github.com/llvm-mirror/llgo@v0.0.0-20190322182713-bf6f0a60fce1/third_party/gofrontend/libgo/go/runtime/chan_test.go (about) 1 // Copyright 2009 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package runtime_test 6 7 import ( 8 "runtime" 9 "sync" 10 "sync/atomic" 11 "testing" 12 "time" 13 ) 14 15 func TestChan(t *testing.T) { 16 defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(4)) 17 N := 200 18 if testing.Short() { 19 N = 20 20 } 21 for chanCap := 0; chanCap < N; chanCap++ { 22 { 23 // Ensure that receive from empty chan blocks. 24 c := make(chan int, chanCap) 25 recv1 := false 26 go func() { 27 _ = <-c 28 recv1 = true 29 }() 30 recv2 := false 31 go func() { 32 _, _ = <-c 33 recv2 = true 34 }() 35 time.Sleep(time.Millisecond) 36 if recv1 || recv2 { 37 t.Fatalf("chan[%d]: receive from empty chan", chanCap) 38 } 39 // Ensure that non-blocking receive does not block. 40 select { 41 case _ = <-c: 42 t.Fatalf("chan[%d]: receive from empty chan", chanCap) 43 default: 44 } 45 select { 46 case _, _ = <-c: 47 t.Fatalf("chan[%d]: receive from empty chan", chanCap) 48 default: 49 } 50 c <- 0 51 c <- 0 52 } 53 54 { 55 // Ensure that send to full chan blocks. 56 c := make(chan int, chanCap) 57 for i := 0; i < chanCap; i++ { 58 c <- i 59 } 60 sent := uint32(0) 61 go func() { 62 c <- 0 63 atomic.StoreUint32(&sent, 1) 64 }() 65 time.Sleep(time.Millisecond) 66 if atomic.LoadUint32(&sent) != 0 { 67 t.Fatalf("chan[%d]: send to full chan", chanCap) 68 } 69 // Ensure that non-blocking send does not block. 70 select { 71 case c <- 0: 72 t.Fatalf("chan[%d]: send to full chan", chanCap) 73 default: 74 } 75 <-c 76 } 77 78 { 79 // Ensure that we receive 0 from closed chan. 80 c := make(chan int, chanCap) 81 for i := 0; i < chanCap; i++ { 82 c <- i 83 } 84 close(c) 85 for i := 0; i < chanCap; i++ { 86 v := <-c 87 if v != i { 88 t.Fatalf("chan[%d]: received %v, expected %v", chanCap, v, i) 89 } 90 } 91 if v := <-c; v != 0 { 92 t.Fatalf("chan[%d]: received %v, expected %v", chanCap, v, 0) 93 } 94 if v, ok := <-c; v != 0 || ok { 95 t.Fatalf("chan[%d]: received %v/%v, expected %v/%v", chanCap, v, ok, 0, false) 96 } 97 } 98 99 { 100 // Ensure that close unblocks receive. 101 c := make(chan int, chanCap) 102 done := make(chan bool) 103 go func() { 104 v, ok := <-c 105 done <- v == 0 && ok == false 106 }() 107 time.Sleep(time.Millisecond) 108 close(c) 109 if !<-done { 110 t.Fatalf("chan[%d]: received non zero from closed chan", chanCap) 111 } 112 } 113 114 { 115 // Send 100 integers, 116 // ensure that we receive them non-corrupted in FIFO order. 117 c := make(chan int, chanCap) 118 go func() { 119 for i := 0; i < 100; i++ { 120 c <- i 121 } 122 }() 123 for i := 0; i < 100; i++ { 124 v := <-c 125 if v != i { 126 t.Fatalf("chan[%d]: received %v, expected %v", chanCap, v, i) 127 } 128 } 129 130 // Same, but using recv2. 