bsnes/nall/vector.hpp

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#pragma once
#include <new>
#include <nall/array-span.hpp>
#include <nall/array-view.hpp>
#include <nall/bit.hpp>
#include <nall/function.hpp>
Update to v106r47 release. byuu says: This is probably the largest code-change diff I've done in years. I spent four days working 10-16 hours a day reworking layouts in hiro completely. The result is we now have TableLayout, which will allow for better horizontal+vertical combined alignment. Windows, GTK2, and now GTK3 are fully supported. Windows is getting the initial window geometry wrong by a bit. GTK2 and GTK3 work perfectly. I basically abandoned trying to detect resize signals, and instead keep a list of all hiro windows that are allocated, and every time the main loop runs, it will query all of them to see if they've been resized. I'm disgusted that I have to do this, but after fighting with GTK for years, I'm about sick of it. GTK was doing this crazy thing where it would trigger another size-allocate inside of a previous size-allocate, and so my layouts would be halfway through resizing all the widgets, and then the size-allocate would kick off another one. That would end up leaving the rest of the first layout loop with bad widget sizes. And if I detected a second re-entry and blocked it, then the entire window would end up with the older geometry. I started trying to build a message queue system to allow the second layout resize to occur after the first one completed, but this was just too much madness, so I went with the simpler solution. Qt4 has some geometry problems, and doesn't show tab frame layouts properly yet. Qt5 causes an ICE error and tanks my entire Xorg display server, so ... something is seriously wrong there, and it's not hiro's fault. Creating a dummy Qt5 application without even using hiro, just int main() { TestObject object; } with object performing a dynamic\_cast to a derived type segfaults. Memory is getting corrupted where GCC allocates the vtables for classes, just by linking in Qt. Could be somehow related to the -fPIC requirement that only Qt5 has ... could just be that FreeBSD 10.1 has a buggy implementation of Qt5. I don't know. It's beyond my ability to debug, so this one's going to stay broken. The Cocoa port is busted. I'll fix it up to compile again, but that's about all I'm going to do. Many optimizations mean bsnes and higan open faster. GTK2 and GTK3 both resize windows very quickly now. higan crashes when you load a game, so that's not good. bsnes works though. bsnes also has the start of a localization engine now. Still a long way to go. The makefiles received a rather substantial restructuring. Including the ruby and hiro makefiles will add the necessary compilation rules for you, which also means that moc will run for the qt4 and qt5 targets, and windres will run for the Windows targets.
2018-07-14 03:59:29 +00:00
#include <nall/iterator.hpp>
#include <nall/maybe.hpp>
#include <nall/memory.hpp>
#include <nall/merge-sort.hpp>
#include <nall/range.hpp>
#include <nall/traits.hpp>
#include <nall/view.hpp>
namespace nall {
template<typename T>
struct vector_base {
using type = vector_base;
//core.hpp
vector_base() = default;
vector_base(const initializer_list<T>& values);
vector_base(const type& source);
vector_base(type&& source);
~vector_base();
explicit operator bool() const;
operator array_span<T>();
operator array_view<T>() const;
template<typename Cast = T> auto capacity() const -> uint64_t;
template<typename Cast = T> auto size() const -> uint64_t;
template<typename Cast = T> auto data() -> Cast*;
template<typename Cast = T> auto data() const -> const Cast*;
//assign.hpp
auto operator=(const type& source) -> type&;
auto operator=(type&& source) -> type&;
//compare.hpp
auto operator==(const type& source) const -> bool;
auto operator!=(const type& source) const -> bool;
//memory.hpp
auto reset() -> void;
2021-05-26 01:25:40 +00:00
auto acquire(T* data, uint64_t size, uint64_t capacity = 0) -> void;
auto release() -> T*;
auto reserveLeft(uint64_t capacity) -> bool;
auto reserveRight(uint64_t capacity) -> bool;
auto reserve(uint64_t capacity) -> bool { return reserveRight(capacity); }
auto reallocateLeft(uint64_t size) -> bool;
auto reallocateRight(uint64_t size) -> bool;
auto reallocate(uint64_t size) -> bool { return reallocateRight(size); }
auto resizeLeft(uint64_t size, const T& value = T()) -> bool;
auto resizeRight(uint64_t size, const T& value = T()) -> bool;
auto resize(uint64_t size, const T& value = T()) -> bool { return resizeRight(size, value); }
//access.hpp
alwaysinline auto operator[](uint64_t offset) -> T&;
alwaysinline auto operator[](uint64_t offset) const -> const T&;
alwaysinline auto operator()(uint64_t offset) -> T&;
alwaysinline auto operator()(uint64_t offset, const T& value) const -> const T&;
alwaysinline auto left() -> T&;
alwaysinline auto first() -> T& { return left(); }
alwaysinline auto left() const -> const T&;
alwaysinline auto first() const -> const T& { return left(); }
alwaysinline auto right() -> T&;
alwaysinline auto last() -> T& { return right(); }
alwaysinline auto right() const -> const T&;
alwaysinline auto last() const -> const T& { return right(); }
//modify.hpp
auto prepend(const T& value) -> void;
auto prepend(T&& value) -> void;
auto prepend(const type& values) -> void;
auto prepend(type&& values) -> void;
auto append(const T& value) -> void;
auto append(T&& value) -> void;
auto append(const type& values) -> void;
auto append(type&& values) -> void;
auto insert(uint64_t offset, const T& value) -> void;
auto removeLeft(uint64_t length = 1) -> void;
auto removeFirst(uint64_t length = 1) -> void { return removeLeft(length); }
auto removeRight(uint64_t length = 1) -> void;
auto removeLast(uint64_t length = 1) -> void { return removeRight(length); }
