8e24c4a204
rejectedsoftware e.K. doesn't exist anymore since mid-2019.
670 lines
17 KiB
D
670 lines
17 KiB
D
/**
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Utility functions for array processing
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Copyright: © 2012 Sönke Ludwig
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License: Subject to the terms of the MIT license, as written in the included LICENSE.txt file.
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Authors: Sönke Ludwig
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*/
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module vibe.internal.array;
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import vibe.internal.allocator;
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import std.algorithm;
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import std.range : isInputRange, isOutputRange;
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import std.traits;
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static import std.utf;
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void removeFromArray(T)(ref T[] array, T item)
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{
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foreach( i; 0 .. array.length )
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if( array[i] is item ){
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removeFromArrayIdx(array, i);
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return;
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}
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}
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void removeFromArrayIdx(T)(ref T[] array, size_t idx)
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{
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foreach( j; idx+1 .. array.length)
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array[j-1] = array[j];
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array.length = array.length-1;
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}
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enum AppenderResetMode {
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keepData,
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freeData,
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reuseData
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}
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struct AllocAppender(ArrayType : E[], E) {
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alias ElemType = Unqual!E;
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static assert(!hasIndirections!E && !hasElaborateDestructor!E);
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private {
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ElemType[] m_data;
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ElemType[] m_remaining;
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IAllocator m_alloc;
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bool m_allocatedBuffer = false;
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}
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this(IAllocator alloc, ElemType[] initial_buffer = null)
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@safe {
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m_alloc = alloc;
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m_data = initial_buffer;
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m_remaining = initial_buffer;
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}
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@disable this(this);
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@property ArrayType data() { return cast(ArrayType)m_data[0 .. m_data.length - m_remaining.length]; }
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void reset(AppenderResetMode reset_mode = AppenderResetMode.keepData)
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{
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if (reset_mode == AppenderResetMode.keepData) m_data = null;
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else if (reset_mode == AppenderResetMode.freeData) { if (m_allocatedBuffer) m_alloc.deallocate(m_data); m_data = null; }
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m_remaining = m_data;
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}
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/** Grows the capacity of the internal buffer so that it can hold a minumum amount of elements.
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Params:
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amount = The minimum amount of elements that shall be appendable without
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triggering a re-allocation.
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*/
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void reserve(size_t amount)
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@safe {
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size_t nelems = m_data.length - m_remaining.length;
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if (!m_data.length) {
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m_data = () @trusted { return cast(ElemType[])m_alloc.allocate(amount*E.sizeof); } ();
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m_remaining = m_data;
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m_allocatedBuffer = true;
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}
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if (m_remaining.length < amount) {
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debug {
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import std.digest.crc;
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auto checksum = crc32Of(m_data[0 .. nelems]);
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}
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if (m_allocatedBuffer) () @trusted {
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auto vdata = cast(void[])m_data;
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m_alloc.reallocate(vdata, (nelems+amount)*E.sizeof);
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m_data = cast(ElemType[])vdata;
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} (); else {
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auto newdata = () @trusted { return cast(ElemType[])m_alloc.allocate((nelems+amount)*E.sizeof); } ();
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newdata[0 .. nelems] = m_data[0 .. nelems];
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m_data = newdata;
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m_allocatedBuffer = true;
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}
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debug assert(crc32Of(m_data[0 .. nelems]) == checksum);
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}
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m_remaining = m_data[nelems .. m_data.length];
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}
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void put(E el)
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@safe {
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if( m_remaining.length == 0 ) grow(1);
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m_remaining[0] = el;
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m_remaining = m_remaining[1 .. $];
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}
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void put(ArrayType arr)
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@safe {
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if (m_remaining.length < arr.length) grow(arr.length);
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m_remaining[0 .. arr.length] = arr[];
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m_remaining = m_remaining[arr.length .. $];
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}
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static if( !hasAliasing!E ){
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void put(in ElemType[] arr) @trusted {
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put(cast(ArrayType)arr);
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}
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}
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static if( is(ElemType == char) ){
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void put(dchar el)
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@trusted {
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if( el < 128 ) put(cast(char)el);
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else {
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char[4] buf;
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auto len = std.utf.encode(buf, el);
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put(cast(ArrayType)buf[0 .. len]);
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}
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}
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}
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static if( is(ElemType == wchar) ){
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void put(dchar el)
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@trusted {
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if( el < 128 ) put(cast(wchar)el);
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else {
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wchar[3] buf;
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auto len = std.utf.encode(buf, el);
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put(cast(ArrayType)buf[0 .. len]);
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}
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}
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}
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static if (!is(E == immutable) || !hasAliasing!E) {
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/** Appends a number of bytes in-place.