131 go func() { 132 for i := 0; i < 100; i++ { 133 c <- i 134 } 135 }() 136 for i := 0; i < 100; i++ { 137 v, ok := <-c 138 if !ok { 139 t.Fatalf("chan[%d]: receive failed, expected %v", chanCap, i) 140 } 141 if v != i { 142 t.Fatalf("chan[%d]: received %v, expected %v", chanCap, v, i) 143 } 144 } 145 146 // Send 1000 integers in 4 goroutines, 147 // ensure that we receive what we send. 148 const P = 4 149 const L = 1000 150 for p := 0; p < P; p++ { 151 go func() { 152 for i := 0; i < L; i++ { 153 c <- i 154 } 155 }() 156 } 157 done := make(chan map[int]int) 158 for p := 0; p < P; p++ { 159 go func() { 160 recv := make(map[int]int) 161 for i := 0; i < L; i++ { 162 v := <-c 163 recv[v] = recv[v] + 1 164 } 165 done <- recv 166 }() 167 } 168 recv := make(map[int]int) 169 for p := 0; p < P; p++ { 170 for k, v := range <-done { 171 recv[k] = recv[k] + v 172 } 173 } 174 if len(recv) != L { 175 t.Fatalf("chan[%d]: received %v values, expected %v", chanCap, len(recv), L) 176 } 177 for _, v := range recv { 178 if v != P { 179 t.Fatalf("chan[%d]: received %v values, expected %v", chanCap, v, P) 180 } 181 } 182 } 183 184 { 185 // Test len/cap. 186 c := make(chan int, chanCap) 187 if len(c) != 0 || cap(c) != chanCap { 188 t.Fatalf("chan[%d]: bad len/cap, expect %v/%v, got %v/%v", chanCap, 0, chanCap, len(c), cap(c)) 189 } 190 for i := 0; i < chanCap; i++ { 191 c <- i 192 } 193 if len(c) != chanCap || cap(c) != chanCap { 194 t.Fatalf("chan[%d]: bad len/cap, expect %v/%v, got %v/%v", chanCap, chanCap, chanCap, len(c), cap(c)) 195 } 196 } 197 198 } 199 } 200 201 func TestNonblockRecvRace(t *testing.T) { 202 n := 10000 203 if testing.Short() { 204 n = 100 205 } else { 206 if runtime.GOARCH == "s390" { 207 // Test uses too much address space on 31-bit S390. 208 t.Skip("skipping long test on s390") 209 } 210 } 211 for i := 0; i < n; i++ { 212 c := make(chan int, 1) 213 c <- 1 214 go func() { 215 select { 216 case <-c: 217 default: 218 t.Fatal("chan is not ready") 219 } 220 }() 221 close(c) 222 <-c 223 } 224 } 225 226 // This test checks that select acts on the state of the channels at one 227 // moment in the execution, not over a smeared time window. 228 // In the test, one goroutine does: 229 // create c1, c2 230 // make c1 ready for receiving 231 // create second goroutine 232 // make c2 ready for receiving 233 // make c1 no longer ready for receiving (if possible) 234 // The second goroutine does a non-blocking select receiving from c1 and c2. 235 // From the time the second goroutine is created, at least one of c1 and c2 236 // is always ready for receiving, so the select in the second goroutine must 237 // always receive from one or the other. It must never execute the default case. 238 func TestNonblockSelectRace(t *testing.T) { 239 n := 100000 240 if testing.Short() { 241 n = 1000 242 } 243 done := make(chan bool, 1) 244 for i := 0; i < n; i++ { 245 c1 := make(chan int, 1) 246 c2 := make(chan int, 1) 247 c1 <- 1 248 go func() { 249 select { 250 case <-c1: 251 case <-c2: 252 default: 253 done <- false 254 return 255 } 256 done <- true 257 }() 258 c2 <- 1 259 select { 260 case <-c1: 261 default: 262 } 263 if !<-done { 264 t.Fatal("no chan is ready") 265 } 266 } 267 } 268 269 // Same as TestNonblockSelectRace, but close(c2) replaces c2 <- 1. 270 func TestNonblockSelectRace2(t *testing.T) { 271 n := 100000 272 if testing.Short() { 273 n = 1000 274 } 275 done := make(chan bool, 1) 276 for i := 0; i < n; i++ { 277 c1 := make(chan int, 1) 278 c2 := make(chan int) 279 c1 <- 1 280 go func() { 281 select { 282 case <-c1: 283 case <-c2: 284 default: 285 done <- false 286 return 287 } 288 done <- true 289 }() 290 close(c2) 291 select { 292 case <-c1: 293 default: 294 } 295 if !