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https://github.com/c64scene-ar/llvm-6502.git
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git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@80224 91177308-0d34-0410-b5e6-96231b3b80d8
635 lines
18 KiB
C++
635 lines
18 KiB
C++
//===- llvm/ADT/SmallVector.h - 'Normally small' vectors --------*- C++ -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines the SmallVector class.
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//
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//===----------------------------------------------------------------------===//
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#ifndef LLVM_ADT_SMALLVECTOR_H
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#define LLVM_ADT_SMALLVECTOR_H
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#include "llvm/Support/type_traits.h"
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#include <algorithm>
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#include <cassert>
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#include <cstring>
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#include <memory>
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#ifdef _MSC_VER
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namespace std {
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#if _MSC_VER <= 1310
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// Work around flawed VC++ implementation of std::uninitialized_copy. Define
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// additional overloads so that elements with pointer types are recognized as
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// scalars and not objects, causing bizarre type conversion errors.
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template<class T1, class T2>
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inline _Scalar_ptr_iterator_tag _Ptr_cat(T1 **, T2 **) {
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_Scalar_ptr_iterator_tag _Cat;
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return _Cat;
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}
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template<class T1, class T2>
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inline _Scalar_ptr_iterator_tag _Ptr_cat(T1* const *, T2 **) {
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_Scalar_ptr_iterator_tag _Cat;
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return _Cat;
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}
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#else
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// FIXME: It is not clear if the problem is fixed in VS 2005. What is clear
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// is that the above hack won't work if it wasn't fixed.
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#endif
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}
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#endif
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namespace llvm {
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/// SmallVectorImpl - This class consists of common code factored out of the
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/// SmallVector class to reduce code duplication based on the SmallVector 'N'
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/// template parameter.
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template <typename T>
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class SmallVectorImpl {
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protected:
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T *Begin, *End, *Capacity;
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// Allocate raw space for N elements of type T. If T has a ctor or dtor, we
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// don't want it to be automatically run, so we need to represent the space as
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// something else. An array of char would work great, but might not be
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// aligned sufficiently. Instead, we either use GCC extensions, or some
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// number of union instances for the space, which guarantee maximal alignment.
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protected:
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#ifdef __GNUC__
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typedef char U;
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U FirstEl __attribute__((aligned));
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#else
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union U {
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double D;
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long double LD;
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long long L;
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void *P;
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} FirstEl;
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#endif
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// Space after 'FirstEl' is clobbered, do not add any instance vars after it.
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public:
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// Default ctor - Initialize to empty.
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explicit SmallVectorImpl(unsigned N)
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: Begin(reinterpret_cast<T*>(&FirstEl)),
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End(reinterpret_cast<T*>(&FirstEl)),
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Capacity(reinterpret_cast<T*>(&FirstEl)+N) {
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}
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~SmallVectorImpl() {
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// Destroy the constructed elements in the vector.
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destroy_range(Begin, End);
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// If this wasn't grown from the inline copy, deallocate the old space.
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if (!isSmall())
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operator delete(Begin);
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}
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typedef size_t size_type;
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typedef ptrdiff_t difference_type;
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typedef T value_type;
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typedef T* iterator;
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typedef const T* const_iterator;
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typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
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typedef std::reverse_iterator<iterator> reverse_iterator;
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typedef T& reference;
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typedef const T& const_reference;
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typedef T* pointer;
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typedef const T* const_pointer;
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bool empty() const { return Begin == End; }
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size_type size() const { return End-Begin; }
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size_type max_size() const { return size_type(-1) / sizeof(T); }
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// forward iterator creation methods.
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iterator begin() { return Begin; }
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const_iterator begin() const { return Begin; }
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iterator end() { return End; }
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const_iterator end() const { return End; }
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// reverse iterator creation methods.
