mirror of
https://github.com/ziglang/zig.git
synced 2024-11-27 15:42:49 +00:00
181 lines
6.1 KiB
Zig
181 lines
6.1 KiB
Zig
const assert = std.debug.assert;
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const builtin = @import("builtin");
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const AtomicOrder = builtin.AtomicOrder;
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const expect = std.testing.expect;
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/// Many reader, many writer, non-allocating, thread-safe
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/// Uses a spinlock to protect push() and pop()
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/// When building in single threaded mode, this is a simple linked list.
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pub fn Stack(comptime T: type) type {
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return struct {
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root: ?*Node,
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lock: @typeOf(lock_init),
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const lock_init = if (builtin.single_threaded) {} else u8(0);
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pub const Self = @This();
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pub const Node = struct {
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next: ?*Node,
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data: T,
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};
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pub fn init() Self {
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return Self{
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.root = null,
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.lock = lock_init,
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};
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}
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/// push operation, but only if you are the first item in the stack. if you did not succeed in
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/// being the first item in the stack, returns the other item that was there.
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pub fn pushFirst(self: *Self, node: *Node) ?*Node {
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node.next = null;
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return @cmpxchgStrong(?*Node, &self.root, null, node, AtomicOrder.SeqCst, AtomicOrder.SeqCst);
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}
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pub fn push(self: *Self, node: *Node) void {
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if (builtin.single_threaded) {
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node.next = self.root;
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self.root = node;
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} else {
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while (@atomicRmw(u8, &self.lock, builtin.AtomicRmwOp.Xchg, 1, AtomicOrder.SeqCst) != 0) {}
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defer assert(@atomicRmw(u8, &self.lock, builtin.AtomicRmwOp.Xchg, 0, AtomicOrder.SeqCst) == 1);
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node.next = self.root;
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self.root = node;
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}
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}
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pub fn pop(self: *Self) ?*Node {
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if (builtin.single_threaded) {
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const root = self.root orelse return null;
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self.root = root.next;
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return root;
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} else {
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while (@atomicRmw(u8, &self.lock, builtin.AtomicRmwOp.Xchg, 1, AtomicOrder.SeqCst) != 0) {}
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defer assert(@atomicRmw(u8, &self.lock, builtin.AtomicRmwOp.Xchg, 0, AtomicOrder.SeqCst) == 1);
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const root = self.root orelse return null;
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self.root = root.next;
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return root;
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}
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}
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pub fn isEmpty(self: *Self) bool {
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return @atomicLoad(?*Node, &self.root, AtomicOrder.SeqCst) == null;
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}
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};
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}
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const std = @import("../std.zig");
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const Context = struct {
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allocator: *std.mem.Allocator,
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stack: *Stack(i32),
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put_sum: isize,
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get_sum: isize,
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get_count: usize,
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puts_done: u8, // TODO make this a bool
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};
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// TODO add lazy evaluated build options and then put puts_per_thread behind
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// some option such as: "AggressiveMultithreadedFuzzTest". In the AppVeyor
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// CI we would use a less aggressive setting since at 1 core, while we still
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// want this test to pass, we need a smaller value since there is so much thrashing
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// we would also use a less aggressive setting when running in valgrind
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const puts_per_thread = 500;
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const put_thread_count = 3;
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test "std.atomic.stack" {
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if (builtin.os == .dragonfly) return error.SkipZigTest;
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var plenty_of_memory = try std.heap.direct_allocator.alloc(u8, 300 * 1024);
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defer std.heap.direct_allocator.free(plenty_of_memory);
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var fixed_buffer_allocator = std.heap.ThreadSafeFixedBufferAllocator.init(plenty_of_memory);
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var a = &fixed_buffer_allocator.allocator;
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var stack = Stack(i32).init();
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var context = Context{
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.allocator = a,
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.stack = &stack,
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.put_sum = 0,
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.get_sum = 0,
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.puts_done = 0,
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.get_count = 0,
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};
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if (builtin.single_threaded) {
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{
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var i: usize = 0;
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while (i < put_thread_count) : (i += 1) {
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expect(startPuts(&context) == 0);
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}
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}
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context.puts_done = 1;
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{
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var i: usize = 0;
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while (i < put_thread_count) : (i += 1) {
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expect(startGets(&context) == 0);
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}
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}
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} else {
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var putters: [put_thread_count]*std.Thread = undefined;
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for (putters) |*t| {
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t.* = try std.Thread.spawn(&context, startPuts);
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}
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var getters: [put_thread_count]*std.Thread = undefined;
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for (getters) |*t| {
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t.* = try std.Thread.spawn(&context, startGets);
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}
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for (putters) |t|
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t.wait();
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_ = @atomicRmw(u8, &context.puts_done, builtin.AtomicRmwOp.Xchg, 1, AtomicOrder.SeqCst);
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for (getters) |t|
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t.wait();
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}
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if (context.put_sum != context.get_sum) {
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std.debug.panic("failure\nput_sum:{} != get_sum:{}", context.put_sum, context.get_sum);
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}
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if (context.get_count != puts_per_thread * put_thread_count) {
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std.debug.panic(
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"failure\nget_count:{} != puts_per_thread:{} * put_thread_count:{}",
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context.get_count,
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u32(puts_per_thread),
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u32(put_thread_count),
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);
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}
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}
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fn startPuts(ctx: *Context) u8 {
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var put_count: usize = puts_per_thread;
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var r = std.rand.DefaultPrng.init(0xdeadbeef);
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while (put_count != 0) : (put_count -= 1) {
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std.time.sleep(1); // let the os scheduler be our fuzz
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const x = @bitCast(i32, r.random.scalar(u32));
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const node = ctx.allocator.create(Stack(i32).Node) catch unreachable;
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node.* = Stack(i32).Node{
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.next = undefined,
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.data = x,
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};
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ctx.stack.push(node);
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_ = @atomicRmw(isize, &ctx.put_sum, builtin.AtomicRmwOp.Add, x, AtomicOrder.SeqCst);
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}
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return 0;
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}
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fn startGets(ctx: *Context) u8 {
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while (true) {
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const last = @atomicLoad(u8, &ctx.puts_done, builtin.AtomicOrder.SeqCst) == 1;
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while (ctx.stack.pop()) |node| {
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std.time.sleep(1); // let the os scheduler be our fuzz
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_ = @atomicRmw(isize, &ctx.get_sum, builtin.AtomicRmwOp.Add, node.data, builtin.AtomicOrder.SeqCst);
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_ = @atomicRmw(usize, &ctx.get_count, builtin.AtomicRmwOp.Add, 1, builtin.AtomicOrder.SeqCst);
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}
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if (last) return 0;
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}
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}
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