src/runtime/mgclimit_test.go - go - Git at Google

 // Copyright 2022 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package runtime_test

 import (
 	. "runtime"
 	"testing"
 	"time"
 )

 func TestGCCPULimiter(t *testing.T) {
 	const procs = 14

 	// Create mock time.
 	ticks := int64(0)
 	advance := func(d time.Duration) int64 {
 		t.Helper()
 		ticks += int64(d)
 		return ticks
 	}

 	// assistTime computes the CPU time for assists using frac of GOMAXPROCS
 	// over the wall-clock duration d.
 	assistTime := func(d time.Duration, frac float64) int64 {
 		t.Helper()
 		return int64(frac * float64(d) * procs)
 	}

 	l := NewGCCPULimiter(ticks, procs)

 	// Do the whole test twice to make sure state doesn't leak across.
 	var baseOverflow uint64 // Track total overflow across iterations.
 	for i := 0; i < 2; i++ {
 		t.Logf("Iteration %d", i+1)

 		if l.Capacity() != procs*CapacityPerProc {
 			t.Fatalf("unexpected capacity: %d", l.Capacity())
 		}
 		if l.Fill() != 0 {
 			t.Fatalf("expected empty bucket to start")
 		}

 		// Test filling the bucket with just mutator time.

 		l.Update(advance(10 * time.Millisecond))
 		l.Update(advance(1 * time.Second))
 		l.Update(advance(1 * time.Hour))
 		if l.Fill() != 0 {
 			t.Fatalf("expected empty bucket from only accumulating mutator time, got fill of %d cpu-ns", l.Fill())
 		}

 		// Test needUpdate.

 		if l.NeedUpdate(advance(GCCPULimiterUpdatePeriod / 2)) {
 			t.Fatal("need update even though updated half a period ago")
 		}
 		if !l.NeedUpdate(advance(GCCPULimiterUpdatePeriod)) {
 			t.Fatal("doesn't need update even though updated 1.5 periods ago")
 		}
 		l.Update(advance(0))
 		if l.NeedUpdate(advance(0)) {
 			t.Fatal("need update even though just updated")
 		}

 		// Test transitioning the bucket to enable the GC.

 		l.StartGCTransition(true, advance(109*time.Millisecond))
 		l.FinishGCTransition(advance(2*time.Millisecond + 1*time.Microsecond))

 		if expect := uint64((2*time.Millisecond + 1*time.Microsecond) * procs); l.Fill() != expect {
 			t.Fatalf("expected fill of %d, got %d cpu-ns", expect, l.Fill())
 		}

 		// Test passing time without assists during a GC. Specifically, just enough to drain the bucket to
 		// exactly procs nanoseconds (easier to get to because of rounding).
 		//
 		// The window we need to drain the bucket is 1/(1-2*gcBackgroundUtilization) times the current fill:
 		//
 		//   fill + (window * procs * gcBackgroundUtilization - window * procs * (1-gcBackgroundUtilization)) = n
 		//   fill = n - (window * procs * gcBackgroundUtilization - window * procs * (1-gcBackgroundUtilization))
 		//   fill = n + window * procs * ((1-gcBackgroundUtilization) - gcBackgroundUtilization)
 		//   fill = n + window * procs * (1-2*gcBackgroundUtilization)
 		//   window = (fill - n) / (procs * (1-2*gcBackgroundUtilization)))
 		//
 		// And here we want n=procs:
 		factor := (1 / (1 - 2*GCBackgroundUtilization))
 		fill := (2*time.Millisecond + 1*time.Microsecond) * procs
 		l.Update(advance(time.Duration(factor * float64(fill-procs) / procs)))
 		if l.Fill() != procs {
 			t.Fatalf("expected fill %d cpu-ns from draining after a GC started, got fill of %d cpu-ns", procs, l.Fill())
 		}

 		// Drain to zero for the rest of the test.
 		l.Update(advance(2 * procs * CapacityPerProc))
 		if l.Fill() != 0 {
 			t.Fatalf("expected empty bucket from draining, got fill of %d cpu-ns", l.Fill())
 		}