<-done { 296 t.Fatal("no chan is ready") 297 } 298 } 299 } 300 301 func TestSelfSelect(t *testing.T) { 302 // Ensure that send/recv on the same chan in select 303 // does not crash nor deadlock. 304 defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(2)) 305 for _, chanCap := range []int{0, 10} { 306 var wg sync.WaitGroup 307 wg.Add(2) 308 c := make(chan int, chanCap) 309 for p := 0; p < 2; p++ { 310 p := p 311 go func() { 312 defer wg.Done() 313 for i := 0; i < 1000; i++ { 314 if p == 0 || i%2 == 0 { 315 select { 316 case c <- p: 317 case v := <-c: 318 if chanCap == 0 && v == p { 319 t.Fatalf("self receive") 320 } 321 } 322 } else { 323 select { 324 case v := <-c: 325 if chanCap == 0 && v == p { 326 t.Fatalf("self receive") 327 } 328 case c <- p: 329 } 330 } 331 } 332 }() 333 } 334 wg.Wait() 335 } 336 } 337 338 func TestSelectStress(t *testing.T) { 339 defer runtime.GOMAXPROCS(runtime.GOMAXPROCS(10)) 340 var c [4]chan int 341 c[0] = make(chan int) 342 c[1] = make(chan int) 343 c[2] = make(chan int, 2) 344 c[3] = make(chan int, 3) 345 N := int(1e5) 346 if testing.Short() { 347 N /= 10 348 } 349 // There are 4 goroutines that send N values on each of the chans, 350 // + 4 goroutines that receive N values on each of the chans, 351 // + 1 goroutine that sends N values on each of the chans in a single select, 352 // + 1 goroutine that receives N values on each of the chans in a single select. 353 // All these sends, receives and selects interact chaotically at runtime, 354 // but we are careful that this whole construct does not deadlock. 355 var wg sync.WaitGroup 356 wg.Add(10) 357 for k := 0; k < 4; k++ { 358 k := k 359 go func() { 360 for i := 0; i < N; i++ { 361 c[k] <- 0 362 } 363 wg.Done() 364 }() 365 go func() { 366 for i := 0; i < N; i++ { 367 <-c[k] 368 } 369 wg.Done() 370 }() 371 } 372 go func() { 373 var n [4]int 374 c1 := c 375 for i := 0; i < 4*N; i++ { 376 select { 377 case c1[3] <- 0: 378 n[3]++ 379 if n[3] == N { 380 c1[3] = nil 381 } 382 case c1[2] <- 0: 383 n[2]++ 384 if n[2] == N { 385 c1[2] = nil 386 } 387 case c1[0] <- 0: 388 n[0]++ 389 if n[0] == N { 390 c1[0] = nil 391 } 392 case c1[1] <- 0: 393 n[1]++ 394 if n[1] == N { 395 c1[1] = nil 396 } 397 } 398 } 399 wg.Done() 400 }() 401 go func() { 402 var n [4]int 403 c1 := c 404 for i := 0; i < 4*N; i++ { 405 select { 406 case <-c1[0]: 407 n[0]++ 408 if n[0] == N { 409 c1[0] = nil 410 } 411 case <-c1[1]: 412 n[1]++ 413 if n[1] == N { 414 c1[1] = nil 415 } 416 case <-c1[2]: 417 n[2]++ 418 if n[2] == N { 419 c1[2] = nil 420 } 421 case <-c1[3]: 422 n[3]++ 423 if n[3] == N { 424 c1[3] = nil 425 } 426 } 427 } 428 wg.Done() 429 }() 430 wg.Wait() 431 } 432 433 func TestChanSendInterface(t *testing.T) { 434 type mt struct{} 435 m := &mt{} 436 c := make(chan interface{}, 1) 437 c <- m 438 select { 439 case c <- m: 440 default: 441 } 442 select { 443 case c <- m: 444 case c <- &mt{}: 445 default: 446 } 447 } 448 449 func TestPseudoRandomSend(t *testing.T) { 450 n := 100 451 for _, chanCap := range []int{0, n} { 