mirror of
https://github.com/ziglang/zig.git
synced 2024-11-15 08:33:06 +00:00
613 lines
24 KiB
Zig
613 lines
24 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 os = std.os;
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const builtin = @import("builtin");
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const Os = builtin.Os;
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const c = std.c;
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const maxInt = std.math.maxInt;
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const Allocator = mem.Allocator;
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pub const c_allocator = &c_allocator_state;
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var c_allocator_state = Allocator{
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.reallocFn = cRealloc,
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.shrinkFn = cShrink,
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};
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fn cRealloc(self: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) ![]u8 {
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assert(new_align <= @alignOf(c_longdouble));
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const old_ptr = if (old_mem.len == 0) null else @ptrCast(*c_void, old_mem.ptr);
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const buf = c.realloc(old_ptr, new_size) orelse return error.OutOfMemory;
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return @ptrCast([*]u8, buf)[0..new_size];
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}
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fn cShrink(self: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) []u8 {
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const old_ptr = @ptrCast(*c_void, old_mem.ptr);
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const buf = c.realloc(old_ptr, new_size) orelse return old_mem[0..new_size];
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return @ptrCast([*]u8, buf)[0..new_size];
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}
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/// This allocator makes a syscall directly for every allocation and free.
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/// Thread-safe and lock-free.
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pub const DirectAllocator = struct {
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allocator: Allocator,
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heap_handle: ?HeapHandle,
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const HeapHandle = if (builtin.os == Os.windows) os.windows.HANDLE else void;
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pub fn init() DirectAllocator {
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return DirectAllocator{
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.allocator = Allocator{
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.reallocFn = realloc,
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.shrinkFn = shrink,
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},
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.heap_handle = if (builtin.os == Os.windows) null else {},
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};
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}
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pub fn deinit(self: *DirectAllocator) void {
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switch (builtin.os) {
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Os.windows => if (self.heap_handle) |heap_handle| {
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_ = os.windows.HeapDestroy(heap_handle);
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},
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else => {},
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}
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}
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fn alloc(allocator: *Allocator, n: usize, alignment: u29) error{OutOfMemory}![]u8 {
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const self = @fieldParentPtr(DirectAllocator, "allocator", allocator);
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switch (builtin.os) {
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Os.linux, Os.macosx, Os.ios, Os.freebsd, Os.netbsd => {
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const p = os.posix;
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const alloc_size = if (alignment <= os.page_size) n else n + alignment;
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const addr = p.mmap(null, alloc_size, p.PROT_READ | p.PROT_WRITE, p.MAP_PRIVATE | p.MAP_ANONYMOUS, -1, 0);
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if (addr == p.MAP_FAILED) return error.OutOfMemory;
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if (alloc_size == n) return @intToPtr([*]u8, addr)[0..n];
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const aligned_addr = (addr & ~usize(alignment - 1)) + alignment;
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// We can unmap the unused portions of our mmap, but we must only
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// pass munmap bytes that exist outside our allocated pages or it
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// will happily eat us too.
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// Since alignment > page_size, we are by definition on a page boundary.
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const unused_start = addr;
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const unused_len = aligned_addr - 1 - unused_start;
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const err = p.munmap(unused_start, unused_len);
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assert(p.getErrno(err) == 0);
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// It is impossible that there is an unoccupied page at the top of our
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// mmap.
