mirror of
https://github.com/ziglang/zig.git
synced 2024-11-28 08:02:32 +00:00
231a4b8fde
Removed: std.io.InStream.readUntilDelimiterBuffer Deprecated: std.ArrayList.toSlice std.ArrayList.toSliceConst std.ArrayList.at std.ArrayList.ptrAt std.ArrayList.setOrError std.ArrayList.set std.ArrayList.swapRemoveOrError std.Buffer.toSlice std.Buffer.toSliceConst std.io.InStream.readFull => std.io.InStream.readAll std.io.InStream.readAllBuffer New: std.ArrayList.span std.ArrayList.expandToCapacity std.Buffer.span std.io.InStream.readUntilDelimiterArrayList
482 lines
16 KiB
Zig
482 lines
16 KiB
Zig
const std = @import("std.zig");
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const debug = std.debug;
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const assert = debug.assert;
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const testing = std.testing;
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const mem = std.mem;
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const Allocator = mem.Allocator;
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/// A contiguous, growable list of items in memory.
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/// This is a wrapper around an array of T values. Initialize with `init`.
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pub fn ArrayList(comptime T: type) type {
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return AlignedArrayList(T, null);
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}
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pub fn AlignedArrayList(comptime T: type, comptime alignment: ?u29) type {
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if (alignment) |a| {
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if (a == @alignOf(T)) {
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return AlignedArrayList(T, null);
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}
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}
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return struct {
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const Self = @This();
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/// Use `span` instead of slicing this directly, because if you don't
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/// specify the end position of the slice, this will potentially give
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/// you uninitialized memory.
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items: Slice,
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len: usize,
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allocator: *Allocator,
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pub const Slice = if (alignment) |a| ([]align(a) T) else []T;
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pub const SliceConst = if (alignment) |a| ([]align(a) const T) else []const T;
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/// Deinitialize with `deinit` or use `toOwnedSlice`.
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pub fn init(allocator: *Allocator) Self {
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return Self{
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.items = &[_]T{},
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.len = 0,
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.allocator = allocator,
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};
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}
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/// Initialize with capacity to hold at least num elements.
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/// Deinitialize with `deinit` or use `toOwnedSlice`.
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pub fn initCapacity(allocator: *Allocator, num: usize) !Self {
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var self = Self.init(allocator);
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try self.ensureCapacity(num);
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return self;
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}
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/// Release all allocated memory.
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pub fn deinit(self: Self) void {
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self.allocator.free(self.items);
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}
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/// Return contents as a slice. Only valid while the list
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/// doesn't change size.
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pub fn span(self: var) @TypeOf(self.items[0..self.len]) {
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return self.items[0..self.len];
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}
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/// Deprecated: use `span`.
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pub fn toSlice(self: Self) Slice {
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return self.span();
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}
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/// Deprecated: use `span`.
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pub fn toSliceConst(self: Self) SliceConst {
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return self.span();
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}
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/// Deprecated: use `span()[i]`.
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pub fn at(self: Self, i: usize) T {
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return self.span()[i];
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}
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/// Deprecated: use `&span()[i]`.
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pub fn ptrAt(self: Self, i: usize) *T {
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return &self.span()[i];
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}
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/// Deprecated: use `if (i >= list.len) return error.OutOfBounds else span()[i] = item`.
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pub fn setOrError(self: Self, i: usize, item: T) !void {
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if (i >= self.len) return error.OutOfBounds;
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self.items[i] = item;
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}
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/// Deprecated: use `list.span()[i] = item`.
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pub fn set(self: *Self, i: usize, item: T) void {
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assert(i < self.len);
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self.items[i] = item;
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}
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/// Return the maximum number of items the list can hold
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/// without allocating more memory.
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pub fn capacity(self: Self) usize {
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return self.items.len;
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}
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/// ArrayList takes ownership of the passed in slice. The slice must have been
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/// allocated with `allocator`.
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/// Deinitialize with `deinit` or use `toOwnedSlice`.
