p_index, points.size());
points.write[p_index].out = p_out;
mark_dirty();
}
Vector3 Curve3D::get_point_out(int p_index) const {
ERR_FAIL_INDEX_V(p_index, points.size(), Vector3());
return points[p_index].out;
}
void Curve3D::_remove_point(int p_index) {
ERR_FAIL_INDEX(p_index, points.size());
points.remove_at(p_index);
mark_dirty();
}
void Curve3D::remove_point(int p_index) {
_remove_point(p_index);
notify_property_list_changed();
}
void Curve3D::clear_points() {
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if (!points.is_empty()) {
points.clear();
mark_dirty();
notify_property_list_changed();
}
}
Vector3 Curve3D::sample(int p_index, real_t p_offset) const {
int pc = points.size();
ERR_FAIL_COND_V(pc == 0, Vector3());
if (p_index >= pc - 1) {
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return points[pc - 1].position;
} else if (p_index < 0) {
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return points[0].position;
}
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Vector3 p0 = points[p_index].position;
Vector3 p1 = p0 + points[p_index].out;
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Vector3 p3 = points[p_index + 1].position;
Vector3 p2 = p3 + points[p_index + 1].in;
return p0.bezier_interpolate(p1, p2, p3, p_offset);
}
Vector3 Curve3D::samplef(real_t p_findex) const {
if (p_findex < 0) {
p_findex = 0;
} else if (p_findex >= points.size()) {
p_findex = points.size();
}
return sample((int)p_findex, Math::fmod(p_findex, (real_t)1.0));
}
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void Curve3D::mark_dirty() {
baked_cache_dirty = true;
emit_signal(CoreStringNames::get_singleton()->changed);
}
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void Curve3D::_bake_segment3d(RBMap<real_t, Vector3> &r_bake, real_t p_begin, real_t p_end, const Vector3 &p_a, const Vector3 &p_out, const Vector3 &p_b, const Vector3 &p_in, int p_depth, int p_max_depth, real_t p_tol) const {
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real_t mp = p_begin + (p_end - p_begin) * 0.5;
Vector3 beg = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_begin);
Vector3 mid = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, mp);
Vector3 end = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_end);
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Vector3 na = (mid - beg).normalized();
Vector3 nb = (end - mid).normalized();
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real_t dp = na.dot(nb);
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if (dp < Math::cos(Math::deg_to_rad(p_tol))) {
r_bake[mp] = mid;
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}
if (p_depth < p_max_depth) {
_bake_segment3d(r_bake, p_begin, mp, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_tol);
_bake_segment3d(r_bake, mp, p_end, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_tol);
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}
}
void Curve3D::_bake_segment3d_even_length(RBMap<real_t, Vector3> &r_bake, real_t p_begin, real_t p_end, const Vector3 &p_a, const Vector3 &p_out, const Vector3 &p_b, const Vector3 &p_in, int p_depth, int p_max_depth, real_t p_length) const {
Vector3 beg = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_begin);
Vector3 end = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, p_end);
real_t length = beg.distance_to(end);
if (length > p_length && p_depth < p_max_depth) {
real_t mp = (p_begin + p_end) * 0.5;
Vector3 mid = p_a.bezier_interpolate(p_a + p_out, p_b + p_in, p_b, mp);
r_bake[mp] = mid;
_bake_segment3d_even_length(r_bake, p_begin, mp, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_length);
_bake_segment3d_even_length(r_bake, mp, p_end, p_a, p_out, p_b, p_in, p_depth + 1, p_max_depth, p_length);
}
}
Vector3 Curve3D::_calculate_tangent(const Vector3 &p_begin, const Vector3 &p_control_1, const Vector3 &p_control_2, const Vector3 &p_end, const real_t p_t) {
// Handle corner cases.