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The delegate will get the memory slice of the memory that follows
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the already written data. Use `reserve` to ensure that this slice
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has enough room. The delegate should overwrite as much of the
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slice as desired and then has to return the number of elements
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that should be appended (counting from the start of the slice).
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*/
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void append(scope size_t delegate(scope ElemType[] dst) del)
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{
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auto n = del(m_remaining);
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assert(n <= m_remaining.length);
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m_remaining = m_remaining[n .. $];
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}
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}
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void grow(size_t min_free)
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@safe {
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if( !m_data.length && min_free < 16 ) min_free = 16;
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auto min_size = m_data.length + min_free - m_remaining.length;
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auto new_size = max(m_data.length, 16);
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while( new_size < min_size )
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new_size = (new_size * 3) / 2;
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reserve(new_size - m_data.length + m_remaining.length);
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}
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}
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unittest {
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auto a = AllocAppender!string(theAllocator());
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a.put("Hello");
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a.put(' ');
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a.put("World");
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assert(a.data == "Hello World");
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a.reset();
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assert(a.data == "");
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}
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unittest {
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char[4] buf;
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auto a = AllocAppender!string(theAllocator(), buf);
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a.put("He");
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assert(a.data == "He");
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assert(a.data.ptr == buf.ptr);
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a.put("ll");
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assert(a.data == "Hell");
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assert(a.data.ptr == buf.ptr);
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a.put('o');
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assert(a.data == "Hello");
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assert(a.data.ptr != buf.ptr);
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}
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unittest {
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char[4] buf;
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auto a = AllocAppender!string(theAllocator(), buf);
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a.put("Hello");
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assert(a.data == "Hello");
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assert(a.data.ptr != buf.ptr);
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}
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unittest {
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auto app = AllocAppender!(int[])(theAllocator);
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app.reserve(2);
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app.append((scope mem) {
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assert(mem.length >= 2);
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mem[0] = 1;
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mem[1] = 2;
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return 2;
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});
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assert(app.data == [1, 2]);
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}
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unittest {
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auto app = AllocAppender!string(theAllocator);
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app.reserve(3);
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app.append((scope mem) {
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assert(mem.length >= 3);
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mem[0] = 'f';
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mem[1] = 'o';
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mem[2] = 'o';
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return 3;
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});
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assert(app.data == "foo");
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}
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struct FixedAppender(ArrayType : E[], size_t NELEM, E) {
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alias ElemType = Unqual!E;
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private {
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ElemType[NELEM] m_data;
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size_t m_fill;
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}
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void clear()
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{
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m_fill = 0;
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}
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void put(E el)
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{
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m_data[m_fill++] = el;
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}
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static if( is(ElemType == char) ){
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void put(dchar el)
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{
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if( el < 128 ) put(cast(char)el);
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else {
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char[4] buf;
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auto len = std.utf.encode(buf, el);
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put(cast(ArrayType)buf[0 .. len]);
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}
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}
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}
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static if( is(ElemType == wchar) ){
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void put(dchar el)
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{
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if( el < 128 ) put(cast(wchar)el);
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else {
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wchar[3] buf;
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auto len = std.utf.encode(buf, el);
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put(cast(ArrayType)buf[0 .. len]);
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}
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}
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}
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void put(ArrayType arr)
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{
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m_data[m_fill .. m_fill+arr.length] = (cast(ElemType[])arr)[];
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m_fill += arr.length;
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}
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@property ArrayType data() { return cast(ArrayType)m_data[0 .. m_fill]; }
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static if (!is(E == immutable)) {
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void reset() { m_fill = 0; }
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}
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}
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/**
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TODO: clear ring buffer fields upon removal (to run struct destructors, if T is a struct)
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*/
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struct FixedRingBuffer(T, size_t N = 0, bool INITIALIZE = true) {
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private {
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static if( N > 0 ) {
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static if (INITIALIZE) T[N] m_buffer;
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else T[N] m_buffer = void;
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} else T[] m_buffer;
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size_t m_start = 0;
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size_t m_fill = 0;
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}
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static if( N == 0 ){
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bool m_freeOnDestruct;
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this(size_t capacity) { m_buffer = new T[capacity]; }
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~this() { if (m_freeOnDestruct && m_buffer.length > 0) deleteCompat(m_buffer); }
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}
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@property bool empty() const { return m_fill == 0; }
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@property bool full() const { return m_fill == m_buffer.length; }
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@property size_t length() const { return m_fill; }
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@property size_t freeSpace() const { return m_buffer.length - m_fill; }
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@property size_t capacity() const { return m_buffer.length; }
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static if( N == 0 ){
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deprecated @property void freeOnDestruct(bool b) { m_freeOnDestruct = b; }
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/// Resets the capacity to zero and explicitly frees the memory for the buffer.