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pub fn fromOwnedSlice(allocator: *Allocator, slice: Slice) Self {
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return Self{
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.items = slice,
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.len = slice.len,
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.allocator = allocator,
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};
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}
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/// The caller owns the returned memory. ArrayList becomes empty.
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pub fn toOwnedSlice(self: *Self) Slice {
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const allocator = self.allocator;
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const result = allocator.shrink(self.items, self.len);
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self.* = init(allocator);
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return result;
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}
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/// Insert `item` at index `n`. Moves `list[n .. list.len]`
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/// to make room.
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pub fn insert(self: *Self, n: usize, item: T) !void {
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try self.ensureCapacity(self.len + 1);
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self.len += 1;
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mem.copyBackwards(T, self.items[n + 1 .. self.len], self.items[n .. self.len - 1]);
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self.items[n] = item;
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}
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/// Insert slice `items` at index `i`. Moves
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/// `list[i .. list.len]` to make room.
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/// This operation is O(N).
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pub fn insertSlice(self: *Self, i: usize, items: SliceConst) !void {
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try self.ensureCapacity(self.len + items.len);
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self.len += items.len;
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mem.copyBackwards(T, self.items[i + items.len .. self.len], self.items[i .. self.len - items.len]);
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mem.copy(T, self.items[i .. i + items.len], items);
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}
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/// Extend the list by 1 element. Allocates more memory as necessary.
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pub fn append(self: *Self, item: T) !void {
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const new_item_ptr = try self.addOne();
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new_item_ptr.* = item;
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}
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/// Extend the list by 1 element, but asserting `self.capacity`
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/// is sufficient to hold an additional item.
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pub fn appendAssumeCapacity(self: *Self, item: T) void {
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const new_item_ptr = self.addOneAssumeCapacity();
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new_item_ptr.* = item;
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}
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/// Remove the element at index `i` from the list and return its value.
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/// Asserts the array has at least one item.
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/// This operation is O(N).
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pub fn orderedRemove(self: *Self, i: usize) T {
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const newlen = self.len - 1;
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if (newlen == i) return self.pop();
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const old_item = self.at(i);
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for (self.items[i..newlen]) |*b, j| b.* = self.items[i + 1 + j];
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self.items[newlen] = undefined;
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self.len = newlen;
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return old_item;
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}
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/// Removes the element at the specified index and returns it.
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/// The empty slot is filled from the end of the list.
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/// This operation is O(1).
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pub fn swapRemove(self: *Self, i: usize) T {
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if (self.len - 1 == i) return self.pop();
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const slice = self.span();
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const old_item = slice[i];
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slice[i] = self.pop();
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return old_item;
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}
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/// Deprecated: use `if (i >= list.len) return error.OutOfBounds else list.swapRemove(i)`.
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pub fn swapRemoveOrError(self: *Self, i: usize) !T {
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if (i >= self.len) return error.OutOfBounds;
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return self.swapRemove(i);
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}
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/// Append the slice of items to the list. Allocates more
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/// memory as necessary.
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pub fn appendSlice(self: *Self, items: SliceConst) !void {
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try self.ensureCapacity(self.len + items.len);
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mem.copy(T, self.items[self.len..], items);
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self.len += items.len;
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}
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/// Append a value to the list `n` times. Allocates more memory
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/// as necessary.
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pub fn appendNTimes(self: *Self, value: T, n: usize) !void {
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const old_len = self.len;
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try self.resize(self.len + n);
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mem.set(T, self.items[old_len..self.len], value);
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}
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/// Adjust the list's length to `new_len`. Doesn't initialize
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/// added items if any.
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pub fn resize(self: *Self, new_len: usize) !void {
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try self.ensureCapacity(new_len);
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self.len = new_len;
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}
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/// Reduce allocated capacity to `new_len`.
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/// Invalidates element pointers.
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pub fn shrink(self: *Self, new_len: usize) void {
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assert(new_len <= self.len);
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self.len = new_len;
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self.items = self.allocator.realloc(self.items, new_len) catch |e| switch (e) {
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error.OutOfMemory => return, // no problem, capacity is still correct then.