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reverse_iterator rbegin() { return reverse_iterator(end()); }
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const_reverse_iterator rbegin() const{ return const_reverse_iterator(end()); }
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reverse_iterator rend() { return reverse_iterator(begin()); }
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const_reverse_iterator rend() const { return const_reverse_iterator(begin());}
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reference operator[](unsigned idx) {
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assert(Begin + idx < End);
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return Begin[idx];
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}
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const_reference operator[](unsigned idx) const {
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assert(Begin + idx < End);
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return Begin[idx];
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}
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reference front() {
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return begin()[0];
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}
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const_reference front() const {
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return begin()[0];
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}
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reference back() {
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return end()[-1];
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}
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const_reference back() const {
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return end()[-1];
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}
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void push_back(const_reference Elt) {
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if (End < Capacity) {
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Retry:
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new (End) T(Elt);
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++End;
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return;
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}
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grow();
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goto Retry;
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}
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void pop_back() {
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--End;
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End->~T();
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}
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T pop_back_val() {
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T Result = back();
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pop_back();
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return Result;
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}
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void clear() {
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destroy_range(Begin, End);
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End = Begin;
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}
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void resize(unsigned N) {
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if (N < size()) {
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destroy_range(Begin+N, End);
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End = Begin+N;
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} else if (N > size()) {
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if (unsigned(Capacity-Begin) < N)
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grow(N);
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construct_range(End, Begin+N, T());
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End = Begin+N;
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}
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}
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void resize(unsigned N, const T &NV) {
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if (N < size()) {
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destroy_range(Begin+N, End);
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End = Begin+N;
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} else if (N > size()) {
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if (unsigned(Capacity-Begin) < N)
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grow(N);
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construct_range(End, Begin+N, NV);
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End = Begin+N;
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}
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}
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void reserve(unsigned N) {
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if (unsigned(Capacity-Begin) < N)
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grow(N);
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}
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void swap(SmallVectorImpl &RHS);
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/// append - Add the specified range to the end of the SmallVector.
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///
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template<typename in_iter>
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void append(in_iter in_start, in_iter in_end) {
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size_type NumInputs = std::distance(in_start, in_end);
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// Grow allocated space if needed.
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if (NumInputs > size_type(Capacity-End))
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grow(size()+NumInputs);
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// Copy the new elements over.
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std::uninitialized_copy(in_start, in_end, End);
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End += NumInputs;
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}
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/// append - Add the specified range to the end of the SmallVector.
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///
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void append(size_type NumInputs, const T &Elt) {
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// Grow allocated space if needed.
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if (NumInputs > size_type(Capacity-End))
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grow(size()+NumInputs);
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// Copy the new elements over.
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std::uninitialized_fill_n(End, NumInputs, Elt);
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End += NumInputs;
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}
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void assign(unsigned NumElts, const T &Elt) {
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clear();
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if (unsigned(Capacity-Begin) < NumElts)
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grow(NumElts);
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End = Begin+NumElts;
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construct_range(Begin, End, Elt);
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}
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iterator erase(iterator I) {
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iterator N = I;
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// Shift all elts down one.
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std::copy(I+1, End, I);
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// Drop the last elt.
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pop_back();
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return(N);
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}
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iterator erase(iterator S, iterator E) {
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iterator N = S;
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// Shift all elts down.
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iterator I = std::copy(E, End, S);
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// Drop the last elts.
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destroy_range(I, End);
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End = I;
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return(N);
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}
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iterator insert(iterator I, const T &Elt) {
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if (I == End) { // Important special case for empty vector.
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push_back(Elt);
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return end()-1;
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}
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if (End < Capacity) {
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Retry:
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new (End) T(back());
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++End;
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// Push everything else over.
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std::copy_backward(I, End-1, End);
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*I = Elt;
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return I;
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}
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size_t EltNo = I-Begin;
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grow();
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I = Begin+EltNo;
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goto Retry;
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}
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iterator insert(iterator I, size_type NumToInsert, const T &Elt) {
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if (I == End) { // Important special case for empty vector.
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append(NumToInsert, Elt);
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return end()-1;
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}
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// Convert iterator to elt# to avoid invalidating iterator when we reserve()
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size_t InsertElt = I-begin();
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// Ensure there is enough space.
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reserve(static_cast<unsigned>(size() + NumToInsert));
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// Uninvalidate the iterator.
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I = begin()+InsertElt;
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// If there are more elements between the insertion point and the end of the
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// range than there are being inserted, we can use a simple approach to
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// insertion. Since we already reserved space, we know that this won't
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// reallocate the vector.