 		// Test filling up the bucket with 50% total GC work (so, not moving the bucket at all).
 		l.AddAssistTime(assistTime(10*time.Millisecond, 0.5-GCBackgroundUtilization))
 		l.Update(advance(10 * time.Millisecond))
 		if l.Fill() != 0 {
 			t.Fatalf("expected empty bucket from 50%% GC work, got fill of %d cpu-ns", l.Fill())
 		}

 		// Test adding to the bucket overall with 100% GC work.
 		l.AddAssistTime(assistTime(time.Millisecond, 1.0-GCBackgroundUtilization))
 		l.Update(advance(time.Millisecond))
 		if expect := uint64(procs * time.Millisecond); l.Fill() != expect {
 			t.Errorf("expected %d fill from 100%% GC CPU, got fill of %d cpu-ns", expect, l.Fill())
 		}
 		if l.Limiting() {
 			t.Errorf("limiter is enabled after filling bucket but shouldn't be")
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Test filling the bucket exactly full.
 		l.AddAssistTime(assistTime(CapacityPerProc-time.Millisecond, 1.0-GCBackgroundUtilization))
 		l.Update(advance(CapacityPerProc - time.Millisecond))
 		if l.Fill() != l.Capacity() {
 			t.Errorf("expected bucket filled to capacity %d, got %d", l.Capacity(), l.Fill())
 		}
 		if !l.Limiting() {
 			t.Errorf("limiter is not enabled after filling bucket but should be")
 		}
 		if l.Overflow() != 0+baseOverflow {
 			t.Errorf("bucket filled exactly should not have overflow, found %d", l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Test adding with a delta of exactly zero. That is, GC work is exactly 50% of all resources.
 		// Specifically, the limiter should still be on, and no overflow should accumulate.
 		l.AddAssistTime(assistTime(1*time.Second, 0.5-GCBackgroundUtilization))
 		l.Update(advance(1 * time.Second))
 		if l.Fill() != l.Capacity() {
 			t.Errorf("expected bucket filled to capacity %d, got %d", l.Capacity(), l.Fill())
 		}
 		if !l.Limiting() {
 			t.Errorf("limiter is not enabled after filling bucket but should be")
 		}
 		if l.Overflow() != 0+baseOverflow {
 			t.Errorf("bucket filled exactly should not have overflow, found %d", l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Drain the bucket by half.
 		l.AddAssistTime(assistTime(CapacityPerProc, 0))
 		l.Update(advance(CapacityPerProc))
 		if expect := l.Capacity() / 2; l.Fill() != expect {
 			t.Errorf("failed to drain to %d, got fill %d", expect, l.Fill())
 		}
 		if l.Limiting() {
 			t.Errorf("limiter is enabled after draining bucket but shouldn't be")
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Test overfilling the bucket.
 		l.AddAssistTime(assistTime(CapacityPerProc, 1.0-GCBackgroundUtilization))
 		l.Update(advance(CapacityPerProc))
 		if l.Fill() != l.Capacity() {
 			t.Errorf("failed to fill to capacity %d, got fill %d", l.Capacity(), l.Fill())
 		}
 		if !l.Limiting() {
 			t.Errorf("limiter is not enabled after overfill but should be")
 		}
 		if expect := uint64(CapacityPerProc * procs / 2); l.Overflow() != expect+baseOverflow {
 			t.Errorf("bucket overfilled should have overflow %d, found %d", expect, l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Test ending the cycle with some assists left over.
 		l.AddAssistTime(assistTime(1*time.Millisecond, 1.0-GCBackgroundUtilization))
 		l.StartGCTransition(false, advance(1*time.Millisecond))
 		if l.Fill() != l.Capacity() {
 			t.Errorf("failed to maintain fill to capacity %d, got fill %d", l.Capacity(), l.Fill())
 		}
 		if !l.Limiting() {
 			t.Errorf("limiter is not enabled after overfill but should be")
 		}
 		if expect := uint64((CapacityPerProc/2 + time.Millisecond) * procs); l.Overflow() != expect+baseOverflow {
 			t.Errorf("bucket overfilled should have overflow %d, found %d", expect, l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Make sure the STW adds to the bucket.
 		l.FinishGCTransition(advance(5 * time.Millisecond))
 		if l.Fill() != l.Capacity() {
 			t.Errorf("failed to maintain fill to capacity %d, got fill %d", l.Capacity(), l.Fill())
 		}
 		if !l.Limiting() {
 			t.Errorf("limiter is not enabled after overfill but should be")
 		}
 		if expect := uint64((CapacityPerProc/2 + 6*time.Millisecond) * procs); l.Overflow() != expect+baseOverflow {
 			t.Errorf("bucket overfilled should have overflow %d, found %d", expect, l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Resize procs up and make sure limiting stops.
 		expectFill := l.Capacity()
 		l.ResetCapacity(advance(0), procs+10)
 		if l.Fill() != expectFill {
 			t.Errorf("failed to maintain fill at old capacity %d, got fill %d", expectFill, l.Fill())
 		}
 		if l.Limiting() {
 			t.Errorf("limiter is enabled after resetting capacity higher")
 		}
 		if expect := uint64((CapacityPerProc/2 + 6*time.Millisecond) * procs); l.Overflow() != expect+baseOverflow {
 			t.Errorf("bucket overflow %d should have remained constant, found %d", expect, l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Resize procs down and make sure limiting begins again.
 		// Also make sure resizing doesn't affect overflow. This isn't
 		// a case where we want to report overflow, because we're not
 		// actively doing work to achieve it. It's that we have fewer
 		// CPU resources now.
 		l.ResetCapacity(advance(0), procs-10)
 		if l.Fill() != l.Capacity() {
 			t.Errorf("failed lower fill to new capacity %d, got fill %d", l.Capacity(), l.Fill())
 		}
 		if !l.Limiting() {
 			t.Errorf("limiter is disabled after resetting capacity lower")
 		}
 		if expect := uint64((CapacityPerProc/2 + 6*time.Millisecond) * procs); l.Overflow() != expect+baseOverflow {
 			t.Errorf("bucket overflow %d should have remained constant, found %d", expect, l.Overflow())
 		}
 		if t.Failed() {
 			t.FailNow()
 		}