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};
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}
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pub fn ensureCapacity(self: *Self, new_capacity: usize) !void {
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var better_capacity = self.capacity();
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if (better_capacity >= new_capacity) return;
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while (true) {
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better_capacity += better_capacity / 2 + 8;
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if (better_capacity >= new_capacity) break;
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}
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self.items = try self.allocator.realloc(self.items, better_capacity);
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}
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/// Increases the array's length to match the full capacity that is already allocated.
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/// The new elements have `undefined` values. This operation does not invalidate any
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/// element pointers.
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pub fn expandToCapacity(self: *Self) void {
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self.len = self.items.len;
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}
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/// Increase length by 1, returning pointer to the new item.
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/// The returned pointer becomes invalid when the list is resized.
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pub fn addOne(self: *Self) !*T {
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const new_length = self.len + 1;
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try self.ensureCapacity(new_length);
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return self.addOneAssumeCapacity();
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}
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/// Increase length by 1, returning pointer to the new item.
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/// Asserts that there is already space for the new item without allocating more.
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/// The returned pointer becomes invalid when the list is resized.
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pub fn addOneAssumeCapacity(self: *Self) *T {
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assert(self.len < self.capacity());
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const result = &self.items[self.len];
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self.len += 1;
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return result;
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}
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/// Remove and return the last element from the list.
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/// Asserts the list has at least one item.
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pub fn pop(self: *Self) T {
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self.len -= 1;
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return self.items[self.len];
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}
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/// Remove and return the last element from the list.
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/// If the list is empty, returns `null`.
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pub fn popOrNull(self: *Self) ?T {
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if (self.len == 0) return null;
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return self.pop();
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}
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};
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}
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test "std.ArrayList.init" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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testing.expect(list.len == 0);
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testing.expect(list.capacity() == 0);
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}
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test "std.ArrayList.initCapacity" {
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var list = try ArrayList(i8).initCapacity(testing.allocator, 200);
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defer list.deinit();
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testing.expect(list.len == 0);
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testing.expect(list.capacity() >= 200);
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}
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test "std.ArrayList.basic" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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// setting on empty list is out of bounds
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testing.expectError(error.OutOfBounds, list.setOrError(0, 1));
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{
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var i: usize = 0;
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while (i < 10) : (i += 1) {
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list.append(@intCast(i32, i + 1)) catch unreachable;
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}
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}
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{
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var i: usize = 0;
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while (i < 10) : (i += 1) {
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testing.expect(list.items[i] == @intCast(i32, i + 1));
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}
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}
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for (list.span()) |v, i| {
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testing.expect(v == @intCast(i32, i + 1));
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}
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for (list.toSliceConst()) |v, i| {
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testing.expect(v == @intCast(i32, i + 1));
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}
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testing.expect(list.pop() == 10);
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testing.expect(list.len == 9);
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list.appendSlice(&[_]i32{ 1, 2, 3 }) catch unreachable;
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testing.expect(list.len == 12);
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testing.expect(list.pop() == 3);
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testing.expect(list.pop() == 2);
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testing.expect(list.pop() == 1);
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testing.expect(list.len == 9);
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list.appendSlice(&[_]i32{}) catch unreachable;
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testing.expect(list.len == 9);
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// can only set on indices < self.len
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list.set(7, 33);
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list.set(8, 42);
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testing.expectError(error.OutOfBounds, list.setOrError(9, 99));
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testing.expectError(error.OutOfBounds, list.setOrError(10, 123));
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testing.expect(list.pop() == 42);
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testing.expect(list.pop() == 33);
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}
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test "std.ArrayList.appendNTimes" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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try list.appendNTimes(2, 10);
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testing.expectEqual(@as(usize, 10), list.len);
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for (list.span()) |element| {
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testing.expectEqual(@as(i32, 2), element);
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}
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}
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test "std.ArrayList.appendNTimes with failing allocator" {
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var list = ArrayList(i32).init(testing.failing_allocator);
