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263 lines
7.2 KiB
D
263 lines
7.2 KiB
D
/**
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* Implementation of array assignment support routines.
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*
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*
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* Copyright: Copyright Digital Mars 2010 - 2016.
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* License: Distributed under the
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* $(LINK2 http://www.boost.org/LICENSE_1_0.txt, Boost Software License 1.0).
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* Authors: Walter Bright, Kenji Hara
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* Source: $(DRUNTIMESRC src/rt/_arrayassign.d)
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*/
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module rt.arrayassign;
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private
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{
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import rt.util.array;
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import core.stdc.string;
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import core.stdc.stdlib;
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debug(PRINTF) import core.stdc.stdio;
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}
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/**
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* Keep for backward binary compatibility. This function can be removed in the future.
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*/
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extern (C) void[] _d_arrayassign(TypeInfo ti, void[] from, void[] to)
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{
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debug(PRINTF) printf("_d_arrayassign(from = %p,%d, to = %p,%d) size = %d\n", from.ptr, from.length, to.ptr, to.length, ti.tsize);
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immutable elementSize = ti.tsize;
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// Need a temporary buffer tmp[] big enough to hold one element
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void[16] buf = void;
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void* ptmp = (elementSize > buf.sizeof) ? malloc(elementSize) : buf.ptr;
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scope (exit)
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{
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if (ptmp != buf.ptr)
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free(ptmp);
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}
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return _d_arrayassign_l(ti, from, to, ptmp);
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}
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/**
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* Does array assignment (not construction) from another
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* lvalue array of the same element type.
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* Handles overlapping copies.
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* Input:
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* ti TypeInfo of the element type.
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* dst Points target memory. Its .length is equal to the element count, not byte length.
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* src Points source memory. Its .length is equal to the element count, not byte length.
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* ptmp Temporary memory for element swapping.
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*/
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extern (C) void[] _d_arrayassign_l(TypeInfo ti, void[] src, void[] dst, void* ptmp)
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{
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debug(PRINTF) printf("_d_arrayassign_l(src = %p,%d, dst = %p,%d) size = %d\n", src.ptr, src.length, dst.ptr, dst.length, ti.tsize);
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immutable elementSize = ti.tsize;
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enforceRawArraysConformable("copy", elementSize, src, dst, true);
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if (src.ptr < dst.ptr && dst.ptr < src.ptr + elementSize * src.length)
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{
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// If dst is in the middle of src memory, use reverse order.
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for (auto i = dst.length; i--; )
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{
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void* pdst = dst.ptr + i * elementSize;
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void* psrc = src.ptr + i * elementSize;
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memcpy(ptmp, pdst, elementSize);
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memcpy(pdst, psrc, elementSize);
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ti.postblit(pdst);
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ti.destroy(ptmp);
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}
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}
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else
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{
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// Otherwise, use normal order.
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foreach (i; 0 .. dst.length)
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{
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void* pdst = dst.ptr + i * elementSize;
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void* psrc = src.ptr + i * elementSize;
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memcpy(ptmp, pdst, elementSize);
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memcpy(pdst, psrc, elementSize);
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ti.postblit(pdst);
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ti.destroy(ptmp);
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}
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}
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return dst;
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}
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unittest // Bugzilla 14024
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{
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string op;
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struct S
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{
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char x = 'x';
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this(this) { op ~= x-0x20; } // upper case
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~this() { op ~= x; } // lower case
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}
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S[4] mem;
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ref S[2] slice(int a, int b) { return mem[a .. b][0 .. 2]; }
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op = null;
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mem[0].x = 'a';
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mem[1].x = 'b';
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mem[2].x = 'x';
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mem[3].x = 'y';
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slice(0, 2) = slice(2, 4); // [ab] = [xy]
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assert(op == "XaYb", op);
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op = null;
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mem[0].x = 'x';
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mem[1].x = 'y';
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mem[2].x = 'a';
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mem[3].x = 'b';
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slice(2, 4) = slice(0, 2); // [ab] = [xy]
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assert(op == "XaYb", op);
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op = null;
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mem[0].x = 'a';
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mem[1].x = 'b';
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mem[2].x = 'c';
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slice(0, 2) = slice(1, 3); // [ab] = [bc]
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assert(op == "BaCb", op);
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op = null;
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mem[0].x = 'x';
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mem[1].x = 'y';
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mem[2].x = 'z';
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slice(1, 3) = slice(0, 2); // [yz] = [xy]
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assert(op == "YzXy", op);
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}
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/**
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* Does array assignment (not construction) from another
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* rvalue array of the same element type.