452 c := make(chan int, chanCap) 453 l := make([]int, n) 454 var m sync.Mutex 455 m.Lock() 456 go func() { 457 for i := 0; i < n; i++ { 458 runtime.Gosched() 459 l[i] = <-c 460 } 461 m.Unlock() 462 }() 463 for i := 0; i < n; i++ { 464 select { 465 case c <- 1: 466 case c <- 0: 467 } 468 } 469 m.Lock() // wait 470 n0 := 0 471 n1 := 0 472 for _, i := range l { 473 n0 += (i + 1) % 2 474 n1 += i 475 } 476 if n0 <= n/10 || n1 <= n/10 { 477 t.Errorf("Want pseudorandom, got %d zeros and %d ones (chan cap %d)", n0, n1, chanCap) 478 } 479 } 480 } 481 482 func TestMultiConsumer(t *testing.T) { 483 const nwork = 23 484 const niter = 271828 485 486 pn := []int{2, 3, 7, 11, 13, 17, 19, 23, 27, 31} 487 488 q := make(chan int, nwork*3) 489 r := make(chan int, nwork*3) 490 491 // workers 492 var wg sync.WaitGroup 493 for i := 0; i < nwork; i++ { 494 wg.Add(1) 495 go func(w int) { 496 for v := range q { 497 // mess with the fifo-ish nature of range 498 if pn[w%len(pn)] == v { 499 runtime.Gosched() 500 } 501 r <- v 502 } 503 wg.Done() 504 }(i) 505 } 506 507 // feeder & closer 508 expect := 0 509 go func() { 510 for i := 0; i < niter; i++ { 511 v := pn[i%len(pn)] 512 expect += v 513 q <- v 514 } 515 close(q) // no more work 516 wg.Wait() // workers done 517 close(r) // ... so there can be no more results 518 }() 519 520 // consume & check 521 n := 0 522 s := 0 523 for v := range r { 524 n++ 525 s += v 526 } 527 if n != niter || s != expect { 528 t.Errorf("Expected sum %d (got %d) from %d iter (saw %d)", 529 expect, s, niter, n) 530 } 531 } 532 533 func TestShrinkStackDuringBlockedSend(t *testing.T) { 534 // make sure that channel operations still work when we are 535 // blocked on a channel send and we shrink the stack. 536 // NOTE: this test probably won't fail unless stack1.go:stackDebug 537 // is set to >= 1. 538 const n = 10 539 c := make(chan int) 540 done := make(chan struct{}) 541 542 go func() { 543 for i := 0; i < n; i++ { 544 c <- i 545 // use lots of stack, briefly. 546 stackGrowthRecursive(20) 547 } 548 done <- struct{}{} 549 }() 550 551 for i := 0; i < n; i++ { 552 x := <-c 553 if x != i { 554 t.Errorf("bad channel read: want %d, got %d", i, x) 555 } 556 // Waste some time so sender can finish using lots of stack 557 // and block in channel send. 558 time.Sleep(1 * time.Millisecond) 559 // trigger GC which will shrink the stack of the sender. 560 runtime.GC() 561 } 562 <-done 563 } 564 565 func TestSelectDuplicateChannel(t *testing.T) { 566 // This test makes sure we can queue a G on 567 // the same channel multiple times. 568 c := make(chan int) 569 d := make(chan int) 570 e := make(chan int) 571 572 // goroutine A 573 go func() { 574 select { 575 case <-c: 576 case <-c: 577 case <-d: 578 } 579 e <- 9 580 }() 581 time.Sleep(time.Millisecond) // make sure goroutine A gets qeueued first on c 582 583 // goroutine B 584 go func() { 585 <-c 586 }() 587 time.Sleep(time.Millisecond) // make sure goroutine B gets queued on c before continuing 588 589 d <- 7 // wake up A, it dequeues itself from c. This operation used to corrupt c.recvq. 