281 lines
8.9 KiB
C++
281 lines
8.9 KiB
C++
#ifndef _libslic3r_h_
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#define _libslic3r_h_
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#include "libslic3r_version.h"
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// this needs to be included early for MSVC (listing it in Build.PL is not enough)
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#include <memory>
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#include <array>
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#include <algorithm>
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#include <ostream>
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#include <iostream>
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#include <math.h>
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#include <queue>
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#include <sstream>
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#include <cstdio>
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#include <stdint.h>
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#include <stdarg.h>
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#include <vector>
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#include <cassert>
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#include <cmath>
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#include <type_traits>
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#include "Technologies.hpp"
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#include "Semver.hpp"
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#if 1
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// Saves around 32% RAM after slicing step, 6.7% after G-code export (tested on PrusaSlicer 2.2.0 final).
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using coord_t = int32_t;
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#else
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//FIXME At least FillRectilinear2 and std::boost Voronoi require coord_t to be 32bit.
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typedef int64_t coord_t;
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#endif
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using coordf_t = double;
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//FIXME This epsilon value is used for many non-related purposes:
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// For a threshold of a squared Euclidean distance,
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// for a trheshold in a difference of radians,
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// for a threshold of a cross product of two non-normalized vectors etc.
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static constexpr double EPSILON = 1e-4;
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// Scaling factor for a conversion from coord_t to coordf_t: 10e-6
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// This scaling generates a following fixed point representation with for a 32bit integer:
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// 0..4294mm with 1nm resolution
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// int32_t fits an interval of (-2147.48mm, +2147.48mm)
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// with int64_t we don't have to worry anymore about the size of the int.
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static constexpr double SCALING_FACTOR = 0.000001;
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// RESOLUTION, SCALED_RESOLUTION: Used as an error threshold for a Douglas-Peucker polyline simplification algorithm.
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static constexpr double RESOLUTION = 0.0125;
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#define SCALED_RESOLUTION (RESOLUTION / SCALING_FACTOR)
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static constexpr double PI = 3.141592653589793238;
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// When extruding a closed loop, the loop is interrupted and shortened a bit to reduce the seam.
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static constexpr double LOOP_CLIPPING_LENGTH_OVER_NOZZLE_DIAMETER = 0.15;
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// Maximum perimeter length for the loop to apply the small perimeter speed.
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#define SMALL_PERIMETER_LENGTH ((6.5 / SCALING_FACTOR) * 2 * PI)
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static constexpr double INSET_OVERLAP_TOLERANCE = 0.4;
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// 3mm ring around the top / bottom / bridging areas.
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//FIXME This is quite a lot.
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static constexpr double EXTERNAL_INFILL_MARGIN = 3.;
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//FIXME Better to use an inline function with an explicit return type.
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//inline coord_t scale_(coordf_t v) { return coord_t(floor(v / SCALING_FACTOR + 0.5f)); }
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#define scale_(val) ((val) / SCALING_FACTOR)
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#define SCALED_EPSILON scale_(EPSILON)
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#define SLIC3R_DEBUG_OUT_PATH_PREFIX "out/"
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inline std::string debug_out_path(const char *name, ...)
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{
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char buffer[2048];
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va_list args;
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va_start(args, name);
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std::vsprintf(buffer, name, args);
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va_end(args);
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return std::string(SLIC3R_DEBUG_OUT_PATH_PREFIX) + std::string(buffer);
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}
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#ifndef UNUSED
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#define UNUSED(x) (void)(x)
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#endif /* UNUSED */
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// Write slices as SVG images into out directory during the 2D processing of the slices.
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// #define SLIC3R_DEBUG_SLICE_PROCESSING
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namespace Slic3r {
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extern Semver SEMVER;
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template<typename T, typename Q>
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inline T unscale(Q v) { return T(v) * T(SCALING_FACTOR); }
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enum Axis {
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X=0,
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Y,
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Z,
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E,
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F,
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NUM_AXES,
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// For the GCodeReader to mark a parsed axis, which is not in "XYZEF", it was parsed correctly.
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UNKNOWN_AXIS = NUM_AXES,
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NUM_AXES_WITH_UNKNOWN,
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};
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template <class T>
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inline void append_to(std::vector<T> &dst, const std::vector<T> &src)
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{
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dst.insert(dst.end(), src.begin(), src.end());
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}
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template <typename T>
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inline void append(std::vector<T>& dest, const std::vector<T>& src)
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{
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if (dest.empty())
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dest = src;
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else
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dest.insert(dest.end(), src.begin(), src.end());
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}
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template <typename T>
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inline void append(std::vector<T>& dest, std::vector<T>&& src)
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{
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if (dest.empty())
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dest = std::move(src);
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else
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std::move(std::begin(src), std::end(src), std::back_inserter(dest));
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src.clear();
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src.shrink_to_fit();
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}
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// Casting an std::vector<> from one type to another type without warnings about a loss of accuracy.
