mirror of
https://github.com/mozilla/gecko-dev.git
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424 lines
15 KiB
C++
424 lines
15 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim:set ts=2 sw=2 sts=2 et cindent: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#ifndef nsTArray_h__
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# error "Don't include this file directly"
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#endif
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template<class Alloc, class Copy>
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nsTArray_base<Alloc, Copy>::nsTArray_base()
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: mHdr(EmptyHdr()) {
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MOZ_COUNT_CTOR(nsTArray_base);
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}
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template<class Alloc, class Copy>
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nsTArray_base<Alloc, Copy>::~nsTArray_base() {
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if (mHdr != EmptyHdr() && !UsesAutoArrayBuffer()) {
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Alloc::Free(mHdr);
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}
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MOZ_COUNT_DTOR(nsTArray_base);
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}
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template<class Alloc, class Copy>
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const nsTArrayHeader* nsTArray_base<Alloc, Copy>::GetAutoArrayBufferUnsafe(size_t elemAlign) const {
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// Assuming |this| points to an nsAutoArray, we want to get a pointer to
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// mAutoBuf. So just cast |this| to nsAutoArray* and read &mAutoBuf!
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const void* autoBuf = &reinterpret_cast<const nsAutoArrayBase<nsTArray<uint32_t>, 1>*>(this)->mAutoBuf;
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// If we're on a 32-bit system and elemAlign is 8, we need to adjust our
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// pointer to take into account the extra alignment in the auto array.
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static_assert(sizeof(void*) != 4 ||
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(MOZ_ALIGNOF(mozilla::AlignedElem<8>) == 8 &&
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sizeof(nsAutoTArray<mozilla::AlignedElem<8>, 1>) ==
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sizeof(void*) + sizeof(nsTArrayHeader) +
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4 + sizeof(mozilla::AlignedElem<8>)),
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"auto array padding wasn't what we expected");
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// We don't support alignments greater than 8 bytes.
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NS_ABORT_IF_FALSE(elemAlign <= 4 || elemAlign == 8, "unsupported alignment.");
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if (sizeof(void*) == 4 && elemAlign == 8) {
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autoBuf = reinterpret_cast<const char*>(autoBuf) + 4;
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}
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return reinterpret_cast<const Header*>(autoBuf);
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}
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template<class Alloc, class Copy>
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bool nsTArray_base<Alloc, Copy>::UsesAutoArrayBuffer() const {
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if (!mHdr->mIsAutoArray) {
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return false;
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}
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// This is nuts. If we were sane, we'd pass elemAlign as a parameter to
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// this function. Unfortunately this function is called in nsTArray_base's
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// destructor, at which point we don't know elem_type's alignment.
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//
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// We'll fall on our face and return true when we should say false if
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//
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// * we're not using our auto buffer,
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// * elemAlign == 4, and
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// * mHdr == GetAutoArrayBuffer(8).
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//
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// This could happen if |*this| lives on the heap and malloc allocated our
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// buffer on the heap adjacent to |*this|.
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//
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// However, we can show that this can't happen. If |this| is an auto array
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// (as we ensured at the beginning of the method), GetAutoArrayBuffer(8)
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// always points to memory owned by |*this|, because (as we assert below)
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//
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// * GetAutoArrayBuffer(8) is at most 4 bytes past GetAutoArrayBuffer(4), and
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// * sizeof(nsTArrayHeader) > 4.
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//
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// Since nsAutoTArray always contains an nsTArrayHeader,
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// GetAutoArrayBuffer(8) will always point inside the auto array object,
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// even if it doesn't point at the beginning of the header.
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//
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// Note that this means that we can't store elements with alignment 16 in an
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// nsTArray, because GetAutoArrayBuffer(16) could lie outside the memory
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// owned by this nsAutoTArray. We statically assert that elem_type's
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// alignment is 8 bytes or less in nsAutoArrayBase.
