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WasmAllocator: simplify thanks to new Allocator interface

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Now it can refuse to resize when it would disturb the metadata tracking
strategy, resulting in smaller code size, a simpler implementation, and
less fragmentation.
This commit is contained in:
Andrew Kelley 2022-11-29 14:05:08 -07:00
parent 931261752d
commit 7f063b2c52
1 changed files with 31 additions and 55 deletions
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86
lib/std/heap/WasmAllocator.zig
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@ -43,14 +43,13 @@ var frees = [1]usize{0} ** size_class_count;
/// For each big size class, points to the freed pointer.
var big_frees = [1]usize{0} ** big_size_class_count;
fn alloc(ctx: *anyopaque, len: usize, alignment: u29, len_align: u29, ra: usize) Error![]u8 {
fn alloc(ctx: *anyopaque, len: usize, log2_align: u8, return_address: usize) ?[*]u8 {
_ = ctx;
_ = len_align;
_ = ra;
if (alignment > wasm.page_size) return error.OutOfMemory; // calm down
_ = return_address;
// Make room for the freelist next pointer.
const alignment = @as(usize, 1) << @intCast(Allocator.Log2Align, log2_align);
const actual_len = @max(len +| @sizeOf(usize), alignment);
const slot_size = math.ceilPowerOfTwo(usize, actual_len) catch return error.OutOfMemory;
const slot_size = math.ceilPowerOfTwo(usize, actual_len) catch return null;
const class = math.log2(slot_size) - min_class;
if (class < size_class_count) {
const addr = a: {
@ -63,7 +62,8 @@ fn alloc(ctx: *anyopaque, len: usize, alignment: u29, len_align: u29, ra: usize)
const next_addr = next_addrs[class];
if (next_addr % wasm.page_size == 0) {
const addr = try allocBigPages(1);
const addr = allocBigPages(1);
if (addr == 0) return null;
//std.debug.print("allocated fresh slot_size={d} class={d} addr=0x{x}\n", .{
// slot_size, class, addr,
//});
@ -74,77 +74,50 @@ fn alloc(ctx: *anyopaque, len: usize, alignment: u29, len_align: u29, ra: usize)
break :a next_addr;
}
};
return @intToPtr([*]u8, addr)[0..len];
return @intToPtr([*]u8, addr);
}
const bigpages_needed = bigPagesNeeded(actual_len);
const addr = try allocBigPages(bigpages_needed);
return @intToPtr([*]u8, addr)[0..len];
const addr = allocBigPages(bigpages_needed);
return @intToPtr([*]u8, addr);
}
fn resize(
ctx: *anyopaque,
buf: []u8,
buf_align: u29,
log2_buf_align: u8,
new_len: usize,
len_align: u29,
ra: usize,
) ?usize {
return_address: usize,
) bool {
_ = ctx;
_ = len_align;
_ = ra;
// We don't want to move anything from one size class to another. But we can recover bytes
// in between powers of two.
_ = return_address;
// We don't want to move anything from one size class to another, but we
// can recover bytes in between powers of two.
const buf_align = @as(usize, 1) << @intCast(Allocator.Log2Align, log2_buf_align);
const old_actual_len = @max(buf.len + @sizeOf(usize), buf_align);
const new_actual_len = @max(new_len +| @sizeOf(usize), buf_align);
const old_small_slot_size = math.ceilPowerOfTwoAssert(usize, old_actual_len);
const old_small_class = math.log2(old_small_slot_size) - min_class;
if (old_small_class < size_class_count) {
const new_small_slot_size = math.ceilPowerOfTwo(usize, new_actual_len) catch return null;
if (old_small_slot_size == new_small_slot_size) return new_len;
if (new_actual_len >= old_actual_len) return null;
const new_small_class = math.log2(new_small_slot_size) - min_class;
assert(new_small_class < old_small_class);
// Split the small allocation into frees.