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return @intToPtr([*]u8, aligned_addr)[0..n];
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},
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Os.windows => {
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const amt = n + alignment + @sizeOf(usize);
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const optional_heap_handle = @atomicLoad(?HeapHandle, &self.heap_handle, builtin.AtomicOrder.SeqCst);
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const heap_handle = optional_heap_handle orelse blk: {
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const hh = os.windows.HeapCreate(0, amt, 0) orelse return error.OutOfMemory;
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const other_hh = @cmpxchgStrong(?HeapHandle, &self.heap_handle, null, hh, builtin.AtomicOrder.SeqCst, builtin.AtomicOrder.SeqCst) orelse break :blk hh;
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_ = os.windows.HeapDestroy(hh);
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break :blk other_hh.?; // can't be null because of the cmpxchg
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};
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const ptr = os.windows.HeapAlloc(heap_handle, 0, amt) orelse return error.OutOfMemory;
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const root_addr = @ptrToInt(ptr);
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const adjusted_addr = mem.alignForward(root_addr, alignment);
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const record_addr = adjusted_addr + n;
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@intToPtr(*align(1) usize, record_addr).* = root_addr;
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return @intToPtr([*]u8, adjusted_addr)[0..n];
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},
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else => @compileError("Unsupported OS"),
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}
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}
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fn shrink(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) []u8 {
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switch (builtin.os) {
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Os.linux, Os.macosx, Os.ios, Os.freebsd, Os.netbsd => {
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const base_addr = @ptrToInt(old_mem.ptr);
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const old_addr_end = base_addr + old_mem.len;
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const new_addr_end = base_addr + new_size;
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const new_addr_end_rounded = mem.alignForward(new_addr_end, os.page_size);
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if (old_addr_end > new_addr_end_rounded) {
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_ = os.posix.munmap(new_addr_end_rounded, old_addr_end - new_addr_end_rounded);
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}
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return old_mem[0..new_size];
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},
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Os.windows => return realloc(allocator, old_mem, old_align, new_size, new_align) catch {
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const old_adjusted_addr = @ptrToInt(old_mem.ptr);
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const old_record_addr = old_adjusted_addr + old_mem.len;
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const root_addr = @intToPtr(*align(1) usize, old_record_addr).*;
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const old_ptr = @intToPtr(*c_void, root_addr);
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const new_record_addr = old_record_addr - new_size + old_mem.len;
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@intToPtr(*align(1) usize, new_record_addr).* = root_addr;
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return old_mem[0..new_size];
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},
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else => @compileError("Unsupported OS"),
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}
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}
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fn realloc(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) ![]u8 {
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switch (builtin.os) {
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Os.linux, Os.macosx, Os.ios, Os.freebsd, Os.netbsd => {
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if (new_size <= old_mem.len and new_align <= old_align) {
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return shrink(allocator, old_mem, old_align, new_size, new_align);
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}
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const result = try alloc(allocator, new_size, new_align);
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mem.copy(u8, result, old_mem);
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_ = os.posix.munmap(@ptrToInt(old_mem.ptr), old_mem.len);
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return result;
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},
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Os.windows => {
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if (old_mem.len == 0) return alloc(allocator, new_size, new_align);
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const self = @fieldParentPtr(DirectAllocator, "allocator", allocator);
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const old_adjusted_addr = @ptrToInt(old_mem.ptr);
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const old_record_addr = old_adjusted_addr + old_mem.len;
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const root_addr = @intToPtr(*align(1) usize, old_record_addr).*;
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const old_ptr = @intToPtr(*c_void, root_addr);
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const amt = new_size + new_align + @sizeOf(usize);
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const new_ptr = os.windows.HeapReAlloc(
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self.heap_handle.?,
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0,
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old_ptr,
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amt,
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) orelse return error.OutOfMemory;
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const offset = old_adjusted_addr - root_addr;
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const new_root_addr = @ptrToInt(new_ptr);
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const new_adjusted_addr = new_root_addr + offset;
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assert(new_adjusted_addr % new_align == 0);
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const new_record_addr = new_adjusted_addr + new_size;
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@intToPtr(*align(1) usize, new_record_addr).* = new_root_addr;
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return @intToPtr([*]u8, new_adjusted_addr)[0..new_size];
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},
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else => @compileError("Unsupported OS"),
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}
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}
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};
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/// This allocator takes an existing allocator, wraps it, and provides an interface
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/// where you can allocate without freeing, and then free it all together.