if (Math::is_zero_approx(p_t - 0.0f) && p_control_1.is_equal_approx(p_begin)) {
return (p_end - p_begin).normalized();
}
if (Math::is_zero_approx(p_t - 1.0f) && p_control_2.is_equal_approx(p_end)) {
return (p_end - p_begin).normalized();
}
return p_begin.bezier_derivative(p_control_1, p_control_2, p_end, p_t).normalized();
}
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void Curve3D::_bake() const {
if (!baked_cache_dirty) {
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return;
}
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baked_max_ofs = 0;
baked_cache_dirty = false;
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if (points.size() == 0) {
baked_point_cache.clear();
baked_tilt_cache.clear();
baked_dist_cache.clear();
baked_forward_vector_cache.clear();
baked_up_vector_cache.clear();
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return;
}
if (points.size() == 1) {
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baked_point_cache.resize(1);
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baked_point_cache.set(0, points[0].position);
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baked_tilt_cache.resize(1);
baked_tilt_cache.set(0, points[0].tilt);
baked_dist_cache.resize(1);
baked_dist_cache.set(0, 0.0);
baked_forward_vector_cache.resize(1);
baked_forward_vector_cache.set(0, Vector3(0.0, 0.0, 1.0));
if (up_vector_enabled) {
baked_up_vector_cache.resize(1);
baked_up_vector_cache.set(0, Vector3(0.0, 1.0, 0.0));
} else {
baked_up_vector_cache.clear();
}
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return;
}
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// Step 1: Tessellate curve to (almost) even length segments
{
Vector<RBMap<real_t, Vector3>> midpoints = _tessellate_even_length(10, bake_interval);
int pc = 1;
for (int i = 0; i < points.size() - 1; i++) {
pc++;
pc += midpoints[i].size();
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}
baked_point_cache.resize(pc);
baked_tilt_cache.resize(pc);
baked_dist_cache.resize(pc);
baked_forward_vector_cache.resize(pc);
Vector3 *bpw = baked_point_cache.ptrw();
real_t *btw = baked_tilt_cache.ptrw();
Vector3 *bfw = baked_forward_vector_cache.ptrw();
// Collect positions and sample tilts and tangents for each baked points.
bpw[0] = points[0].position;
bfw[0] = _calculate_tangent(points[0].position, points[0].position + points[0].out, points[1].position + points[1].in, points[1].position, 0.0);
btw[0] = points[0].tilt;
int pidx = 0;
for (int i = 0; i < points.size() - 1; i++) {
for (const KeyValue<real_t, Vector3> &E : midpoints[i]) {
pidx++;
bpw[pidx] = E.value;
bfw[pidx] = _calculate_tangent(points[i].position, points[i].position + points[i].out, points[i + 1].position + points[i + 1].in, points[i + 1].position, E.key);
btw[pidx] = Math::lerp(points[i].tilt, points[i + 1].tilt, E.key);
}
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pidx++;
bpw[pidx] = points[i + 1].position;
bfw[pidx] = _calculate_tangent(points[i].position, points[i].position + points[i].out, points[i + 1].position + points[i + 1].in, points[i + 1].position, 1.0);
btw[pidx] = points[i + 1].tilt;
}
// Recalculate the baked distances.
real_t *bdw = baked_dist_cache.ptrw();
bdw[0] = 0.0;
for (int i = 0; i < pc - 1; i++) {
bdw[i + 1] = bdw[i] + bpw[i].distance_to(bpw[i + 1]);
}
baked_max_ofs = bdw[pc - 1];
}
if (!up_vector_enabled) {
baked_up_vector_cache.resize(0);
return;
}
// Step 2: Calculate the up vectors and the whole local reference frame
//
// See Dougan, Carl. "The parallel transport frame." Game Programming Gems 2 (2001): 215-219.
// for an example discussing about why not the Frenet frame.
{
int point_count = baked_point_cache.size();
baked_up_vector_cache.resize(point_count);
Vector3 *up_write = baked_up_vector_cache.ptrw();
const Vector3 *forward_ptr = baked_forward_vector_cache.ptr();
const Vector3 *points_ptr = baked_point_cache.ptr();
Basis frame; // X-right, Y-up, Z-forward.