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template<typename T_TO, typename T_FROM>
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std::vector<T_TO> cast(const std::vector<T_FROM> &src)
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{
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std::vector<T_TO> dst;
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dst.reserve(src.size());
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for (const T_FROM &a : src)
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dst.emplace_back((T_TO)a);
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return dst;
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}
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template <typename T>
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inline void remove_nulls(std::vector<T*> &vec)
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{
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vec.erase(
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std::remove_if(vec.begin(), vec.end(), [](const T *ptr) { return ptr == nullptr; }),
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vec.end());
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}
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template <typename T>
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inline void sort_remove_duplicates(std::vector<T> &vec)
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{
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std::sort(vec.begin(), vec.end());
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vec.erase(std::unique(vec.begin(), vec.end()), vec.end());
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}
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// Older compilers do not provide a std::make_unique template. Provide a simple one.
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template<typename T, typename... Args>
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inline std::unique_ptr<T> make_unique(Args&&... args) {
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return std::unique_ptr<T>(new T(std::forward<Args>(args)...));
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}
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// Variant of std::lower_bound() with compare predicate, but without the key.
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// This variant is very useful in case that the T type is large or it does not even have a public constructor.
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template<class ForwardIt, class LowerThanKeyPredicate>
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ForwardIt lower_bound_by_predicate(ForwardIt first, ForwardIt last, LowerThanKeyPredicate lower_thank_key)
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{
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ForwardIt it;
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typename std::iterator_traits<ForwardIt>::difference_type count, step;
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count = std::distance(first, last);
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while (count > 0) {
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it = first;
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step = count / 2;
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std::advance(it, step);
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if (lower_thank_key(*it)) {
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first = ++it;
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count -= step + 1;
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}
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else
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count = step;
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}
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return first;
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}
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// from https://en.cppreference.com/w/cpp/algorithm/lower_bound
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template<class ForwardIt, class T, class Compare=std::less<>>
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ForwardIt binary_find(ForwardIt first, ForwardIt last, const T& value, Compare comp={})
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{
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// Note: BOTH type T and the type after ForwardIt is dereferenced
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// must be implicitly convertible to BOTH Type1 and Type2, used in Compare.
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// This is stricter than lower_bound requirement (see above)
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first = std::lower_bound(first, last, value, comp);
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return first != last && !comp(value, *first) ? first : last;
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}
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// from https://en.cppreference.com/w/cpp/algorithm/lower_bound
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template<class ForwardIt, class LowerThanKeyPredicate, class EqualToKeyPredicate>
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ForwardIt binary_find_by_predicate(ForwardIt first, ForwardIt last, LowerThanKeyPredicate lower_thank_key, EqualToKeyPredicate equal_to_key)
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{
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// Note: BOTH type T and the type after ForwardIt is dereferenced
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// must be implicitly convertible to BOTH Type1 and Type2, used in Compare.
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// This is stricter than lower_bound requirement (see above)
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first = lower_bound_by_predicate(first, last, lower_thank_key);
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return first != last && equal_to_key(*first) ? first : last;
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}
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template<typename T>
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static inline T sqr(T x)
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{
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return x * x;
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}
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template <typename T>
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static inline T clamp(const T low, const T high, const T value)
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{
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return std::max(low, std::min(high, value));
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}
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template <typename T, typename Number>
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static inline T lerp(const T& a, const T& b, Number t)
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{
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assert((t >= Number(-EPSILON)) && (t <= Number(1) + Number(EPSILON)));
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return (Number(1) - t) * a + t * b;
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}
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template <typename Number>
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static inline bool is_approx(Number value, Number test_value)
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{
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return std::fabs(double(value) - double(test_value)) < double(EPSILON);
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}
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// A meta-predicate which is true for integers wider than or equal to coord_t
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template<class I> struct is_scaled_coord
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{
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static const constexpr bool value =
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std::is_integral<I>::value &&
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std::numeric_limits<I>::digits >=
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std::numeric_limits<coord_t>::digits;
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};
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// Meta predicates for floating, 'scaled coord' and generic arithmetic types
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// Can be used to restrict templates to work for only the specified set of types.
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// parameter T is the type we want to restrict
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// parameter O (Optional defaults to T) is the type that the whole expression
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// will be evaluated to.
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// e.g. template<class T> FloatingOnly<T, bool> is_nan(T val);
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// The whole template will be defined only for floating point types and the
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// return type will be bool.
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// For more info how to use, see docs for std::enable_if
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//
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template<class T, class O = T>
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using FloatingOnly = std::enable_if_t<std::is_floating_point<T>::value, O>;
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template<class T, class O = T>
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using ScaledCoordOnly = std::enable_if_t<is_scaled_coord<T>::value, O>;
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template<class T, class O = T>
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using IntegerOnly = std::enable_if_t<std::is_integral<T>::value, O>;
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template<class T, class O = T>
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using ArithmeticOnly = std::enable_if_t<std::is_arithmetic<T>::value, O>;
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template<class T, class O = T>
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using IteratorOnly = std::enable_if_t<
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!std::is_same_v<typename std::iterator_traits<T>::value_type, void>, O
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>;
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template<class T, class I, class... Args> // Arbitrary allocator can be used
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IntegerOnly<I, std::vector<T, Args...>> reserve_vector(I capacity)
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{
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std::vector<T, Args...> ret;
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if (capacity > I(0)) ret.reserve(size_t(capacity));
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return ret;
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}
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} // namespace Slic3r
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#endif
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