var class = old_small_class - 1;
while (true) {
const slot_size = @as(usize, 1) << @intCast(ushift, class + min_class);
const upper_addr = @ptrToInt(buf.ptr) + slot_size;
const node = @intToPtr(*usize, upper_addr + (slot_size - @sizeOf(usize)));
node.* = frees[class];
frees[class] = upper_addr;
if (class == new_small_class) break;
class -= 1;
}
const new_small_slot_size = math.ceilPowerOfTwo(usize, new_actual_len) catch return false;
return old_small_slot_size == new_small_slot_size;
} else {
const old_bigpages_needed = bigPagesNeeded(old_actual_len);
const old_big_slot_pages = math.ceilPowerOfTwoAssert(usize, old_bigpages_needed);
const new_bigpages_needed = bigPagesNeeded(new_actual_len);
const new_big_slot_pages = math.ceilPowerOfTwo(usize, new_bigpages_needed) catch return null;
if (old_big_slot_pages == new_big_slot_pages) return new_len;
if (new_actual_len >= old_actual_len) return null;
const new_small_slot_size = math.ceilPowerOfTwoAssert(usize, new_actual_len);
if (new_small_slot_size < size_class_count) {
const new_small_class = math.log2(new_small_slot_size) - min_class;
// TODO: push the big allocation into the free list
_ = new_small_class;
} else {
const new_big_class = math.log2(new_big_slot_pages);
// TODO: push the upper area into the free list
_ = new_big_class;
}
const new_big_slot_pages = math.ceilPowerOfTwo(usize, new_bigpages_needed) catch return false;
return old_big_slot_pages == new_big_slot_pages;
}
return new_len;
}
fn free(
ctx: *anyopaque,
buf: []u8,
buf_align: u29,
log2_buf_align: u8,
return_address: usize,
) void {
_ = ctx;
_ = return_address;
const buf_align = @as(usize, 1) << @intCast(Allocator.Log2Align, log2_buf_align);
const actual_len = @max(buf.len + @sizeOf(usize), buf_align);
const slot_size = math.ceilPowerOfTwoAssert(usize, actual_len);
const class = math.log2(slot_size) - min_class;
@ -168,7 +141,7 @@ inline fn bigPagesNeeded(byte_count: usize) usize {
return (byte_count + (bigpage_size + (@sizeOf(usize) - 1))) / bigpage_size;
}
fn allocBigPages(n: usize) !usize {
fn allocBigPages(n: usize) usize {
const pow2_pages = math.ceilPowerOfTwoAssert(usize, n);
const slot_size_bytes = pow2_pages * bigpage_size;
const class = math.log2(pow2_pages);
@ -181,7 +154,7 @@ fn allocBigPages(n: usize) !usize {
}
const page_index = @wasmMemoryGrow(0, pow2_pages * pages_per_bigpage);
if (page_index <= 0) return error.OutOfMemory;
if (page_index <= 0) return 0;
const addr = @intCast(u32, page_index) * wasm.page_size;
return addr;
}
@ -259,13 +232,15 @@ test "shrink" {
mem.set(u8, slice, 0x11);
slice = test_ally.shrink(slice, 17);
try std.testing.expect(test_ally.resize(slice, 17));
slice = slice[0..17];
for (slice) |b| {
try std.testing.expect(b == 0x11);
}
slice = test_ally.shrink(slice, 16);
try std.testing.expect(test_ally.resize(slice, 16));
slice = slice[0..16];
for (slice) |b| {
try std.testing.expect(b == 0x11);
@ -303,11 +278,12 @@ test "shrink large object to large object" {
slice[0] = 0x12;
slice[60] = 0x34;
slice = test_ally.resize(slice, bigpage_size * 2 + 1) orelse return;
try std.testing.expect(test_ally.resize(slice, bigpage_size * 2 + 1));
slice = slice[0 .. bigpage_size * 2 + 1];
try std.testing.expect(slice[0] == 0x12);
try std.testing.expect(slice[60] == 0x34);
slice = test_ally.shrink(slice, bigpage_size * 2 + 1);
try std.testing.expect(test_ally.resize(slice, bigpage_size * 2 + 1));
try std.testing.expect(slice[0] == 0x12);
try std.testing.expect(slice[60] == 0x34);