Basis frame_prev;
// Set the initial frame based on Y-up rule.
{
Vector3 forward = forward_ptr[0];
if (abs(forward.dot(Vector3(0, 1, 0))) > 1.0 - UNIT_EPSILON) {
frame_prev = Basis::looking_at(-forward, Vector3(1, 0, 0));
} else {
frame_prev = Basis::looking_at(-forward, Vector3(0, 1, 0));
}
up_write[0] = frame_prev.get_column(1);
}
// Calculate the Parallel Transport Frame.
for (int idx = 1; idx < point_count; idx++) {
Vector3 forward = forward_ptr[idx];
Basis rotate;
rotate.rotate_to_align(frame_prev.get_column(2), forward);
frame = rotate * frame_prev;
frame.orthonormalize(); // guard against float error accumulation
up_write[idx] = frame.get_column(1);
frame_prev = frame;
}
bool is_loop = true;
// Loop smoothing only applies when the curve is a loop, which means two ends meet, and share forward directions.
{
if (!points_ptr[0].is_equal_approx(points_ptr[point_count - 1])) {
is_loop = false;
}
real_t dot = forward_ptr[0].dot(forward_ptr[point_count - 1]);
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if (dot < 1.0 - UNIT_EPSILON) { // Alignment should not be too tight, or it doesn't work for coarse bake interval.
is_loop = false;
}
}
// Twist up vectors, so that they align at two ends of the curve.
if (is_loop) {
const Vector3 up_start = up_write[0];
const Vector3 up_end = up_write[point_count - 1];
real_t sign = SIGN(up_end.cross(up_start).dot(forward_ptr[0]));
real_t full_angle = Quaternion(up_end, up_start).get_angle();
if (abs(full_angle) < CMP_EPSILON) {
return;
} else {
const real_t *dists = baked_dist_cache.ptr();
for (int idx = 1; idx < point_count; idx++) {
const real_t frac = dists[idx] / baked_max_ofs;
const real_t angle = Math::lerp((real_t)0.0, full_angle, frac);
Basis twist(forward_ptr[idx] * sign, angle);
up_write[idx] = twist.xform(up_write[idx]);
}
}
}
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}
}
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real_t Curve3D::get_baked_length() const {
if (baked_cache_dirty) {
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_bake();
}
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return baked_max_ofs;
}
Curve3D::Interval Curve3D::_find_interval(real_t p_offset) const {
Interval interval = {
-1,
0.0
};
ERR_FAIL_COND_V_MSG(baked_cache_dirty, interval, "Backed cache is dirty");
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int pc = baked_point_cache.size();
ERR_FAIL_COND_V_MSG(pc < 2, interval, "Less than two points in cache");
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int start = 0;
int end = pc;
int idx = (end + start) / 2;
// Binary search to find baked points.
while (start < idx) {
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real_t offset = baked_dist_cache[idx];
if (p_offset <= offset) {
end = idx;
} else {
start = idx;
}
idx = (end + start) / 2;
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}
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real_t offset_begin = baked_dist_cache[idx];
real_t offset_end = baked_dist_cache[idx + 1];
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real_t idx_interval = offset_end - offset_begin;
ERR_FAIL_COND_V_MSG(p_offset < offset_begin || p_offset > offset_end, interval, "Offset out of range.");
interval.idx = idx;
if (idx_interval < FLT_EPSILON) {
interval.frac = 0.5; // For a very short interval, 0.5 is a reasonable choice.
ERR_FAIL_V_MSG(interval, "Zero length interval.");
}
interval.frac = (p_offset - offset_begin) / idx_interval;
return interval;
}
Vector3 Curve3D::_sample_baked(Interval p_interval, bool p_cubic) const {
// Assuming p_interval is valid.