auto remove(uint64_t offset, uint64_t length = 1) -> void;
auto removeByIndex(uint64_t offset) -> bool;
auto removeByValue(const T& value) -> bool;
auto takeLeft() -> T;
auto takeFirst() -> T { return move(takeLeft()); }
auto takeRight() -> T;
auto takeLast() -> T { return move(takeRight()); }
auto take(uint64_t offset) -> T;
//iterator.hpp
Update to v106r47 release. byuu says: This is probably the largest code-change diff I've done in years. I spent four days working 10-16 hours a day reworking layouts in hiro completely. The result is we now have TableLayout, which will allow for better horizontal+vertical combined alignment. Windows, GTK2, and now GTK3 are fully supported. Windows is getting the initial window geometry wrong by a bit. GTK2 and GTK3 work perfectly. I basically abandoned trying to detect resize signals, and instead keep a list of all hiro windows that are allocated, and every time the main loop runs, it will query all of them to see if they've been resized. I'm disgusted that I have to do this, but after fighting with GTK for years, I'm about sick of it. GTK was doing this crazy thing where it would trigger another size-allocate inside of a previous size-allocate, and so my layouts would be halfway through resizing all the widgets, and then the size-allocate would kick off another one. That would end up leaving the rest of the first layout loop with bad widget sizes. And if I detected a second re-entry and blocked it, then the entire window would end up with the older geometry. I started trying to build a message queue system to allow the second layout resize to occur after the first one completed, but this was just too much madness, so I went with the simpler solution. Qt4 has some geometry problems, and doesn't show tab frame layouts properly yet. Qt5 causes an ICE error and tanks my entire Xorg display server, so ... something is seriously wrong there, and it's not hiro's fault. Creating a dummy Qt5 application without even using hiro, just int main() { TestObject object; } with object performing a dynamic\_cast to a derived type segfaults. Memory is getting corrupted where GCC allocates the vtables for classes, just by linking in Qt. Could be somehow related to the -fPIC requirement that only Qt5 has ... could just be that FreeBSD 10.1 has a buggy implementation of Qt5. I don't know. It's beyond my ability to debug, so this one's going to stay broken. The Cocoa port is busted. I'll fix it up to compile again, but that's about all I'm going to do. Many optimizations mean bsnes and higan open faster. GTK2 and GTK3 both resize windows very quickly now. higan crashes when you load a game, so that's not good. bsnes works though. bsnes also has the start of a localization engine now. Still a long way to go. The makefiles received a rather substantial restructuring. Including the ruby and hiro makefiles will add the necessary compilation rules for you, which also means that moc will run for the qt4 and qt5 targets, and windres will run for the Windows targets.
2018-07-14 03:59:29 +00:00
auto begin() -> iterator<T> { return {data(), 0}; }
auto end() -> iterator<T> { return {data(), size()}; }
Update to v106r47 release. byuu says: This is probably the largest code-change diff I've done in years. I spent four days working 10-16 hours a day reworking layouts in hiro completely. The result is we now have TableLayout, which will allow for better horizontal+vertical combined alignment. Windows, GTK2, and now GTK3 are fully supported. Windows is getting the initial window geometry wrong by a bit. GTK2 and GTK3 work perfectly. I basically abandoned trying to detect resize signals, and instead keep a list of all hiro windows that are allocated, and every time the main loop runs, it will query all of them to see if they've been resized. I'm disgusted that I have to do this, but after fighting with GTK for years, I'm about sick of it. GTK was doing this crazy thing where it would trigger another size-allocate inside of a previous size-allocate, and so my layouts would be halfway through resizing all the widgets, and then the size-allocate would kick off another one. That would end up leaving the rest of the first layout loop with bad widget sizes. And if I detected a second re-entry and blocked it, then the entire window would end up with the older geometry. I started trying to build a message queue system to allow the second layout resize to occur after the first one completed, but this was just too much madness, so I went with the simpler solution. Qt4 has some geometry problems, and doesn't show tab frame layouts properly yet. Qt5 causes an ICE error and tanks my entire Xorg display server, so ... something is seriously wrong there, and it's not hiro's fault. Creating a dummy Qt5 application without even using hiro, just int main() { TestObject object; } with object performing a dynamic\_cast to a derived type segfaults. Memory is getting corrupted where GCC allocates the vtables for classes, just by linking in Qt. Could be somehow related to the -fPIC requirement that only Qt5 has ... could just be that FreeBSD 10.1 has a buggy implementation of Qt5. I don't know. It's beyond my ability to debug, so this one's going to stay broken. The Cocoa port is busted. I'll fix it up to compile again, but that's about all I'm going to do. Many optimizations mean bsnes and higan open faster. GTK2 and GTK3 both resize windows very quickly now. higan crashes when you load a game, so that's not good. bsnes works though. bsnes also has the start of a localization engine now. Still a long way to go. The makefiles received a rather substantial restructuring. Including the ruby and hiro makefiles will add the necessary compilation rules for you, which also means that moc will run for the qt4 and qt5 targets, and windres will run for the Windows targets.