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pub const ArenaAllocator = struct {
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pub allocator: Allocator,
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child_allocator: *Allocator,
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buffer_list: std.LinkedList([]u8),
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end_index: usize,
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const BufNode = std.LinkedList([]u8).Node;
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pub fn init(child_allocator: *Allocator) ArenaAllocator {
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return ArenaAllocator{
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.allocator = Allocator{
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.reallocFn = realloc,
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.shrinkFn = shrink,
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},
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.child_allocator = child_allocator,
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.buffer_list = std.LinkedList([]u8).init(),
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.end_index = 0,
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};
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}
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pub fn deinit(self: *ArenaAllocator) void {
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var it = self.buffer_list.first;
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while (it) |node| {
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// this has to occur before the free because the free frees node
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it = node.next;
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self.child_allocator.free(node.data);
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}
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}
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fn createNode(self: *ArenaAllocator, prev_len: usize, minimum_size: usize) !*BufNode {
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const actual_min_size = minimum_size + @sizeOf(BufNode);
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var len = prev_len;
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while (true) {
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len += len / 2;
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len += os.page_size - @rem(len, os.page_size);
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if (len >= actual_min_size) break;
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}
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const buf = try self.child_allocator.alignedAlloc(u8, @alignOf(BufNode), len);
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const buf_node_slice = @bytesToSlice(BufNode, buf[0..@sizeOf(BufNode)]);
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const buf_node = &buf_node_slice[0];
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buf_node.* = BufNode{
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.data = buf,
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.prev = null,
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.next = null,
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};
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self.buffer_list.append(buf_node);
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self.end_index = 0;
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return buf_node;
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}
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fn alloc(allocator: *Allocator, n: usize, alignment: u29) ![]u8 {
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const self = @fieldParentPtr(ArenaAllocator, "allocator", allocator);
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var cur_node = if (self.buffer_list.last) |last_node| last_node else try self.createNode(0, n + alignment);
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while (true) {
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const cur_buf = cur_node.data[@sizeOf(BufNode)..];
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const addr = @ptrToInt(cur_buf.ptr) + self.end_index;
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const adjusted_addr = mem.alignForward(addr, alignment);
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const adjusted_index = self.end_index + (adjusted_addr - addr);
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const new_end_index = adjusted_index + n;
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if (new_end_index > cur_buf.len) {
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cur_node = try self.createNode(cur_buf.len, n + alignment);
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continue;
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}
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const result = cur_buf[adjusted_index..new_end_index];
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self.end_index = new_end_index;
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return result;
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}
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}
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fn realloc(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) ![]u8 {
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if (new_size <= old_mem.len and new_align <= new_size) {
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// We can't do anything with the memory, so tell the client to keep it.
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return error.OutOfMemory;
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} else {
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const result = try alloc(allocator, new_size, new_align);
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mem.copy(u8, result, old_mem);
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return result;
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}
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}
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fn shrink(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) []u8 {
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return old_mem[0..new_size];
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}
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};
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pub const FixedBufferAllocator = struct {
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allocator: Allocator,
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end_index: usize,
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buffer: []u8,
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pub fn init(buffer: []u8) FixedBufferAllocator {
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return FixedBufferAllocator{
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.allocator = Allocator{
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.reallocFn = realloc,
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.shrinkFn = shrink,
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},
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.buffer = buffer,
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.end_index = 0,
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};
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}
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fn alloc(allocator: *Allocator, n: usize, alignment: u29) ![]u8 {
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const self = @fieldParentPtr(FixedBufferAllocator, "allocator", allocator);
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const addr = @ptrToInt(self.buffer.ptr) + self.end_index;
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const adjusted_addr = mem.alignForward(addr, alignment);
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const adjusted_index = self.end_index + (adjusted_addr - addr);
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const new_end_index = adjusted_index + n;
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if (new_end_index > self.buffer.len) {
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return error.OutOfMemory;
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}
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const result = self.buffer[adjusted_index..new_end_index];
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self.end_index = new_end_index;
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return result;
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}
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fn realloc(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) ![]u8 {
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const self = @fieldParentPtr(FixedBufferAllocator, "allocator", allocator);
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assert(old_mem.len <= self.end_index);
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if (old_mem.ptr == self.buffer.ptr + self.end_index - old_mem.len and
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mem.alignForward(@ptrToInt(old_mem.ptr), new_align) == @ptrToInt(old_mem.ptr))
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{
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const start_index = self.end_index - old_mem.len;
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const new_end_index = start_index + new_size;
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if (new_end_index > self.buffer.len) return error.OutOfMemory;
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const result = self.buffer[start_index..new_end_index];
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self.end_index = new_end_index;
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return result;
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} else if (new_size <= old_mem.len and new_align <= old_align) {
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// We can't do anything with the memory, so tell the client to keep it.