ERR_FAIL_INDEX_V_MSG(p_interval.idx, baked_point_cache.size(), Vector3(), "Invalid interval");
int idx = p_interval.idx;
real_t frac = p_interval.frac;
const Vector3 *r = baked_point_cache.ptr();
int pc = baked_point_cache.size();
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if (p_cubic) {
Vector3 pre = idx > 0 ? r[idx - 1] : r[idx];
Vector3 post = (idx < (pc - 2)) ? r[idx + 2] : r[idx + 1];
return r[idx].cubic_interpolate(r[idx + 1], pre, post, frac);
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} else {
return r[idx].lerp(r[idx + 1], frac);
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}
}
real_t Curve3D::_sample_baked_tilt(Interval p_interval) const {
// Assuming that p_interval is valid.
ERR_FAIL_INDEX_V_MSG(p_interval.idx, baked_tilt_cache.size(), 0.0, "Invalid interval");
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int idx = p_interval.idx;
real_t frac = p_interval.frac;
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const real_t *r = baked_tilt_cache.ptr();
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return Math::lerp(r[idx], r[idx + 1], frac);
}
Basis Curve3D::_sample_posture(Interval p_interval, bool p_apply_tilt) const {
// Assuming that p_interval is valid.
ERR_FAIL_INDEX_V_MSG(p_interval.idx, baked_point_cache.size(), Basis(), "Invalid interval");
if (up_vector_enabled) {
ERR_FAIL_INDEX_V_MSG(p_interval.idx, baked_up_vector_cache.size(), Basis(), "Invalid interval");
}
int idx = p_interval.idx;
real_t frac = p_interval.frac;
Vector3 forward_begin = baked_forward_vector_cache[idx];
Vector3 forward_end = baked_forward_vector_cache[idx + 1];
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Vector3 up_begin;
Vector3 up_end;
if (up_vector_enabled) {
up_begin = baked_up_vector_cache[idx];
up_end = baked_up_vector_cache[idx + 1];
} else {
up_begin = Vector3(0.0, 1.0, 0.0);
up_end = Vector3(0.0, 1.0, 0.0);
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}
// Build frames at both ends of the interval, then interpolate.
const Basis frame_begin = Basis::looking_at(-forward_begin, up_begin);
const Basis frame_end = Basis::looking_at(-forward_end, up_end);
const Basis frame = frame_begin.slerp(frame_end, frac).orthonormalized();
if (!p_apply_tilt) {
return frame;
}
// Applying tilt.
const real_t tilt = _sample_baked_tilt(p_interval);
Vector3 forward = frame.get_column(2);
const Basis twist(forward, tilt);
return twist * frame;
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}
Vector3 Curve3D::sample_baked(real_t p_offset, bool p_cubic) const {
if (baked_cache_dirty) {
_bake();
}
// Validate: Curve may not have baked points.
int pc = baked_point_cache.size();
ERR_FAIL_COND_V_MSG(pc == 0, Vector3(), "No points in Curve3D.");
if (pc == 1) {
return baked_point_cache[0];
}
p_offset = CLAMP(p_offset, 0.0, get_baked_length()); // PathFollower implement wrapping logic.
Curve3D::Interval interval = _find_interval(p_offset);
return _sample_baked(interval, p_cubic);
}
Transform3D Curve3D::sample_baked_with_rotation(real_t p_offset, bool p_cubic, bool p_apply_tilt) const {
if (baked_cache_dirty) {
_bake();
}
// Validate: Curve may not have baked points.
const int point_count = baked_point_cache.size();
ERR_FAIL_COND_V_MSG(point_count == 0, Transform3D(), "No points in Curve3D.");
if (point_count == 1) {
Transform3D t;
t.origin = baked_point_cache.get(0);
ERR_FAIL_V_MSG(t, "Only 1 point in Curve3D.");
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}
p_offset = CLAMP(p_offset, 0.0, get_baked_length()); // PathFollower implement wrapping logic.
// 0. Find interval for all sampling steps.
Curve3D::Interval interval = _find_interval(p_offset);
// 1. Sample position.