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if (size_t(end()-I) >= NumToInsert) {
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T *OldEnd = End;
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append(End-NumToInsert, End);
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// Copy the existing elements that get replaced.
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std::copy_backward(I, OldEnd-NumToInsert, OldEnd);
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std::fill_n(I, NumToInsert, Elt);
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return I;
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}
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// Otherwise, we're inserting more elements than exist already, and we're
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// not inserting at the end.
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// Copy over the elements that we're about to overwrite.
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T *OldEnd = End;
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End += NumToInsert;
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size_t NumOverwritten = OldEnd-I;
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std::uninitialized_copy(I, OldEnd, End-NumOverwritten);
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// Replace the overwritten part.
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std::fill_n(I, NumOverwritten, Elt);
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// Insert the non-overwritten middle part.
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std::uninitialized_fill_n(OldEnd, NumToInsert-NumOverwritten, Elt);
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return I;
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}
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template<typename ItTy>
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iterator insert(iterator I, ItTy From, ItTy To) {
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if (I == End) { // Important special case for empty vector.
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append(From, To);
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return end()-1;
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}
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size_t NumToInsert = std::distance(From, To);
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// Convert iterator to elt# to avoid invalidating iterator when we reserve()
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size_t InsertElt = I-begin();
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// Ensure there is enough space.
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reserve(static_cast<unsigned>(size() + NumToInsert));
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// Uninvalidate the iterator.
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I = begin()+InsertElt;
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// If there are more elements between the insertion point and the end of the
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// range than there are being inserted, we can use a simple approach to
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// insertion. Since we already reserved space, we know that this won't
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// reallocate the vector.
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if (size_t(end()-I) >= NumToInsert) {
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T *OldEnd = End;
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append(End-NumToInsert, End);
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// Copy the existing elements that get replaced.
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std::copy_backward(I, OldEnd-NumToInsert, OldEnd);
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std::copy(From, To, I);
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return I;
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}
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// Otherwise, we're inserting more elements than exist already, and we're
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// not inserting at the end.
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// Copy over the elements that we're about to overwrite.
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T *OldEnd = End;
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End += NumToInsert;
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size_t NumOverwritten = OldEnd-I;
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std::uninitialized_copy(I, OldEnd, End-NumOverwritten);
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// Replace the overwritten part.
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std::copy(From, From+NumOverwritten, I);
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// Insert the non-overwritten middle part.
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std::uninitialized_copy(From+NumOverwritten, To, OldEnd);
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return I;
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}
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/// data - Return a pointer to the vector's buffer, even if empty().
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pointer data() {
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return pointer(Begin);
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}
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/// data - Return a pointer to the vector's buffer, even if empty().
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const_pointer data() const {
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return const_pointer(Begin);
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}
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const SmallVectorImpl &operator=(const SmallVectorImpl &RHS);
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bool operator==(const SmallVectorImpl &RHS) const {
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if (size() != RHS.size()) return false;
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for (T *This = Begin, *That = RHS.Begin, *E = Begin+size();
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This != E; ++This, ++That)
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if (*This != *That)
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return false;
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return true;
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}
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bool operator!=(const SmallVectorImpl &RHS) const { return !(*this == RHS); }
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bool operator<(const SmallVectorImpl &RHS) const {
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return std::lexicographical_compare(begin(), end(),
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RHS.begin(), RHS.end());
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}
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/// capacity - Return the total number of elements in the currently allocated
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/// buffer.
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size_t capacity() const { return Capacity - Begin; }
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/// set_size - Set the array size to \arg N, which the current array must have
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/// enough capacity for.
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///
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/// This does not construct or destroy any elements in the vector.
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///
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/// Clients can use this in conjunction with capacity() to write past the end
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/// of the buffer when they know that more elements are available, and only
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/// update the size later. This avoids the cost of value initializing elements
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/// which will only be overwritten.
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void set_size(unsigned N) {
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assert(N <= capacity());
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End = Begin + N;
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}
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private:
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/// isSmall - Return true if this is a smallvector which has not had dynamic
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/// memory allocated for it.