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return error.OutOfMemory;
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} else {
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const result = try alloc(allocator, new_size, new_align);
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mem.copy(u8, result, old_mem);
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return result;
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}
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}
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fn shrink(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) []u8 {
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return old_mem[0..new_size];
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}
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};
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pub const ThreadSafeFixedBufferAllocator = blk: {
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if (builtin.single_threaded) {
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break :blk FixedBufferAllocator;
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} else {
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// lock free
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break :blk struct {
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allocator: Allocator,
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end_index: usize,
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buffer: []u8,
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pub fn init(buffer: []u8) ThreadSafeFixedBufferAllocator {
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return ThreadSafeFixedBufferAllocator{
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.allocator = Allocator{
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.reallocFn = realloc,
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.shrinkFn = shrink,
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},
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.buffer = buffer,
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.end_index = 0,
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};
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}
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fn alloc(allocator: *Allocator, n: usize, alignment: u29) ![]u8 {
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const self = @fieldParentPtr(ThreadSafeFixedBufferAllocator, "allocator", allocator);
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var end_index = @atomicLoad(usize, &self.end_index, builtin.AtomicOrder.SeqCst);
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while (true) {
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const addr = @ptrToInt(self.buffer.ptr) + end_index;
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const adjusted_addr = mem.alignForward(addr, alignment);
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const adjusted_index = end_index + (adjusted_addr - addr);
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const new_end_index = adjusted_index + n;
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if (new_end_index > self.buffer.len) {
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return error.OutOfMemory;
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}
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end_index = @cmpxchgWeak(usize, &self.end_index, end_index, new_end_index, builtin.AtomicOrder.SeqCst, builtin.AtomicOrder.SeqCst) orelse return self.buffer[adjusted_index..new_end_index];
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}
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}
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fn realloc(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) ![]u8 {
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if (new_size <= old_mem.len and new_align <= old_align) {
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// We can't do anything useful with the memory, tell the client to keep it.
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return error.OutOfMemory;
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} else {
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const result = try alloc(allocator, new_size, new_align);
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mem.copy(u8, result, old_mem);
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return result;
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}
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}
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fn shrink(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) []u8 {
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return old_mem[0..new_size];
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}
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};
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}
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};
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pub fn stackFallback(comptime size: usize, fallback_allocator: *Allocator) StackFallbackAllocator(size) {
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return StackFallbackAllocator(size){