Vector3 pos = _sample_baked(interval, p_cubic);
// 2. Sample rotation frame.
Basis frame = _sample_posture(interval, p_apply_tilt);
return Transform3D(frame, pos);
}
real_t Curve3D::sample_baked_tilt(real_t p_offset) const {
if (baked_cache_dirty) {
_bake();
}
// Validate: Curve may not have baked tilts.
int pc = baked_tilt_cache.size();
ERR_FAIL_COND_V_MSG(pc == 0, 0, "No tilts in Curve3D.");
if (pc == 1) {
return baked_tilt_cache.get(0);
}
p_offset = CLAMP(p_offset, 0.0, get_baked_length()); // PathFollower implement wrapping logic
Curve3D::Interval interval = _find_interval(p_offset);
return _sample_baked_tilt(interval);
}
Vector3 Curve3D::sample_baked_up_vector(real_t p_offset, bool p_apply_tilt) const {
if (baked_cache_dirty) {
_bake();
}
// Validate: Curve may not have baked up vectors.
ERR_FAIL_COND_V_MSG(!up_vector_enabled, Vector3(0, 1, 0), "No up vectors in Curve3D.");
int count = baked_up_vector_cache.size();
if (count == 1) {
return baked_up_vector_cache.get(0);
}
p_offset = CLAMP(p_offset, 0.0, get_baked_length()); // PathFollower implement wrapping logic.
Curve3D::Interval interval = _find_interval(p_offset);
return _sample_posture(interval, p_apply_tilt).get_column(1);
}
PackedVector3Array Curve3D::get_baked_points() const {
if (baked_cache_dirty) {
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_bake();
}
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return baked_point_cache;
}
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Vector<real_t> Curve3D::get_baked_tilts() const {
if (baked_cache_dirty) {
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_bake();
}
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return baked_tilt_cache;
}
PackedVector3Array Curve3D::get_baked_up_vectors() const {
if (baked_cache_dirty) {
_bake();
}
return baked_up_vector_cache;
}
Vector3 Curve3D::get_closest_point(const Vector3 &p_to_point) const {
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// Brute force method.
if (baked_cache_dirty) {
_bake();
}
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// Validate: Curve may not have baked points.
int pc = baked_point_cache.size();
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ERR_FAIL_COND_V_MSG(pc == 0, Vector3(), "No points in Curve3D.");
if (pc == 1) {
return baked_point_cache.get(0);
}
const Vector3 *r = baked_point_cache.ptr();
Vector3 nearest;
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real_t nearest_dist = -1.0f;
for (int i = 0; i < pc - 1; i++) {
const real_t interval = baked_dist_cache[i + 1] - baked_dist_cache[i];
Vector3 origin = r[i];
Vector3 direction = (r[i + 1] - origin) / interval;
real_t d = CLAMP((p_to_point - origin).dot(direction), 0.0f, interval);
Vector3 proj = origin + direction * d;
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real_t dist = proj.distance_squared_to(p_to_point);
if (nearest_dist < 0.0f || dist < nearest_dist) {
nearest = proj;
nearest_dist = dist;
}
}
return nearest;
}
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real_t Curve3D::get_closest_offset(const Vector3 &p_to_point) const {
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// Brute force method.
if (baked_cache_dirty) {
_bake();
}
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// Validate: Curve may not have baked points.