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void dispose()
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{
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deleteCompat(m_buffer);
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m_buffer = null;
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m_start = m_fill = 0;
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}
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@property void capacity(size_t new_size)
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{
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if( m_buffer.length ){
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auto newbuffer = new T[new_size];
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auto dst = newbuffer;
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auto newfill = min(m_fill, new_size);
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read(dst[0 .. newfill]);
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if (m_freeOnDestruct && m_buffer.length > 0) () @trusted {
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deleteCompat(m_buffer);
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} ();
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m_buffer = newbuffer;
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m_start = 0;
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m_fill = newfill;
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} else {
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if (m_freeOnDestruct && m_buffer.length > 0) () @trusted {
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deleteCompat(m_buffer);
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} ();
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m_buffer = new T[new_size];
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}
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}
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}
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@property ref inout(T) front() inout { assert(!empty); return m_buffer[m_start]; }
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@property ref inout(T) back() inout { assert(!empty); return m_buffer[mod(m_start+m_fill-1)]; }
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void clear()
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{
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popFrontN(length);
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assert(m_fill == 0);
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m_start = 0;
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}
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void put()(T itm) { assert(m_fill < m_buffer.length); move(itm, m_buffer[mod(m_start + m_fill++)]); }
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void put(TC : T)(scope TC[] itms)
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{
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if( !itms.length ) return;
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assert(m_fill+itms.length <= m_buffer.length);
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if( mod(m_start+m_fill) >= mod(m_start+m_fill+itms.length) ){
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size_t chunk1 = m_buffer.length - (m_start+m_fill);
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size_t chunk2 = itms.length - chunk1;
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m_buffer[m_start+m_fill .. m_buffer.length] = itms[0 .. chunk1];
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m_buffer[0 .. chunk2] = itms[chunk1 .. $];
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} else {
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m_buffer[mod(m_start+m_fill) .. mod(m_start+m_fill)+itms.length] = itms[];
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}
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m_fill += itms.length;
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}
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void putN(size_t n) { assert(m_fill+n <= m_buffer.length); m_fill += n; }
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void popFront() { assert(!empty); m_start = mod(m_start+1); m_fill--; }
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void popFrontN(size_t n) { assert(length >= n); m_start = mod(m_start + n); m_fill -= n; }
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void popBack() { assert(!empty); m_fill--; }
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void popBackN(size_t n) { assert(length >= n); m_fill -= n; }
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void removeAt(Range r)
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{
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assert(r.m_buffer is m_buffer);
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if( m_start + m_fill > m_buffer.length ){
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assert(r.m_start >= m_start && r.m_start < m_buffer.length || r.m_start < mod(m_start+m_fill));
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if( r.m_start > m_start ){
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foreach(i; r.m_start .. m_buffer.length-1)
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move(m_buffer[i+1], m_buffer[i]);
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move(m_buffer[0], m_buffer[$-1]);
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foreach(i; 0 .. mod(m_start + m_fill - 1))
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move(m_buffer[i+1], m_buffer[i]);
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} else {
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foreach(i; r.m_start .. mod(m_start + m_fill - 1))
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move(m_buffer[i+1], m_buffer[i]);
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}
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} else {
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assert(r.m_start >= m_start && r.m_start < m_start+m_fill);
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foreach(i; r.m_start .. m_start+m_fill-1)
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move(m_buffer[i+1], m_buffer[i]);
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}
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m_fill--;
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destroy(m_buffer[mod(m_start+m_fill)]); // TODO: only call destroy for non-POD T
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}
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inout(T)[] peek() inout { return m_buffer[m_start .. min(m_start+m_fill, m_buffer.length)]; }
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T[] peekDst() {
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if (!m_buffer.length) return null;
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if( m_start + m_fill < m_buffer.length ) return m_buffer[m_start+m_fill .. $];
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else return m_buffer[mod(m_start+m_fill) .. m_start];
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}
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void read(scope T[] dst)
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{
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assert(dst.length <= length);
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if( !dst.length ) return;
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if( mod(m_start) >= mod(m_start+dst.length) ){