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.buffer = undefined,
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.fallback_allocator = fallback_allocator,
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.fixed_buffer_allocator = undefined,
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.allocator = Allocator{
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.reallocFn = StackFallbackAllocator(size).realloc,
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.shrinkFn = StackFallbackAllocator(size).shrink,
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},
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};
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}
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pub fn StackFallbackAllocator(comptime size: usize) type {
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return struct {
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const Self = @This();
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buffer: [size]u8,
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allocator: Allocator,
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fallback_allocator: *Allocator,
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fixed_buffer_allocator: FixedBufferAllocator,
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pub fn get(self: *Self) *Allocator {
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self.fixed_buffer_allocator = FixedBufferAllocator.init(self.buffer[0..]);
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return &self.allocator;
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}
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fn realloc(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) ![]u8 {
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const self = @fieldParentPtr(Self, "allocator", allocator);
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const in_buffer = @ptrToInt(old_mem.ptr) >= @ptrToInt(&self.buffer) and
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@ptrToInt(old_mem.ptr) < @ptrToInt(&self.buffer) + self.buffer.len;
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if (in_buffer) {
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return FixedBufferAllocator.realloc(
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&self.fixed_buffer_allocator.allocator,
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old_mem,
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old_align,
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new_size,
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new_align,
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) catch {
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const result = try self.fallback_allocator.reallocFn(
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self.fallback_allocator,
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([*]u8)(undefined)[0..0],
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undefined,
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new_size,
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new_align,
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);
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mem.copy(u8, result, old_mem);
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return result;
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};
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}
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return self.fallback_allocator.reallocFn(
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self.fallback_allocator,
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old_mem,
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old_align,
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new_size,
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new_align,
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);
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}
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fn shrink(allocator: *Allocator, old_mem: []u8, old_align: u29, new_size: usize, new_align: u29) []u8 {
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const self = @fieldParentPtr(Self, "allocator", allocator);
|
|
const in_buffer = @ptrToInt(old_mem.ptr) >= @ptrToInt(&self.buffer) and
|
|
@ptrToInt(old_mem.ptr) < @ptrToInt(&self.buffer) + self.buffer.len;
|
|
if (in_buffer) {
|
|
return FixedBufferAllocator.shrink(
|
|
&self.fixed_buffer_allocator.allocator,
|
|
old_mem,
|
|
old_align,
|
|
new_size,
|
|
new_align,
|
|
);
|
|
}
|
|
return self.fallback_allocator.shrinkFn(
|
|
self.fallback_allocator,
|
|
old_mem,
|
|
old_align,
|
|
new_size,
|
|
new_align,
|
|
);
|
|
}
|
|
};
|
|
}
|
|
|
|
test "c_allocator" {
|
|
if (builtin.link_libc) {
|
|
var slice = try c_allocator.alloc(u8, 50);
|
|
defer c_allocator.free(slice);
|
|
slice = try c_allocator.realloc(slice, 100);
|
|
}
|
|
}
|
|
|
|
test "DirectAllocator" {
|
|
var direct_allocator = DirectAllocator.init();
|
|
defer direct_allocator.deinit();
|
|
|
|
const allocator = &direct_allocator.allocator;
|
|
try testAllocator(allocator);
|
|
try testAllocatorAligned(allocator, 16);
|
|
try testAllocatorLargeAlignment(allocator);