int pc = baked_point_cache.size();
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ERR_FAIL_COND_V_MSG(pc == 0, 0.0f, "No points in Curve3D.");
if (pc == 1) {
return 0.0f;
}
const Vector3 *r = baked_point_cache.ptr();
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real_t nearest = 0.0f;
real_t nearest_dist = -1.0f;
real_t offset;
for (int i = 0; i < pc - 1; i++) {
offset = baked_dist_cache[i];
const real_t interval = baked_dist_cache[i + 1] - baked_dist_cache[i];
Vector3 origin = r[i];
Vector3 direction = (r[i + 1] - origin) / interval;
real_t d = CLAMP((p_to_point - origin).dot(direction), 0.0f, interval);
Vector3 proj = origin + direction * d;
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real_t dist = proj.distance_squared_to(p_to_point);
if (nearest_dist < 0.0f || dist < nearest_dist) {
nearest = offset + d;
nearest_dist = dist;
}
}
return nearest;
}
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void Curve3D::set_bake_interval(real_t p_tolerance) {
bake_interval = p_tolerance;
mark_dirty();
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}
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real_t Curve3D::get_bake_interval() const {
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return bake_interval;
}
void Curve3D::set_up_vector_enabled(bool p_enable) {
up_vector_enabled = p_enable;
mark_dirty();
}
bool Curve3D::is_up_vector_enabled() const {
return up_vector_enabled;
}
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Dictionary Curve3D::_get_data() const {
Dictionary dc;
PackedVector3Array d;
d.resize(points.size() * 3);
Vector3 *w = d.ptrw();
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Vector<real_t> t;
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t.resize(points.size());
real_t *wt = t.ptrw();
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for (int i = 0; i < points.size(); i++) {
w[i * 3 + 0] = points[i].in;
w[i * 3 + 1] = points[i].out;
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w[i * 3 + 2] = points[i].position;
wt[i] = points[i].tilt;
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}
dc["points"] = d;
dc["tilts"] = t;
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return dc;
}
void Curve3D::_set_data(const Dictionary &p_data) {
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ERR_FAIL_COND(!p_data.has("points"));
ERR_FAIL_COND(!p_data.has("tilts"));
PackedVector3Array rp = p_data["points"];
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int pc = rp.size();
ERR_FAIL_COND(pc % 3 != 0);
points.resize(pc / 3);
const Vector3 *r = rp.ptr();
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Vector<real_t> rtl = p_data["tilts"];
const real_t *rt = rtl.ptr();
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for (int i = 0; i < points.size(); i++) {
points.write[i].in = r[i * 3 + 0];
points.write[i].out = r[i * 3 + 1];
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points.write[i].position = r[i * 3 + 2];
points.write[i].tilt = rt[i];
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}
mark_dirty();
notify_property_list_changed();
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}
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PackedVector3Array Curve3D::tessellate(int p_max_stages, real_t p_tolerance) const {
PackedVector3Array tess;
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if (points.size() == 0) {
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return tess;
}
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Vector<RBMap<real_t, Vector3>> midpoints;
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midpoints.resize(points.size() - 1);
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int pc = 1;
for (int i = 0; i < points.size() - 1; i++) {
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_bake_segment3d(midpoints.write[i], 0, 1, points[i].position, points[i].out, points[i + 1].position, points[i + 1].in, 0, p_max_stages, p_tolerance);
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pc++;