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static_assert(sizeof(nsTArrayHeader) > 4,
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"see comment above");
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#ifdef DEBUG
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ptrdiff_t diff = reinterpret_cast<const char*>(GetAutoArrayBuffer(8)) -
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reinterpret_cast<const char*>(GetAutoArrayBuffer(4));
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NS_ABORT_IF_FALSE(diff >= 0 && diff <= 4, "GetAutoArrayBuffer doesn't do what we expect.");
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#endif
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return mHdr == GetAutoArrayBuffer(4) || mHdr == GetAutoArrayBuffer(8);
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}
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// defined in nsTArray.cpp
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bool
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IsTwiceTheRequiredBytesRepresentableAsUint32(size_t capacity, size_t elemSize);
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template<class Alloc, class Copy>
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typename Alloc::ResultTypeProxy
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nsTArray_base<Alloc, Copy>::EnsureCapacity(size_type capacity, size_type elemSize) {
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// This should be the most common case so test this first
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if (capacity <= mHdr->mCapacity)
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return Alloc::SuccessResult();
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// If the requested memory allocation exceeds size_type(-1)/2, then
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// our doubling algorithm may not be able to allocate it.
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// Additionally, if it exceeds uint32_t(-1) then we couldn't fit in the
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// Header::mCapacity member. Just bail out in cases like that. We don't want
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// to be allocating 2 GB+ arrays anyway.
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if (!IsTwiceTheRequiredBytesRepresentableAsUint32(capacity, elemSize)) {
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Alloc::SizeTooBig((size_t)capacity * elemSize);
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return Alloc::FailureResult();
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}
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if (mHdr == EmptyHdr()) {
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// Malloc() new data
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Header *header = static_cast<Header*>
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(Alloc::Malloc(sizeof(Header) + capacity * elemSize));
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if (!header)
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return Alloc::FailureResult();
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header->mLength = 0;
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header->mCapacity = capacity;
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header->mIsAutoArray = 0;
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mHdr = header;
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return Alloc::SuccessResult();
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}
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// We increase our capacity so |capacity * elemSize + sizeof(Header)| is the
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// next power of two, if this value is less than pageSize bytes, or otherwise
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// so it's the next multiple of pageSize.
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const size_t pageSizeBytes = 12;
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const size_t pageSize = 1 << pageSizeBytes;
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size_t minBytes = capacity * elemSize + sizeof(Header);
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size_t bytesToAlloc;
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if (minBytes >= pageSize) {
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// Round up to the next multiple of pageSize.
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bytesToAlloc = pageSize * ((minBytes + pageSize - 1) / pageSize);
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}
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else {
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// Round up to the next power of two. See
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// http://graphics.stanford.edu/~seander/bithacks.html
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bytesToAlloc = minBytes - 1;
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bytesToAlloc |= bytesToAlloc >> 1;
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bytesToAlloc |= bytesToAlloc >> 2;
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bytesToAlloc |= bytesToAlloc >> 4;
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bytesToAlloc |= bytesToAlloc >> 8;
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bytesToAlloc |= bytesToAlloc >> 16;
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bytesToAlloc++;
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MOZ_ASSERT((bytesToAlloc & (bytesToAlloc - 1)) == 0,
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"nsTArray's allocation size should be a power of two!");
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}
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Header *header;
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if (UsesAutoArrayBuffer() || !Copy::allowRealloc) {
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// Malloc() and copy
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header = static_cast<Header*>(Alloc::Malloc(bytesToAlloc));
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if (!header)
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return Alloc::FailureResult();
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Copy::CopyHeaderAndElements(header, mHdr, Length(), elemSize);
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if (!UsesAutoArrayBuffer())
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Alloc::Free(mHdr);
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} else {
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// Realloc() existing data
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header = static_cast<Header*>(Alloc::Realloc(mHdr, bytesToAlloc));
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if (!header)
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return Alloc::FailureResult();
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}
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// How many elements can we fit in bytesToAlloc?
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size_t newCapacity = (bytesToAlloc - sizeof(Header)) / elemSize;
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MOZ_ASSERT(newCapacity >= capacity, "Didn't enlarge the array enough!");
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header->mCapacity = newCapacity;
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mHdr = header;
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return Alloc::SuccessResult();
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}
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template<class Alloc, class Copy>
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void
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nsTArray_base<Alloc, Copy>::ShrinkCapacity(size_type elemSize, size_t elemAlign) {
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if (mHdr == EmptyHdr() || UsesAutoArrayBuffer())
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return;
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if (mHdr->mLength >= mHdr->mCapacity) // should never be greater than...