590 <-e // A tells us it's done 591 c <- 8 // wake up B. This operation used to fail because c.recvq was corrupted (it tries to wake up an already running G instead of B) 592 } 593 594 func BenchmarkChanNonblocking(b *testing.B) { 595 myc := make(chan int) 596 b.RunParallel(func(pb *testing.PB) { 597 for pb.Next() { 598 select { 599 case <-myc: 600 default: 601 } 602 } 603 }) 604 } 605 606 func BenchmarkSelectUncontended(b *testing.B) { 607 b.RunParallel(func(pb *testing.PB) { 608 myc1 := make(chan int, 1) 609 myc2 := make(chan int, 1) 610 myc1 <- 0 611 for pb.Next() { 612 select { 613 case <-myc1: 614 myc2 <- 0 615 case <-myc2: 616 myc1 <- 0 617 } 618 } 619 }) 620 } 621 622 func BenchmarkSelectSyncContended(b *testing.B) { 623 myc1 := make(chan int) 624 myc2 := make(chan int) 625 myc3 := make(chan int) 626 done := make(chan int) 627 b.RunParallel(func(pb *testing.PB) { 628 go func() { 629 for { 630 select { 631 case myc1 <- 0: 632 case myc2 <- 0: 633 case myc3 <- 0: 634 case <-done: 635 return 636 } 637 } 638 }() 639 for pb.Next() { 640 select { 641 case <-myc1: 642 case <-myc2: 643 case <-myc3: 644 } 645 } 646 }) 647 close(done) 648 } 649 650 func BenchmarkSelectAsyncContended(b *testing.B) { 651 procs := runtime.GOMAXPROCS(0) 652 myc1 := make(chan int, procs) 653 myc2 := make(chan int, procs) 654 b.RunParallel(func(pb *testing.PB) { 655 myc1 <- 0 656 for pb.Next() { 657 select { 658 case <-myc1: 659 myc2 <- 0 660 case <-myc2: 661 myc1 <- 0 662 } 663 } 664 }) 665 } 666 667 func BenchmarkSelectNonblock(b *testing.B) { 668 myc1 := make(chan int) 669 myc2 := make(chan int) 670 myc3 := make(chan int, 1) 671 myc4 := make(chan int, 1) 672 b.RunParallel(func(pb *testing.PB) { 673 for pb.Next() { 674 select { 675 case <-myc1: 676 default: 677 } 678 select { 679 case myc2 <- 0: 680 default: 681 } 682 select { 683 case <-myc3: 684 default: 685 } 686 select { 687 case myc4 <- 0: 688 default: 689 } 690 } 691 }) 692 } 693 694 func BenchmarkChanUncontended(b *testing.B) { 695 const C = 100 696 b.RunParallel(func(pb *testing.PB) { 697 myc := make(chan int, C) 698 for pb.Next() { 699 for i := 0; i < C; i++ { 700 myc <- 0 701 } 702 for i := 0; i < C; i++ { 703 <-myc 704 } 705 } 706 }) 707 } 708 709 func BenchmarkChanContended(b *testing.B) { 710 const C = 100 711 myc := make(chan int, C*runtime.GOMAXPROCS(0)) 712 b.RunParallel(func(pb *testing.PB) { 713 for pb.Next() { 714 for i := 0; i < C; i++ { 715 myc <- 0 716 } 717 for i := 0; i < C; i++ { 718 <-myc 719 } 720 } 721 }) 722 } 723 724 func BenchmarkChanSync(b *testing.B) { 725 const CallsPerSched = 1000 726 procs := 2 727 N := int32(b.N / CallsPerSched / procs * procs) 728 c := make(chan bool, procs) 729 myc := make(chan int) 730 for p := 0; p < procs; p++ { 731 go func() { 732 for { 733 i := atomic.AddInt32(&N, -1) 734 if i < 0 { 735 break 736 } 737 for g := 0; g < CallsPerSched; g++ { 738 if i%2 == 0 { 739 <-myc 740 myc <- 0 741 } else { 742 myc <- 0 743 <-myc 744 } 745 } 746 } 747 c <- true 748 }() 749 } 750 for p := 0; p < procs; p++ { 751 <-c 752 } 753 } 754 755 func benchmarkChanProdCons(b *testing.B, chanSize, localWork int) { 756 const CallsPerSched = 1000 757 procs := runtime.GOMAXPROCS(-1) 758 N := int32(b.N / CallsPerSched) 759 c := make(chan bool, 2*procs) 760 myc := make(chan int, chanSize) 761 for p := 0; p < procs; p++ { 762 go func() { 763 foo := 0 764 for atomic.AddInt32(&N, -1) >= 0 { 765 for g := 0; g < CallsPerSched; g++ { 766 for i := 0; i < localWork; i++ { 767 foo *= 2 768 foo /= 2 769 } 770 myc <- 1 771 } 772 } 773 myc <- 0 774 c <- foo == 42 775 }() 776 go func() { 777 foo := 0 778 for { 779 v := <-myc 780 if v == 0 { 781 break 782 } 783 for i := 0; i < localWork; i++ { 784 foo *= 2 785 foo /= 2 786 } 787 } 788 c <- foo == 42 789 }() 790 } 791 for p := 0; p < procs; p++ { 792 <-c 793 <-c 794 } 795 } 796 797 func BenchmarkChanProdCons0(b *testing.B) { 798 benchmarkChanProdCons(b, 0, 0) 799 } 800 801 func BenchmarkChanProdCons10(b *testing.B) { 802 benchmarkChanProdCons(b, 10, 0) 803 } 804 805 func BenchmarkChanProdCons100(b *testing.B) { 806 benchmarkChanProdCons(b, 100, 0) 807 } 808 809 func BenchmarkChanProdConsWork0(b *testing.B) { 810 benchmarkChanProdCons(b, 0, 100) 811 } 812 813 func BenchmarkChanProdConsWork10(b *testing.B) { 814 benchmarkChanProdCons(b, 10, 100) 815 } 816 817 func BenchmarkChanProdConsWork100(b *testing.B) { 818 benchmarkChanProdCons(b, 100, 100) 819 } 820 821 func BenchmarkSelectProdCons(b *testing.B) { 822 const CallsPerSched = 1000 823 procs := runtime.GOMAXPROCS(-1) 824 N := int32(b.N / CallsPerSched) 825 c := make(chan bool, 2*procs) 826 myc := make(chan int, 128) 827 myclose := make(chan bool) 828 for p := 0; p < procs; p++ { 829 go func() { 830 // Producer: sends to myc. 831 foo := 0 832 // Intended to not fire during benchmarking. 833 mytimer := time.After(time.Hour) 834 for atomic.AddInt32(&N, -1) >= 0 { 835 for g := 0; g < CallsPerSched; g++ { 836 // Model some local work. 837 for i := 0; i < 100; i++ { 838 foo *= 2 839 foo /= 2 840 } 841 select { 842 case myc <- 1: 843 case <-mytimer: 844 case <-myclose: 845 } 846 } 847 } 848 myc <- 0 849 c <- foo == 42 850 }() 851 go func() { 852 // Consumer: receives from myc. 853 foo := 0 854 // Intended to not fire during benchmarking. 855 mytimer := time.After(time.Hour) 856 loop: 857 for { 858 select { 859 case v := <-myc: 860 if v == 0 { 861 break loop 862 } 863 case <-mytimer: 864 case <-myclose: 865 } 866 // Model some local work. 867 for i := 0; i < 100; i++ { 868 foo *= 2 869 foo /= 2 870 } 871 } 872 c <- foo == 42 873 }() 874 } 875 for p := 0; p < procs; p++ { 876 <-c 877 <-c 878 } 879 } 880 881 func BenchmarkChanCreation(b *testing.B) { 882 b.RunParallel(func(pb *testing.PB) { 883 for pb.Next() { 884 myc := make(chan int, 1) 885 myc <- 0 886 <-myc 887 } 888 }) 889 } 890 891 func BenchmarkChanSem(b *testing.B) { 892 type Empty struct{} 893 myc := make(chan Empty, runtime.GOMAXPROCS(0)) 894 b.RunParallel(func(pb *testing.PB) { 895 for pb.Next() { 896 myc <- Empty{} 897 <-myc 898 } 899 }) 900 } 901 902 func BenchmarkChanPopular(b *testing.B) { 903 const n = 1000 904 c := make(chan bool) 905 var a []chan bool 906 var wg sync.WaitGroup 907 wg.Add(n) 908 for j := 0; j < n; j++ { 909 d := make(chan bool) 910 a = append(a, d) 911 go func() { 912 for i := 0; i < b.N; i++ { 913 select { 914 case <-c: 915 case <-d: 916 } 917 } 918 wg.Done() 919 }() 920 } 921 for i := 0; i < b.N; i++ { 922 for _, d := range a { 923 d <- true 924 } 925 } 926 wg.Wait() 927 }