pc += midpoints[i].size();
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}
tess.resize(pc);
Vector3 *bpw = tess.ptrw();
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bpw[0] = points[0].position;
int pidx = 0;
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for (int i = 0; i < points.size() - 1; i++) {
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for (const KeyValue<real_t, Vector3> &E : midpoints[i]) {
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pidx++;
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bpw[pidx] = E.value;
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}
pidx++;
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bpw[pidx] = points[i + 1].position;
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}
return tess;
}
Vector<RBMap<real_t, Vector3>> Curve3D::_tessellate_even_length(int p_max_stages, real_t p_length) const {
Vector<RBMap<real_t, Vector3>> midpoints;
ERR_FAIL_COND_V_MSG(points.size() < 2, midpoints, "Curve must have at least 2 control point");
midpoints.resize(points.size() - 1);
for (int i = 0; i < points.size() - 1; i++) {
_bake_segment3d_even_length(midpoints.write[i], 0, 1, points[i].position, points[i].out, points[i + 1].position, points[i + 1].in, 0, p_max_stages, p_length);
}
return midpoints;
}
PackedVector3Array Curve3D::tessellate_even_length(int p_max_stages, real_t p_length) const {
PackedVector3Array tess;
Vector<RBMap<real_t, Vector3>> midpoints = _tessellate_even_length(p_max_stages, p_length);
if (midpoints.size() == 0) {
return tess;
}
int pc = 1;
for (int i = 0; i < points.size() - 1; i++) {
pc++;
pc += midpoints[i].size();
}
tess.resize(pc);
Vector3 *bpw = tess.ptrw();
bpw[0] = points[0].position;
int pidx = 0;
for (int i = 0; i < points.size() - 1; i++) {
for (const KeyValue<real_t, Vector3> &E : midpoints[i]) {
pidx++;
bpw[pidx] = E.value;
}
pidx++;
bpw[pidx] = points[i + 1].position;
}
return tess;
}
bool Curve3D::_set(const StringName &p_name, const Variant &p_value) {
Vector<String> components = String(p_name).split("/", true, 2);
if (components.size() >= 2 && components[0].begins_with("point_") && components[0].trim_prefix("point_").is_valid_int()) {
int point_index = components[0].trim_prefix("point_").to_int();
String property = components[1];
if (property == "position") {
set_point_position(point_index, p_value);
return true;
} else if (property == "in") {
set_point_in(point_index, p_value);
return true;
} else if (property == "out") {
set_point_out(point_index, p_value);
return true;
} else if (property == "tilt") {
set_point_tilt(point_index, p_value);
return true;
}
}
return false;
}
bool Curve3D::_get(const StringName &p_name, Variant &r_ret) const {
Vector<String> components = String(p_name).split("/", true, 2);
if (components.size() >= 2 && components[0].begins_with("point_") && components[0].trim_prefix("point_").is_valid_int()) {
int point_index = components[0].trim_prefix("point_").to_int();
String property = components[1];
if (property == "position") {
r_ret = get_point_position(point_index);
return true;
} else if (property == "in") {
r_ret = get_point_in(point_index);
return true;
} else if (property == "out") {
r_ret = get_point_out(point_index);
return true;
} else if (property == "tilt") {
r_ret = get_point_tilt(point_index);
return true;
}
}
return false;
}
void Curve3D::_get_property_list(List<PropertyInfo> *p_list) const {
for (int i = 0; i < points.size(); i++) {
PropertyInfo pi = PropertyInfo(Variant::VECTOR3, vformat("point_%d/position", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
if (i != 0) {
pi = PropertyInfo(Variant::VECTOR3, vformat("point_%d/in", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
if (i != points.size() - 1) {
pi = PropertyInfo(Variant::VECTOR3, vformat("point_%d/out", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
pi = PropertyInfo(Variant::FLOAT, vformat("point_%d/tilt", i));
pi.usage &= ~PROPERTY_USAGE_STORAGE;
p_list->push_back(pi);
}
}