 		// Get back to a zero state. The top of the loop will double check.
 		l.ResetCapacity(advance(CapacityPerProc*procs), procs)

 		// Track total overflow for future iterations.
 		baseOverflow += uint64((CapacityPerProc/2 + 6*time.Millisecond) * procs)
 	}
 }
	// Copyright 2022 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package runtime_test

	import (
	. "runtime"
	"testing"
	"time"
	)

	func TestGCCPULimiter(t *testing.T) {
	const procs = 14

	// Create mock time.
	ticks := int64(0)
	advance := func(d time.Duration) int64 {
	t.Helper()
	ticks += int64(d)
	return ticks
	}

	// assistTime computes the CPU time for assists using frac of GOMAXPROCS
	// over the wall-clock duration d.
	assistTime := func(d time.Duration, frac float64) int64 {
	t.Helper()
	return int64(frac * float64(d) * procs)
	}

	l := NewGCCPULimiter(ticks, procs)

	// Do the whole test twice to make sure state doesn't leak across.
	var baseOverflow uint64 // Track total overflow across iterations.
	for i := 0; i < 2; i++ {
	t.Logf("Iteration %d", i+1)

	if l.Capacity() != procs*CapacityPerProc {
	t.Fatalf("unexpected capacity: %d", l.Capacity())
	}
	if l.Fill() != 0 {
	t.Fatalf("expected empty bucket to start")
	}

	// Test filling the bucket with just mutator time.

	l.Update(advance(10 * time.Millisecond))
	l.Update(advance(1 * time.Second))
	l.Update(advance(1 * time.Hour))
	if l.Fill() != 0 {
	t.Fatalf("expected empty bucket from only accumulating mutator time, got fill of %d cpu-ns", l.Fill())
	}

	// Test needUpdate.

	if l.NeedUpdate(advance(GCCPULimiterUpdatePeriod / 2)) {
	t.Fatal("need update even though updated half a period ago")
	}
	if !l.NeedUpdate(advance(GCCPULimiterUpdatePeriod)) {
	t.Fatal("doesn't need update even though updated 1.5 periods ago")
	}
	l.Update(advance(0))
	if l.NeedUpdate(advance(0)) {
	t.Fatal("need update even though just updated")
	}