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* Input:
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* ti TypeInfo of the element type.
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* dst Points target memory. Its .length is equal to the element count, not byte length.
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* src Points source memory. Its .length is equal to the element count, not byte length.
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* It is always allocated on stack and never overlapping with dst.
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* ptmp Temporary memory for element swapping.
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*/
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extern (C) void[] _d_arrayassign_r(TypeInfo ti, void[] src, void[] dst, void* ptmp)
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{
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debug(PRINTF) printf("_d_arrayassign_r(src = %p,%d, dst = %p,%d) size = %d\n", src.ptr, src.length, dst.ptr, dst.length, ti.tsize);
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immutable elementSize = ti.tsize;
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enforceRawArraysConformable("copy", elementSize, src, dst, false);
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// Always use normal order, because we can assume that
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// the rvalue src has no overlapping with dst.
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foreach (i; 0 .. dst.length)
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{
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void* pdst = dst.ptr + i * elementSize;
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void* psrc = src.ptr + i * elementSize;
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memcpy(ptmp, pdst, elementSize);
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memcpy(pdst, psrc, elementSize);
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ti.destroy(ptmp);
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}
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return dst;
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}
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/**
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* Does array initialization (not assignment) from another
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* array of the same element type.
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* ti is the element type.
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*/
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extern (C) void[] _d_arrayctor(TypeInfo ti, void[] from, void[] to)
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{
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debug(PRINTF) printf("_d_arrayctor(from = %p,%d, to = %p,%d) size = %d\n", from.ptr, from.length, to.ptr, to.length, ti.tsize);
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auto element_size = ti.tsize;
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enforceRawArraysConformable("initialization", element_size, from, to);
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size_t i;
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try
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{
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for (i = 0; i < to.length; i++)
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{
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// Copy construction is defined as bit copy followed by postblit.
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memcpy(to.ptr + i * element_size, from.ptr + i * element_size, element_size);
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ti.postblit(to.ptr + i * element_size);
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}
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}
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catch (Throwable o)
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{
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/* Destroy, in reverse order, what we've constructed so far
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*/
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while (i--)
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{
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ti.destroy(to.ptr + i * element_size);
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}
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throw o;
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}
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return to;
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}
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/**
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* Do assignment to an array.
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* p[0 .. count] = value;
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*/
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extern (C) void* _d_arraysetassign(void* p, void* value, int count, TypeInfo ti)
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{
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void* pstart = p;
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auto element_size = ti.tsize;
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// Need a temporary buffer tmp[] big enough to hold one element
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immutable maxAllocaSize = 512;
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void *ptmp = (element_size > maxAllocaSize) ? malloc(element_size) : alloca(element_size);
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foreach (i; 0 .. count)
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{
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memcpy(ptmp, p, element_size);
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memcpy(p, value, element_size);
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ti.postblit(p);
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ti.destroy(ptmp);
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p += element_size;
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}
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if (element_size > maxAllocaSize)
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free(ptmp);
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return pstart;
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}
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/**
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* Do construction of an array.
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* ti[count] p = value;
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*/
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extern (C) void* _d_arraysetctor(void* p, void* value, int count, TypeInfo ti)
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{
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void* pstart = p;
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auto element_size = ti.tsize;
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try
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{
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foreach (i; 0 .. count)
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{
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// Copy construction is defined as bit copy followed by postblit.
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memcpy(p, value, element_size);
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ti.postblit(p);
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p += element_size;
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}
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}
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catch (Throwable o)
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{
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// Destroy, in reverse order, what we've constructed so far
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while (p > pstart)
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{
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p -= element_size;
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ti.destroy(p);
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}
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throw o;
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}
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return pstart;
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}
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