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void Curve3D::_bind_methods() {
ClassDB::bind_method(D_METHOD("get_point_count"), &Curve3D::get_point_count);
ClassDB::bind_method(D_METHOD("set_point_count", "count"), &Curve3D::set_point_count);
ClassDB::bind_method(D_METHOD("add_point", "position", "in", "out", "index"), &Curve3D::add_point, DEFVAL(Vector3()), DEFVAL(Vector3()), DEFVAL(-1));
ClassDB::bind_method(D_METHOD("set_point_position", "idx", "position"), &Curve3D::set_point_position);
ClassDB::bind_method(D_METHOD("get_point_position", "idx"), &Curve3D::get_point_position);
ClassDB::bind_method(D_METHOD("set_point_tilt", "idx", "tilt"), &Curve3D::set_point_tilt);
ClassDB::bind_method(D_METHOD("get_point_tilt", "idx"), &Curve3D::get_point_tilt);
ClassDB::bind_method(D_METHOD("set_point_in", "idx", "position"), &Curve3D::set_point_in);
ClassDB::bind_method(D_METHOD("get_point_in", "idx"), &Curve3D::get_point_in);
ClassDB::bind_method(D_METHOD("set_point_out", "idx", "position"), &Curve3D::set_point_out);
ClassDB::bind_method(D_METHOD("get_point_out", "idx"), &Curve3D::get_point_out);
ClassDB::bind_method(D_METHOD("remove_point", "idx"), &Curve3D::remove_point);
ClassDB::bind_method(D_METHOD("clear_points"), &Curve3D::clear_points);
ClassDB::bind_method(D_METHOD("sample", "idx", "t"), &Curve3D::sample);
ClassDB::bind_method(D_METHOD("samplef", "fofs"), &Curve3D::samplef);
//ClassDB::bind_method(D_METHOD("bake","subdivs"),&Curve3D::bake,DEFVAL(10));
ClassDB::bind_method(D_METHOD("set_bake_interval", "distance"), &Curve3D::set_bake_interval);
ClassDB::bind_method(D_METHOD("get_bake_interval"), &Curve3D::get_bake_interval);
ClassDB::bind_method(D_METHOD("set_up_vector_enabled", "enable"), &Curve3D::set_up_vector_enabled);
ClassDB::bind_method(D_METHOD("is_up_vector_enabled"), &Curve3D::is_up_vector_enabled);
ClassDB::bind_method(D_METHOD("get_baked_length"), &Curve3D::get_baked_length);
ClassDB::bind_method(D_METHOD("sample_baked", "offset", "cubic"), &Curve3D::sample_baked, DEFVAL(0.0), DEFVAL(false));
ClassDB::bind_method(D_METHOD("sample_baked_with_rotation", "offset", "cubic", "apply_tilt"), &Curve3D::sample_baked_with_rotation, DEFVAL(0.0), DEFVAL(false), DEFVAL(false));
ClassDB::bind_method(D_METHOD("sample_baked_up_vector", "offset", "apply_tilt"), &Curve3D::sample_baked_up_vector, DEFVAL(false));
ClassDB::bind_method(D_METHOD("get_baked_points"), &Curve3D::get_baked_points);
ClassDB::bind_method(D_METHOD("get_baked_tilts"), &Curve3D::get_baked_tilts);
ClassDB::bind_method(D_METHOD("get_baked_up_vectors"), &Curve3D::get_baked_up_vectors);
ClassDB::bind_method(D_METHOD("get_closest_point", "to_point"), &Curve3D::get_closest_point);
ClassDB::bind_method(D_METHOD("get_closest_offset", "to_point"), &Curve3D::get_closest_offset);
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ClassDB::bind_method(D_METHOD("tessellate", "max_stages", "tolerance_degrees"), &Curve3D::tessellate, DEFVAL(5), DEFVAL(4));
ClassDB::bind_method(D_METHOD("tessellate_even_length", "max_stages", "tolerance_length"), &Curve3D::tessellate_even_length, DEFVAL(5), DEFVAL(0.2));
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ClassDB::bind_method(D_METHOD("_get_data"), &Curve3D::_get_data);
ClassDB::bind_method(D_METHOD("_set_data", "data"), &Curve3D::_set_data);
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ADD_PROPERTY(PropertyInfo(Variant::FLOAT, "bake_interval", PROPERTY_HINT_RANGE, "0.01,512,0.01"), "set_bake_interval", "get_bake_interval");
ADD_PROPERTY(PropertyInfo(Variant::INT, "_data", PROPERTY_HINT_NONE, "", PROPERTY_USAGE_NO_EDITOR | PROPERTY_USAGE_INTERNAL), "_set_data", "_get_data");
ADD_ARRAY_COUNT("Points", "point_count", "set_point_count", "get_point_count", "point_");
ADD_GROUP("Up Vector", "up_vector_");
ADD_PROPERTY(PropertyInfo(Variant::BOOL, "up_vector_enabled"), "set_up_vector_enabled", "is_up_vector_enabled");
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}
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Curve3D::Curve3D() {}