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return;
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size_type length = Length();
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if (IsAutoArray() && GetAutoArrayBuffer(elemAlign)->mCapacity >= length) {
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Header* header = GetAutoArrayBuffer(elemAlign);
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// Copy data, but don't copy the header to avoid overwriting mCapacity
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header->mLength = length;
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Copy::CopyElements(header + 1, mHdr + 1, length, elemSize);
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Alloc::Free(mHdr);
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mHdr = header;
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return;
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}
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if (length == 0) {
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MOZ_ASSERT(!IsAutoArray(), "autoarray should have fit 0 elements");
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Alloc::Free(mHdr);
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mHdr = EmptyHdr();
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return;
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}
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size_type size = sizeof(Header) + length * elemSize;
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void *ptr = Alloc::Realloc(mHdr, size);
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if (!ptr)
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return;
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mHdr = static_cast<Header*>(ptr);
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mHdr->mCapacity = length;
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}
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template<class Alloc, class Copy>
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void
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nsTArray_base<Alloc, Copy>::ShiftData(index_type start,
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size_type oldLen, size_type newLen,
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size_type elemSize, size_t elemAlign) {
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if (oldLen == newLen)
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return;
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// Determine how many elements need to be shifted
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size_type num = mHdr->mLength - (start + oldLen);
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// Compute the resulting length of the array
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mHdr->mLength += newLen - oldLen;
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if (mHdr->mLength == 0) {
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ShrinkCapacity(elemSize, elemAlign);
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} else {
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// Maybe nothing needs to be shifted
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if (num == 0)
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return;
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// Perform shift (change units to bytes first)
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start *= elemSize;
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newLen *= elemSize;
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oldLen *= elemSize;
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char *base = reinterpret_cast<char*>(mHdr + 1) + start;
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Copy::MoveElements(base + newLen, base + oldLen, num, elemSize);
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}
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}
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template<class Alloc, class Copy>
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bool
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nsTArray_base<Alloc, Copy>::InsertSlotsAt(index_type index, size_type count,
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size_type elementSize, size_t elemAlign) {
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MOZ_ASSERT(index <= Length(), "Bogus insertion index");
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size_type newLen = Length() + count;
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EnsureCapacity(newLen, elementSize);
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// Check for out of memory conditions
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if (Capacity() < newLen)
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return false;
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// Move the existing elements as needed. Note that this will
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// change our mLength, so no need to call IncrementLength.
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ShiftData(index, 0, count, elementSize, elemAlign);
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return true;
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}
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// nsTArray_base::IsAutoArrayRestorer is an RAII class which takes
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// |nsTArray_base &array| in its constructor. When it's destructed, it ensures
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// that
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//
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// * array.mIsAutoArray has the same value as it did when we started, and
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// * if array has an auto buffer and mHdr would otherwise point to sEmptyHdr,
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// array.mHdr points to array's auto buffer.
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template<class Alloc, class Copy>
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nsTArray_base<Alloc, Copy>::IsAutoArrayRestorer::IsAutoArrayRestorer(
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nsTArray_base<Alloc, Copy> &array,
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size_t elemAlign)
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: mArray(array),
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mElemAlign(elemAlign),
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mIsAuto(array.IsAutoArray())
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{
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}
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template<class Alloc, class Copy>
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nsTArray_base<Alloc, Copy>::IsAutoArrayRestorer::~IsAutoArrayRestorer() {
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// Careful: We don't want to set mIsAutoArray = 1 on sEmptyHdr.
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if (mIsAuto && mArray.mHdr == mArray.EmptyHdr()) {
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// Call GetAutoArrayBufferUnsafe() because GetAutoArrayBuffer() asserts
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// that mHdr->mIsAutoArray is true, which surely isn't the case here.
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mArray.mHdr = mArray.GetAutoArrayBufferUnsafe(mElemAlign);
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mArray.mHdr->mLength = 0;
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}
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else if (mArray.mHdr != mArray.EmptyHdr()) {
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mArray.mHdr->mIsAutoArray = mIsAuto;
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}
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}
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template<class Alloc, class Copy>
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template<class Allocator>
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typename Alloc::ResultTypeProxy
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nsTArray_base<Alloc, Copy>::SwapArrayElements(nsTArray_base<Allocator, Copy>& other,
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size_type elemSize, size_t elemAlign) {
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// EnsureNotUsingAutoArrayBuffer will set mHdr = sEmptyHdr even if we have an
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// auto buffer. We need to point mHdr back to our auto buffer before we
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// return, otherwise we'll forget that we have an auto buffer at all!
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// IsAutoArrayRestorer takes care of this for us.
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IsAutoArrayRestorer ourAutoRestorer(*this, elemAlign);
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typename nsTArray_base<Allocator, Copy>::IsAutoArrayRestorer otherAutoRestorer(other, elemAlign);
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// If neither array uses an auto buffer which is big enough to store the
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// other array's elements, then ensure that both arrays use malloc'ed storage
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// and swap their mHdr pointers.