|
|
}
|
|
|
|
test "ArenaAllocator" {
|
|
var direct_allocator = DirectAllocator.init();
|
|
defer direct_allocator.deinit();
|
|
|
|
var arena_allocator = ArenaAllocator.init(&direct_allocator.allocator);
|
|
defer arena_allocator.deinit();
|
|
|
|
try testAllocator(&arena_allocator.allocator);
|
|
try testAllocatorAligned(&arena_allocator.allocator, 16);
|
|
try testAllocatorLargeAlignment(&arena_allocator.allocator);
|
|
}
|
|
|
|
var test_fixed_buffer_allocator_memory: [30000 * @sizeOf(usize)]u8 = undefined;
|
|
test "FixedBufferAllocator" {
|
|
var fixed_buffer_allocator = FixedBufferAllocator.init(test_fixed_buffer_allocator_memory[0..]);
|
|
|
|
try testAllocator(&fixed_buffer_allocator.allocator);
|
|
try testAllocatorAligned(&fixed_buffer_allocator.allocator, 16);
|
|
try testAllocatorLargeAlignment(&fixed_buffer_allocator.allocator);
|
|
}
|
|
|
|
test "FixedBufferAllocator Reuse memory on realloc" {
|
|
var small_fixed_buffer: [10]u8 = undefined;
|
|
// check if we re-use the memory
|
|
{
|
|
var fixed_buffer_allocator = FixedBufferAllocator.init(small_fixed_buffer[0..]);
|
|
|
|
var slice0 = try fixed_buffer_allocator.allocator.alloc(u8, 5);
|
|
testing.expect(slice0.len == 5);
|
|
var slice1 = try fixed_buffer_allocator.allocator.realloc(slice0, 10);
|
|
testing.expect(slice1.ptr == slice0.ptr);
|
|
testing.expect(slice1.len == 10);
|
|
testing.expectError(error.OutOfMemory, fixed_buffer_allocator.allocator.realloc(slice1, 11));
|
|
}
|
|
// check that we don't re-use the memory if it's not the most recent block
|
|
{
|
|
var fixed_buffer_allocator = FixedBufferAllocator.init(small_fixed_buffer[0..]);
|
|
|
|
var slice0 = try fixed_buffer_allocator.allocator.alloc(u8, 2);
|
|
slice0[0] = 1;
|
|
slice0[1] = 2;
|
|
var slice1 = try fixed_buffer_allocator.allocator.alloc(u8, 2);
|
|
var slice2 = try fixed_buffer_allocator.allocator.realloc(slice0, 4);
|
|
testing.expect(slice0.ptr != slice2.ptr);
|
|
testing.expect(slice1.ptr != slice2.ptr);
|
|
testing.expect(slice2[0] == 1);
|
|
testing.expect(slice2[1] == 2);
|
|
}
|
|
}
|
|
|
|
test "ThreadSafeFixedBufferAllocator" {
|
|
var fixed_buffer_allocator = ThreadSafeFixedBufferAllocator.init(test_fixed_buffer_allocator_memory[0..]);
|
|
|
|
try testAllocator(&fixed_buffer_allocator.allocator);
|
|
try testAllocatorAligned(&fixed_buffer_allocator.allocator, 16);
|
|
try testAllocatorLargeAlignment(&fixed_buffer_allocator.allocator);
|
|
}
|
|
|
|
fn testAllocator(allocator: *mem.Allocator) !void {
|
|
var slice = try allocator.alloc(*i32, 100);
|
|
testing.expect(slice.len == 100);
|
|
for (slice) |*item, i| {
|
|
item.* = try allocator.create(i32);
|
|
item.*.* = @intCast(i32, i);
|
|
}
|
|
|
|
slice = try allocator.realloc(slice, 20000);
|
|
testing.expect(slice.len == 20000);
|
|
|
|
for (slice[0..100]) |item, i| {
|
|
testing.expect(item.* == @intCast(i32, i));
|
|
allocator.destroy(item);
|
|
}
|
|
|
|
slice = allocator.shrink(slice, 50);
|
|
testing.expect(slice.len == 50);
|
|
slice = allocator.shrink(slice, 25);
|
|
testing.expect(slice.len == 25);
|
|
slice = allocator.shrink(slice, 0);
|
|
testing.expect(slice.len == 0);
|
|
slice = try allocator.realloc(slice, 10);
|
|
testing.expect(slice.len == 10);
|
|
|
|
allocator.free(slice);
|
|
}
|
|
|
|
fn testAllocatorAligned(allocator: *mem.Allocator, comptime alignment: u29) !void {
|
|
// initial
|
|
var slice = try allocator.alignedAlloc(u8, alignment, 10);
|
|
testing.expect(slice.len == 10);
|
|
// grow
|
|
slice = try allocator.realloc(slice, 100);
|
|
testing.expect(slice.len == 100);
|
|
// shrink
|
|
slice = allocator.shrink(slice, 10);
|
|
testing.expect(slice.len == 10);
|
|
// go to zero
|
|
slice = allocator.shrink(slice, 0);
|
|
testing.expect(slice.len == 0);
|
|
// realloc from zero
|
|
slice = try allocator.realloc(slice, 100);
|
|
testing.expect(slice.len == 100);
|
|
// shrink with shrink
|
|
slice = allocator.shrink(slice, 10);
|
|
testing.expect(slice.len == 10);
|
|
// shrink to zero
|
|
slice = allocator.shrink(slice, 0);
|
|
testing.expect(slice.len == 0);
|
|
}
|
|
|
|
fn testAllocatorLargeAlignment(allocator: *mem.Allocator) mem.Allocator.Error!void {
|
|
//Maybe a platform's page_size is actually the same as or
|
|
// very near usize?
|
|
if (os.page_size << 2 > maxInt(usize)) return;
|
|
|
|
const USizeShift = @IntType(false, std.math.log2(usize.bit_count));
|
|
const large_align = u29(os.page_size << 2);
|
|
|
|
var align_mask: usize = undefined;
|
|
_ = @shlWithOverflow(usize, ~usize(0), USizeShift(@ctz(large_align)), &align_mask);
|
|
|
|
var slice = try allocator.alignedAlloc(u8, large_align, 500);
|
|
testing.expect(@ptrToInt(slice.ptr) & align_mask == @ptrToInt(slice.ptr));
|
|
|
|
slice = allocator.shrink(slice, 100);
|
|
testing.expect(@ptrToInt(slice.ptr) & align_mask == @ptrToInt(slice.ptr));
|
|
|
|
slice = try allocator.realloc(slice, 5000);
|
|
testing.expect(@ptrToInt(slice.ptr) & align_mask == @ptrToInt(slice.ptr));
|
|
|
|
slice = allocator.shrink(slice, 10);
|
|
testing.expect(@ptrToInt(slice.ptr) & align_mask == @ptrToInt(slice.ptr));
|
|
|
|
slice = try allocator.realloc(slice, 20000);
|
|
testing.expect(@ptrToInt(slice.ptr) & align_mask == @ptrToInt(slice.ptr));
|
|
|
|
allocator.free(slice);
|
|
}
|