	// Test transitioning the bucket to enable the GC.

	l.StartGCTransition(true, advance(109*time.Millisecond))
	l.FinishGCTransition(advance(2time.Millisecond + 1time.Microsecond))

	if expect := uint64((2time.Millisecond + 1time.Microsecond) * procs); l.Fill() != expect {
	t.Fatalf("expected fill of %d, got %d cpu-ns", expect, l.Fill())
	}

	// Test passing time without assists during a GC. Specifically, just enough to drain the bucket to
	// exactly procs nanoseconds (easier to get to because of rounding).
	//
	// The window we need to drain the bucket is 1/(1-2*gcBackgroundUtilization) times the current fill:
	//
	// fill + (window * procs * gcBackgroundUtilization - window * procs * (1-gcBackgroundUtilization)) = n
	// fill = n - (window * procs * gcBackgroundUtilization - window * procs * (1-gcBackgroundUtilization))
	// fill = n + window * procs * ((1-gcBackgroundUtilization) - gcBackgroundUtilization)
	// fill = n + window * procs * (1-2*gcBackgroundUtilization)
	// window = (fill - n) / (procs * (1-2*gcBackgroundUtilization)))
	//
	// And here we want n=procs:
	factor := (1 / (1 - 2*GCBackgroundUtilization))
	fill := (2time.Millisecond + 1time.Microsecond) * procs
	l.Update(advance(time.Duration(factor * float64(fill-procs) / procs)))
	if l.Fill() != procs {
	t.Fatalf("expected fill %d cpu-ns from draining after a GC started, got fill of %d cpu-ns", procs, l.Fill())
	}

	// Drain to zero for the rest of the test.
	l.Update(advance(2 * procs * CapacityPerProc))
	if l.Fill() != 0 {
	t.Fatalf("expected empty bucket from draining, got fill of %d cpu-ns", l.Fill())
	}

	// Test filling up the bucket with 50% total GC work (so, not moving the bucket at all).
	l.AddAssistTime(assistTime(10*time.Millisecond, 0.5-GCBackgroundUtilization))
	l.Update(advance(10 * time.Millisecond))
	if l.Fill() != 0 {
	t.Fatalf("expected empty bucket from 50%% GC work, got fill of %d cpu-ns", l.Fill())
	}

	// Test adding to the bucket overall with 100% GC work.
	l.AddAssistTime(assistTime(time.Millisecond, 1.0-GCBackgroundUtilization))
	l.Update(advance(time.Millisecond))
	if expect := uint64(procs * time.Millisecond); l.Fill() != expect {
	t.Errorf("expected %d fill from 100%% GC CPU, got fill of %d cpu-ns", expect, l.Fill())
	}
	if l.Limiting() {
	t.Errorf("limiter is enabled after filling bucket but shouldn't be")
	}
	if t.Failed() {
	t.FailNow()
	}

	// Test filling the bucket exactly full.
	l.AddAssistTime(assistTime(CapacityPerProc-time.Millisecond, 1.0-GCBackgroundUtilization))
	l.Update(advance(CapacityPerProc - time.Millisecond))
	if l.Fill() != l.Capacity() {
	t.Errorf("expected bucket filled to capacity %d, got %d", l.Capacity(), l.Fill())
	}
	if !l.Limiting() {
	t.Errorf("limiter is not enabled after filling bucket but should be")
	}
	if l.Overflow() != 0+baseOverflow {
	t.Errorf("bucket filled exactly should not have overflow, found %d", l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Test adding with a delta of exactly zero. That is, GC work is exactly 50% of all resources.
	// Specifically, the limiter should still be on, and no overflow should accumulate.
	l.AddAssistTime(assistTime(1*time.Second, 0.5-GCBackgroundUtilization))
	l.Update(advance(1 * time.Second))
	if l.Fill() != l.Capacity() {
	t.Errorf("expected bucket filled to capacity %d, got %d", l.Capacity(), l.Fill())
	}
	if !l.Limiting() {
	t.Errorf("limiter is not enabled after filling bucket but should be")
	}
	if l.Overflow() != 0+baseOverflow {
	t.Errorf("bucket filled exactly should not have overflow, found %d", l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Drain the bucket by half.
	l.AddAssistTime(assistTime(CapacityPerProc, 0))
	l.Update(advance(CapacityPerProc))
	if expect := l.Capacity() / 2; l.Fill() != expect {
	t.Errorf("failed to drain to %d, got fill %d", expect, l.Fill())
	}
	if l.Limiting() {
	t.Errorf("limiter is enabled after draining bucket but shouldn't be")
	}
	if t.Failed() {
	t.FailNow()
	}