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if ((!UsesAutoArrayBuffer() || Capacity() < other.Length()) &&
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(!other.UsesAutoArrayBuffer() || other.Capacity() < Length())) {
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if (!EnsureNotUsingAutoArrayBuffer(elemSize) ||
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!other.EnsureNotUsingAutoArrayBuffer(elemSize)) {
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return Alloc::FailureResult();
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}
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Header *temp = mHdr;
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mHdr = other.mHdr;
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other.mHdr = temp;
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return Alloc::SuccessResult();
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}
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// Swap the two arrays by copying, since at least one is using an auto
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// buffer which is large enough to hold all of the other's elements. We'll
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// copy the shorter array into temporary storage.
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//
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// (We could do better than this in some circumstances. Suppose we're
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// swapping arrays X and Y. X has space for 2 elements in its auto buffer,
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// but currently has length 4, so it's using malloc'ed storage. Y has length
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// 2. When we swap X and Y, we don't need to use a temporary buffer; we can
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// write Y straight into X's auto buffer, write X's malloc'ed buffer on top
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// of Y, and then switch X to using its auto buffer.)
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if (!Alloc::Successful(EnsureCapacity(other.Length(), elemSize)) ||
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!Allocator::Successful(other.EnsureCapacity(Length(), elemSize))) {
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return Alloc::FailureResult();
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}
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// The EnsureCapacity calls above shouldn't have caused *both* arrays to
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// switch from their auto buffers to malloc'ed space.
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NS_ABORT_IF_FALSE(UsesAutoArrayBuffer() ||
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other.UsesAutoArrayBuffer(),
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"One of the arrays should be using its auto buffer.");
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size_type smallerLength = XPCOM_MIN(Length(), other.Length());
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size_type largerLength = XPCOM_MAX(Length(), other.Length());
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void *smallerElements, *largerElements;
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if (Length() <= other.Length()) {
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smallerElements = Hdr() + 1;
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largerElements = other.Hdr() + 1;
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}
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else {
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smallerElements = other.Hdr() + 1;
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largerElements = Hdr() + 1;
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}
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// Allocate temporary storage for the smaller of the two arrays. We want to
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// allocate this space on the stack, if it's not too large. Sounds like a
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// job for AutoTArray! (One of the two arrays we're swapping is using an
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// auto buffer, so we're likely not allocating a lot of space here. But one
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// could, in theory, allocate a huge AutoTArray on the heap.)
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nsAutoArrayBase<nsTArray_Impl<uint8_t, Alloc>, 64> temp;
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if (!Alloc::Successful(temp.EnsureCapacity(smallerLength, elemSize))) {
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return Alloc::FailureResult();
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}
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Copy::CopyElements(temp.Elements(), smallerElements, smallerLength, elemSize);
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Copy::CopyElements(smallerElements, largerElements, largerLength, elemSize);
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Copy::CopyElements(largerElements, temp.Elements(), smallerLength, elemSize);
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// Swap the arrays' lengths.
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NS_ABORT_IF_FALSE((other.Length() == 0 || mHdr != EmptyHdr()) &&
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(Length() == 0 || other.mHdr != EmptyHdr()),
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"Don't set sEmptyHdr's length.");
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size_type tempLength = Length();
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mHdr->mLength = other.Length();
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other.mHdr->mLength = tempLength;
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return Alloc::SuccessResult();
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}
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template<class Alloc, class Copy>
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bool
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nsTArray_base<Alloc, Copy>::EnsureNotUsingAutoArrayBuffer(size_type elemSize) {
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if (UsesAutoArrayBuffer()) {
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// If you call this on a 0-length array, we'll set that array's mHdr to
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// sEmptyHdr, in flagrant violation of the nsAutoTArray invariants. It's
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// up to you to set it back! (If you don't, the nsAutoTArray will forget
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// that it has an auto buffer.)
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if (Length() == 0) {
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mHdr = EmptyHdr();
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return true;
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}
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size_type size = sizeof(Header) + Length() * elemSize;
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Header* header = static_cast<Header*>(Alloc::Malloc(size));
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if (!header)
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return false;
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Copy::CopyHeaderAndElements(header, mHdr, Length(), elemSize);
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header->mCapacity = Length();
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mHdr = header;
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}
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return true;
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}
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