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bool isSmall() const {
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return static_cast<const void*>(Begin) ==
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static_cast<const void*>(&FirstEl);
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}
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/// grow - double the size of the allocated memory, guaranteeing space for at
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/// least one more element or MinSize if specified.
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void grow(size_type MinSize = 0);
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void construct_range(T *S, T *E, const T &Elt) {
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for (; S != E; ++S)
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new (S) T(Elt);
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}
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void destroy_range(T *S, T *E) {
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while (S != E) {
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--E;
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E->~T();
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}
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}
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};
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// Define this out-of-line to dissuade the C++ compiler from inlining it.
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template <typename T>
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void SmallVectorImpl<T>::grow(size_t MinSize) {
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size_t CurCapacity = Capacity-Begin;
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size_t CurSize = size();
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size_t NewCapacity = 2*CurCapacity;
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if (NewCapacity < MinSize)
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NewCapacity = MinSize;
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T *NewElts = static_cast<T*>(operator new(NewCapacity*sizeof(T)));
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// Copy the elements over.
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if (is_class<T>::value)
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std::uninitialized_copy(Begin, End, NewElts);
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else
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// Use memcpy for PODs (std::uninitialized_copy optimizes to memmove).
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memcpy(NewElts, Begin, CurSize * sizeof(T));
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// Destroy the original elements.
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destroy_range(Begin, End);
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// If this wasn't grown from the inline copy, deallocate the old space.
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if (!isSmall())
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operator delete(Begin);
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Begin = NewElts;
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End = NewElts+CurSize;
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Capacity = Begin+NewCapacity;
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}
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template <typename T>
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void SmallVectorImpl<T>::swap(SmallVectorImpl<T> &RHS) {
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if (this == &RHS) return;
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// We can only avoid copying elements if neither vector is small.
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if (!isSmall() && !RHS.isSmall()) {
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std::swap(Begin, RHS.Begin);
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std::swap(End, RHS.End);
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std::swap(Capacity, RHS.Capacity);
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return;
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}
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if (RHS.size() > size_type(Capacity-Begin))
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grow(RHS.size());
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if (size() > size_type(RHS.Capacity-RHS.begin()))
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RHS.grow(size());
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// Swap the shared elements.
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size_t NumShared = size();
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if (NumShared > RHS.size()) NumShared = RHS.size();
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for (unsigned i = 0; i != static_cast<unsigned>(NumShared); ++i)
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std::swap(Begin[i], RHS[i]);
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// Copy over the extra elts.
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if (size() > RHS.size()) {
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size_t EltDiff = size() - RHS.size();
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std::uninitialized_copy(Begin+NumShared, End, RHS.End);
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RHS.End += EltDiff;
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destroy_range(Begin+NumShared, End);
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End = Begin+NumShared;
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} else if (RHS.size() > size()) {
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size_t EltDiff = RHS.size() - size();
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std::uninitialized_copy(RHS.Begin+NumShared, RHS.End, End);
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End += EltDiff;
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destroy_range(RHS.Begin+NumShared, RHS.End);
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RHS.End = RHS.Begin+NumShared;
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}
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}
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template <typename T>
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const SmallVectorImpl<T> &
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SmallVectorImpl<T>::operator=(const SmallVectorImpl<T> &RHS) {
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// Avoid self-assignment.
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if (this == &RHS) return *this;
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// If we already have sufficient space, assign the common elements, then
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// destroy any excess.
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unsigned RHSSize = unsigned(RHS.size());
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unsigned CurSize = unsigned(size());
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if (CurSize >= RHSSize) {
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// Assign common elements.
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iterator NewEnd;
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if (RHSSize)
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NewEnd = std::copy(RHS.Begin, RHS.Begin+RHSSize, Begin);
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else
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NewEnd = Begin;
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// Destroy excess elements.
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destroy_range(NewEnd, End);
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// Trim.
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End = NewEnd;
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return *this;
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}
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// If we have to grow to have enough elements, destroy the current elements.