	// Test overfilling the bucket.
	l.AddAssistTime(assistTime(CapacityPerProc, 1.0-GCBackgroundUtilization))
	l.Update(advance(CapacityPerProc))
	if l.Fill() != l.Capacity() {
	t.Errorf("failed to fill to capacity %d, got fill %d", l.Capacity(), l.Fill())
	}
	if !l.Limiting() {
	t.Errorf("limiter is not enabled after overfill but should be")
	}
	if expect := uint64(CapacityPerProc * procs / 2); l.Overflow() != expect+baseOverflow {
	t.Errorf("bucket overfilled should have overflow %d, found %d", expect, l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Test ending the cycle with some assists left over.
	l.AddAssistTime(assistTime(1*time.Millisecond, 1.0-GCBackgroundUtilization))
	l.StartGCTransition(false, advance(1*time.Millisecond))
	if l.Fill() != l.Capacity() {
	t.Errorf("failed to maintain fill to capacity %d, got fill %d", l.Capacity(), l.Fill())
	}
	if !l.Limiting() {
	t.Errorf("limiter is not enabled after overfill but should be")
	}
	if expect := uint64((CapacityPerProc/2 + time.Millisecond) * procs); l.Overflow() != expect+baseOverflow {
	t.Errorf("bucket overfilled should have overflow %d, found %d", expect, l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Make sure the STW adds to the bucket.
	l.FinishGCTransition(advance(5 * time.Millisecond))
	if l.Fill() != l.Capacity() {
	t.Errorf("failed to maintain fill to capacity %d, got fill %d", l.Capacity(), l.Fill())
	}
	if !l.Limiting() {
	t.Errorf("limiter is not enabled after overfill but should be")
	}
	if expect := uint64((CapacityPerProc/2 + 6time.Millisecond) procs); l.Overflow() != expect+baseOverflow {
	t.Errorf("bucket overfilled should have overflow %d, found %d", expect, l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Resize procs up and make sure limiting stops.
	expectFill := l.Capacity()
	l.ResetCapacity(advance(0), procs+10)
	if l.Fill() != expectFill {
	t.Errorf("failed to maintain fill at old capacity %d, got fill %d", expectFill, l.Fill())
	}
	if l.Limiting() {
	t.Errorf("limiter is enabled after resetting capacity higher")
	}
	if expect := uint64((CapacityPerProc/2 + 6time.Millisecond) procs); l.Overflow() != expect+baseOverflow {
	t.Errorf("bucket overflow %d should have remained constant, found %d", expect, l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Resize procs down and make sure limiting begins again.
	// Also make sure resizing doesn't affect overflow. This isn't
	// a case where we want to report overflow, because we're not
	// actively doing work to achieve it. It's that we have fewer
	// CPU resources now.
	l.ResetCapacity(advance(0), procs-10)
	if l.Fill() != l.Capacity() {
	t.Errorf("failed lower fill to new capacity %d, got fill %d", l.Capacity(), l.Fill())
	}
	if !l.Limiting() {
	t.Errorf("limiter is disabled after resetting capacity lower")
	}
	if expect := uint64((CapacityPerProc/2 + 6time.Millisecond) procs); l.Overflow() != expect+baseOverflow {
	t.Errorf("bucket overflow %d should have remained constant, found %d", expect, l.Overflow())
	}
	if t.Failed() {
	t.FailNow()
	}

	// Get back to a zero state. The top of the loop will double check.
	l.ResetCapacity(advance(CapacityPerProc*procs), procs)

	// Track total overflow for future iterations.
	baseOverflow += uint64((CapacityPerProc/2 + 6time.Millisecond) procs)
	}
	}