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size_t chunk1 = m_buffer.length - m_start;
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size_t chunk2 = dst.length - chunk1;
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static if (isCopyable!T) {
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dst[0 .. chunk1] = m_buffer[m_start .. $];
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dst[chunk1 .. $] = m_buffer[0 .. chunk2];
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} else {
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foreach (i; 0 .. chunk1) move(m_buffer[m_start+i], dst[i]);
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foreach (i; chunk1 .. this.length) move(m_buffer[i-chunk1], dst[i]);
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}
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} else {
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static if (isCopyable!T) {
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dst[] = m_buffer[m_start .. m_start+dst.length];
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} else {
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foreach (i; 0 .. dst.length)
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move(m_buffer[m_start + i], dst[i]);
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}
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}
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popFrontN(dst.length);
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}
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int opApply(scope int delegate(ref T itm) del)
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{
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if( m_start+m_fill > m_buffer.length ){
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foreach(i; m_start .. m_buffer.length)
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if( auto ret = del(m_buffer[i]) )
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return ret;
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foreach(i; 0 .. mod(m_start+m_fill))
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if( auto ret = del(m_buffer[i]) )
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return ret;
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} else {
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foreach(i; m_start .. m_start+m_fill)
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if( auto ret = del(m_buffer[i]) )
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return ret;
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}
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return 0;
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}
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/// iterate through elements with index
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int opApply(scope int delegate(size_t i, ref T itm) del)
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{
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if( m_start+m_fill > m_buffer.length ){
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foreach(i; m_start .. m_buffer.length)
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if( auto ret = del(i - m_start, m_buffer[i]) )
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return ret;
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foreach(i; 0 .. mod(m_start+m_fill))
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if( auto ret = del(i + m_buffer.length - m_start, m_buffer[i]) )
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return ret;
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} else {
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foreach(i; m_start .. m_start+m_fill)
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if( auto ret = del(i - m_start, m_buffer[i]) )
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return ret;
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}
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return 0;
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}
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ref inout(T) opIndex(size_t idx) inout { assert(idx < length); return m_buffer[mod(m_start+idx)]; }
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Range opSlice() { return Range(m_buffer, m_start, m_fill); }
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Range opSlice(size_t from, size_t to)
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{
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assert(from <= to);
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assert(to <= m_fill);
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return Range(m_buffer, mod(m_start+from), to-from);
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}
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size_t opDollar(size_t dim)() const if(dim == 0) { return length; }
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private size_t mod(size_t n)
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const {
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static if( N == 0 ){
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/*static if(PotOnly){
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return x & (m_buffer.length-1);
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} else {*/
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return n % m_buffer.length;
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//}
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} else static if( ((N - 1) & N) == 0 ){
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return n & (N - 1);
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} else return n % N;
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}
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static struct Range {
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private {
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T[] m_buffer;
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size_t m_start;
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size_t m_length;
|
|
}
|
|
|
|
private this(T[] buffer, size_t start, size_t length)
|
|
{
|
|
m_buffer = buffer;
|
|
m_start = start;
|
|
m_length = length;
|
|
}
|
|
|
|
@property bool empty() const { return m_length == 0; }
|
|
|
|
@property ref inout(T) front() inout { assert(!empty); return m_buffer[m_start]; }
|
|
|
|
void popFront()
|
|
{
|
|
assert(!empty);
|
|
m_start++;
|
|
m_length--;
|
|
if( m_start >= m_buffer.length )
|
|
m_start = 0;
|
|
}
|
|
}
|
|
}
|
|
|
|
unittest {
|
|
static assert(isInputRange!(FixedRingBuffer!int) && isOutputRange!(FixedRingBuffer!int, int));
|
|
|
|
FixedRingBuffer!(int, 5) buf;
|
|
assert(buf.length == 0 && buf.freeSpace == 5); buf.put(1); // |1 . . . .
|
|
assert(buf.length == 1 && buf.freeSpace == 4); buf.put(2); // |1 2 . . .
|
|
assert(buf.length == 2 && buf.freeSpace == 3); buf.put(3); // |1 2 3 . .
|
|
assert(buf.length == 3 && buf.freeSpace == 2); buf.put(4); // |1 2 3 4 .
|
|
assert(buf.length == 4 && buf.freeSpace == 1); buf.put(5); // |1 2 3 4 5
|
|
assert(buf.length == 5 && buf.freeSpace == 0);
|
|
assert(buf.front == 1);
|
|
buf.popFront(); // .|2 3 4 5
|
|
assert(buf.front == 2);
|
|
buf.popFrontN(2); // . . .|4 5
|
|
assert(buf.front == 4);
|
|
assert(buf.length == 2 && buf.freeSpace == 3);
|
|
buf.put([6, 7, 8]); // 6 7 8|4 5
|
|
assert(buf.length == 5 && buf.freeSpace == 0);
|
|
int[5] dst;
|
|
buf.read(dst); // . . .|. .