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// This allows us to avoid copying them during the grow.
|
|
if (unsigned(Capacity-Begin) < RHSSize) {
|
|
// Destroy current elements.
|
|
destroy_range(Begin, End);
|
|
End = Begin;
|
|
CurSize = 0;
|
|
grow(RHSSize);
|
|
} else if (CurSize) {
|
|
// Otherwise, use assignment for the already-constructed elements.
|
|
std::copy(RHS.Begin, RHS.Begin+CurSize, Begin);
|
|
}
|
|
|
|
// Copy construct the new elements in place.
|
|
std::uninitialized_copy(RHS.Begin+CurSize, RHS.End, Begin+CurSize);
|
|
|
|
// Set end.
|
|
End = Begin+RHSSize;
|
|
return *this;
|
|
}
|
|
|
|
/// SmallVector - This is a 'vector' (really, a variable-sized array), optimized
|
|
/// for the case when the array is small. It contains some number of elements
|
|
/// in-place, which allows it to avoid heap allocation when the actual number of
|
|
/// elements is below that threshold. This allows normal "small" cases to be
|
|
/// fast without losing generality for large inputs.
|
|
///
|
|
/// Note that this does not attempt to be exception safe.
|
|
///
|
|
template <typename T, unsigned N>
|
|
class SmallVector : public SmallVectorImpl<T> {
|
|
/// InlineElts - These are 'N-1' elements that are stored inline in the body
|
|
/// of the vector. The extra '1' element is stored in SmallVectorImpl.
|
|
typedef typename SmallVectorImpl<T>::U U;
|
|
enum {
|
|
// MinUs - The number of U's require to cover N T's.
|
|
MinUs = (static_cast<unsigned int>(sizeof(T))*N +
|
|
static_cast<unsigned int>(sizeof(U)) - 1) /
|
|
static_cast<unsigned int>(sizeof(U)),
|
|
|
|
// NumInlineEltsElts - The number of elements actually in this array. There
|
|
// is already one in the parent class, and we have to round up to avoid
|
|
// having a zero-element array.
|
|
NumInlineEltsElts = MinUs > 1 ? (MinUs - 1) : 1,
|
|
|
|
// NumTsAvailable - The number of T's we actually have space for, which may
|
|
// be more than N due to rounding.
|
|
NumTsAvailable = (NumInlineEltsElts+1)*static_cast<unsigned int>(sizeof(U))/
|
|
static_cast<unsigned int>(sizeof(T))
|
|
};
|
|
U InlineElts[NumInlineEltsElts];
|
|
public:
|
|
SmallVector() : SmallVectorImpl<T>(NumTsAvailable) {
|
|
}
|
|
|
|
explicit SmallVector(unsigned Size, const T &Value = T())
|
|
: SmallVectorImpl<T>(NumTsAvailable) {
|
|
this->reserve(Size);
|
|
while (Size--)
|
|
this->push_back(Value);
|
|
}
|
|
|
|
template<typename ItTy>
|
|
SmallVector(ItTy S, ItTy E) : SmallVectorImpl<T>(NumTsAvailable) {
|
|
this->append(S, E);
|
|
}
|
|
|
|
SmallVector(const SmallVector &RHS) : SmallVectorImpl<T>(NumTsAvailable) {
|
|
if (!RHS.empty())
|
|
SmallVectorImpl<T>::operator=(RHS);
|
|
}
|
|
|
|
const SmallVector &operator=(const SmallVector &RHS) {
|
|
SmallVectorImpl<T>::operator=(RHS);
|
|
return *this;
|
|
}
|
|
|
|
};
|
|
|
|
} // End llvm namespace
|
|
|
|
namespace std {
|
|
/// Implement std::swap in terms of SmallVector swap.
|
|
template<typename T>
|
|
inline void
|
|
swap(llvm::SmallVectorImpl<T> &LHS, llvm::SmallVectorImpl<T> &RHS) {
|
|
LHS.swap(RHS);
|
|
}
|
|
|
|
/// Implement std::swap in terms of SmallVector swap.
|
|
template<typename T, unsigned N>
|
|
inline void
|
|
swap(llvm::SmallVector<T, N> &LHS, llvm::SmallVector<T, N> &RHS) {
|
|
LHS.swap(RHS);
|
|
}
|
|
}
|
|
|
|
#endif
|