2018-07-14 03:59:29 +00:00
auto begin() const -> iterator_const<T> { return {data(), 0}; }
auto end() const -> iterator_const<T> { return {data(), size()}; }
auto rbegin() -> reverse_iterator<T> { return {data(), size() - 1}; }
auto rend() -> reverse_iterator<T> { return {data(), (uint64_t)-1}; }
Update to v106r47 release. byuu says: This is probably the largest code-change diff I've done in years. I spent four days working 10-16 hours a day reworking layouts in hiro completely. The result is we now have TableLayout, which will allow for better horizontal+vertical combined alignment. Windows, GTK2, and now GTK3 are fully supported. Windows is getting the initial window geometry wrong by a bit. GTK2 and GTK3 work perfectly. I basically abandoned trying to detect resize signals, and instead keep a list of all hiro windows that are allocated, and every time the main loop runs, it will query all of them to see if they've been resized. I'm disgusted that I have to do this, but after fighting with GTK for years, I'm about sick of it. GTK was doing this crazy thing where it would trigger another size-allocate inside of a previous size-allocate, and so my layouts would be halfway through resizing all the widgets, and then the size-allocate would kick off another one. That would end up leaving the rest of the first layout loop with bad widget sizes. And if I detected a second re-entry and blocked it, then the entire window would end up with the older geometry. I started trying to build a message queue system to allow the second layout resize to occur after the first one completed, but this was just too much madness, so I went with the simpler solution. Qt4 has some geometry problems, and doesn't show tab frame layouts properly yet. Qt5 causes an ICE error and tanks my entire Xorg display server, so ... something is seriously wrong there, and it's not hiro's fault. Creating a dummy Qt5 application without even using hiro, just int main() { TestObject object; } with object performing a dynamic\_cast to a derived type segfaults. Memory is getting corrupted where GCC allocates the vtables for classes, just by linking in Qt. Could be somehow related to the -fPIC requirement that only Qt5 has ... could just be that FreeBSD 10.1 has a buggy implementation of Qt5. I don't know. It's beyond my ability to debug, so this one's going to stay broken. The Cocoa port is busted. I'll fix it up to compile again, but that's about all I'm going to do. Many optimizations mean bsnes and higan open faster. GTK2 and GTK3 both resize windows very quickly now. higan crashes when you load a game, so that's not good. bsnes works though. bsnes also has the start of a localization engine now. Still a long way to go. The makefiles received a rather substantial restructuring. Including the ruby and hiro makefiles will add the necessary compilation rules for you, which also means that moc will run for the qt4 and qt5 targets, and windres will run for the Windows targets.
2018-07-14 03:59:29 +00:00
auto rbegin() const -> reverse_iterator_const<T> { return {data(), size() - 1}; }
auto rend() const -> reverse_iterator_const<T> { return {data(), (uint64_t)-1}; }
//utility.hpp
auto fill(const T& value = {}) -> void;
auto sort(const function<bool (const T& lhs, const T& rhs)>& comparator = [](auto& lhs, auto& rhs) { return lhs < rhs; }) -> void;
auto reverse() -> void;
auto find(const function<bool (const T& lhs)>& comparator) -> maybe<uint64_t>;
auto find(const T& value) const -> maybe<uint64_t>;
auto findSorted(const T& value) const -> maybe<uint64_t>;
auto foreach(const function<void (const T&)>& callback) -> void;
auto foreach(const function<void (uint, const T&)>& callback) -> void;
protected:
T* _pool = nullptr; //pointer to first initialized element in pool
uint64_t _size = 0; //number of initialized elements in pool
uint64_t _left = 0; //number of allocated elements free on the left of pool
uint64_t _right = 0; //number of allocated elements free on the right of pool
};
}
#define vector vector_base
#include <nall/vector/core.hpp>
#include <nall/vector/assign.hpp>
#include <nall/vector/compare.hpp>
#include <nall/vector/memory.hpp>
#include <nall/vector/access.hpp>
#include <nall/vector/modify.hpp>
#include <nall/vector/iterator.hpp>
#include <nall/vector/utility.hpp>
#undef vector
namespace nall {
template<typename T> struct vector : vector_base<T> {
using vector_base<T>::vector_base;
};
}
#include <nall/vector/specialization/uint8_t.hpp>