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defer list.deinit();
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testing.expectError(error.OutOfMemory, list.appendNTimes(2, 10));
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}
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test "std.ArrayList.orderedRemove" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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try list.append(1);
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try list.append(2);
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try list.append(3);
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try list.append(4);
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try list.append(5);
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try list.append(6);
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try list.append(7);
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//remove from middle
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testing.expectEqual(@as(i32, 4), list.orderedRemove(3));
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testing.expectEqual(@as(i32, 5), list.at(3));
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testing.expectEqual(@as(usize, 6), list.len);
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//remove from end
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testing.expectEqual(@as(i32, 7), list.orderedRemove(5));
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testing.expectEqual(@as(usize, 5), list.len);
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//remove from front
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testing.expectEqual(@as(i32, 1), list.orderedRemove(0));
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testing.expectEqual(@as(i32, 2), list.at(0));
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testing.expectEqual(@as(usize, 4), list.len);
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}
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test "std.ArrayList.swapRemove" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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try list.append(1);
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try list.append(2);
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try list.append(3);
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try list.append(4);
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try list.append(5);
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try list.append(6);
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try list.append(7);
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//remove from middle
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testing.expect(list.swapRemove(3) == 4);
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testing.expect(list.at(3) == 7);
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testing.expect(list.len == 6);
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//remove from end
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testing.expect(list.swapRemove(5) == 6);
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testing.expect(list.len == 5);
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//remove from front
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testing.expect(list.swapRemove(0) == 1);
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testing.expect(list.at(0) == 5);
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testing.expect(list.len == 4);
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}
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test "std.ArrayList.swapRemoveOrError" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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// Test just after initialization
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testing.expectError(error.OutOfBounds, list.swapRemoveOrError(0));
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// Test after adding one item and remote it
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try list.append(1);
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testing.expect((try list.swapRemoveOrError(0)) == 1);
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testing.expectError(error.OutOfBounds, list.swapRemoveOrError(0));
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// Test after adding two items and remote both
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try list.append(1);
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try list.append(2);
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testing.expect((try list.swapRemoveOrError(1)) == 2);
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testing.expect((try list.swapRemoveOrError(0)) == 1);
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testing.expectError(error.OutOfBounds, list.swapRemoveOrError(0));
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// Test out of bounds with one item
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try list.append(1);
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testing.expectError(error.OutOfBounds, list.swapRemoveOrError(1));
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// Test out of bounds with two items
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try list.append(2);
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testing.expectError(error.OutOfBounds, list.swapRemoveOrError(2));
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}
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test "std.ArrayList.insert" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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try list.append(1);
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try list.append(2);
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try list.append(3);
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try list.insert(0, 5);
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testing.expect(list.items[0] == 5);
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testing.expect(list.items[1] == 1);
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testing.expect(list.items[2] == 2);
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testing.expect(list.items[3] == 3);
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}
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test "std.ArrayList.insertSlice" {
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var list = ArrayList(i32).init(testing.allocator);
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defer list.deinit();
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try list.append(1);
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try list.append(2);
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try list.append(3);
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try list.append(4);
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try list.insertSlice(1, &[_]i32{ 9, 8 });
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testing.expect(list.items[0] == 1);
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testing.expect(list.items[1] == 9);
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testing.expect(list.items[2] == 8);
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testing.expect(list.items[3] == 2);
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testing.expect(list.items[4] == 3);
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testing.expect(list.items[5] == 4);
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const items = [_]i32{1};
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try list.insertSlice(0, items[0..0]);
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testing.expect(list.len == 6);
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testing.expect(list.items[0] == 1);
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}
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const Item = struct {
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integer: i32,
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sub_items: ArrayList(Item),
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};
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test "std.ArrayList: ArrayList(T) of struct T" {
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var root = Item{ .integer = 1, .sub_items = ArrayList(Item).init(testing.allocator) };
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defer root.sub_items.deinit();
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try root.sub_items.append(Item{ .integer = 42, .sub_items = ArrayList(Item).init(testing.allocator) });
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testing.expect(root.sub_items.items[0].integer == 42);
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}
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