|
|
assert(dst == [4, 5, 6, 7, 8]);
|
|
assert(buf.length == 0 && buf.freeSpace == 5);
|
|
buf.put([1, 2]); // . . .|1 2
|
|
assert(buf.length == 2 && buf.freeSpace == 3);
|
|
buf.read(dst[0 .. 2]); //|. . . . .
|
|
assert(dst[0 .. 2] == [1, 2]);
|
|
|
|
buf.put([0, 0, 0, 1, 2]); //|0 0 0 1 2
|
|
buf.popFrontN(2); //. .|0 1 2
|
|
buf.put([3, 4]); // 3 4|0 1 2
|
|
foreach(i, item; buf)
|
|
{
|
|
assert(i == item);
|
|
}
|
|
}
|
|
|
|
|
|
/// Write a single batch and drain
|
|
struct BatchBuffer(T, size_t N = 0) {
|
|
private {
|
|
size_t m_fill;
|
|
size_t m_first;
|
|
static if (N == 0) T[] m_buffer;
|
|
else T[N] m_buffer;
|
|
}
|
|
|
|
static if (N == 0) {
|
|
@property void capacity(size_t n) { assert(n >= m_fill); m_buffer.length = n; }
|
|
}
|
|
|
|
@property bool empty() const { assert(m_first < m_fill || m_fill == 0 && m_first == 0); return m_first >= m_fill; }
|
|
@property size_t capacity() const { return m_buffer.length; }
|
|
@property size_t length() const { return m_fill - m_first; }
|
|
@property ref inout(T) front() inout { assert(!empty); return m_buffer[m_first]; }
|
|
void popFront() { popFrontN(1); }
|
|
void popFrontN(size_t n) {
|
|
assert(n <= length);
|
|
m_first += n;
|
|
if (m_first == m_fill)
|
|
m_first = m_fill = 0;
|
|
}
|
|
inout(T)[] peek() inout { return m_buffer[m_first .. m_fill]; }
|
|
T[] peekDst() { assert(empty); return m_buffer; }
|
|
void putN(size_t n) { assert(empty && n <= m_buffer.length); m_fill = n; }
|
|
void putN(T[] elems) { assert(empty && elems.length <= m_buffer.length); m_buffer[0 .. elems.length] = elems[]; m_fill = elems.length; }
|
|
void read(T[] dst) {
|
|
assert(length() >= dst.length);
|
|
dst[] = m_buffer[m_first .. m_first + dst.length];
|
|
popFrontN(dst.length);
|
|
}
|
|
}
|
|
|
|
|
|
struct ArraySet(Key)
|
|
{
|
|
private {
|
|
Key[4] m_staticEntries;
|
|
Key[] m_entries;
|
|
}
|
|
|
|
@property ArraySet dup()
|
|
{
|
|
return ArraySet(m_staticEntries, m_entries.dup);
|
|
}
|
|
|
|
bool opBinaryRight(string op)(Key key) if (op == "in") { return contains(key); }
|
|
|
|
int opApply(int delegate(ref Key) del)
|
|
{
|
|
foreach (ref k; m_staticEntries)
|
|
if (k != Key.init)
|
|
if (auto ret = del(k))
|
|
return ret;
|
|
foreach (ref k; m_entries)
|
|
if (k != Key.init)
|
|
if (auto ret = del(k))
|
|
return ret;
|
|
return 0;
|
|
}
|
|
|
|
bool contains(Key key)
|
|
const {
|
|
foreach (ref k; m_staticEntries) if (k == key) return true;
|
|
foreach (ref k; m_entries) if (k == key) return true;
|
|
return false;
|
|
}
|
|
|
|
void insert(Key key)
|
|
{
|
|
if (contains(key)) return;
|
|
foreach (ref k; m_staticEntries)
|
|
if (k == Key.init) {
|
|
k = key;
|
|
return;
|
|
}
|
|
foreach (ref k; m_entries)
|
|
if (k == Key.init) {
|
|
k = key;
|
|
return;
|
|
}
|
|
m_entries ~= key;
|
|
}
|
|
|
|
void remove(Key key)
|
|
{
|
|
foreach (ref k; m_staticEntries) if (k == key) { k = Key.init; return; }
|
|
foreach (ref k; m_entries) if (k == key) { k = Key.init; return; }
|
|
}
|
|
}
|
|
|
|
private void deleteCompat(T)(ref T v)
|
|
{
|
|
static if (__VERSION__ >= 2079) {
|
|
import core.memory : __delete;
|
|
__delete(v);
|
|
} else mixin("delete v;");
|
|
}
|