tools/lib/cache/filecache_test.go - fuchsia - Git at Google

 // Copyright 2019 The Fuchsia 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 cache

 import (
 	"bytes"
 	"encoding/hex"
 	"encoding/json"
 	"io/ioutil"
 	"math/rand"
 	"runtime"
 	"sync"
 	"sync/atomic"
 	"testing"
 	"time"
 )

 // hammerThread is a way for users to configure specific loads on the cache.
 // the times are not maintained precisely due to the fact that the time it
 // takes to perform an operation on the cache is assumed to be zero.
 type hammerThread struct {
 	// ReadsPerSec sets the mean rate of read operations for this thread in
 	// reads per second
 	ReadsPerSec float64 `json:"rps"`
 	// ReadTime sets the mean time to hold on to a file for before closing.
 	ReadTime float64 `json:"read_time"`
 	// WritesPerSec sets the mean rate of write operations for this thread in
 	// reads per second.
 	WritesPerSec float64 `json:"wps"`
 	// Duration is the number of seconds this thread should run for.
 	Duration float64 `json:"duration"`
 }

 type hammerProc struct {
 	Threads []hammerThread `json:"threads"`
 }

 type fuzzerProc struct {
 	hammerProc
 	cache *FileCache
 }

 type fuzzKey string

 func (f fuzzKey) Hash() string {
 	return string(f)
 }

 type cacheFuzzer struct {
 	cachePath string
 	size      uint64
 	procs     []fuzzerProc
 	// TODO: Figure out if write contention is making things slow and bucket
 	// the keys so that a lock only has to be obtained for the particular part
 	// of the map being used.
 	recordLock sync.RWMutex
 	record     map[string]string
 	// These need to be updated atomically.
 	totalMisses uint64
 	totalTries  uint64
 	totalWrites uint64
 	writeFails  uint64
 	// Makes sure we wait on all threads.
 	wg sync.WaitGroup
 }

 func newCacheFuzzer(config string, cachePath string, size uint64) (*cacheFuzzer, error) {
 	file := bytes.NewBufferString(config)
 	var out cacheFuzzer
 	out.cachePath = cachePath
 	out.size = size
 	dec := json.NewDecoder(file)
 	var procs []hammerProc
 	dec.Decode(&procs)
 	for _, proc := range procs {
 		filecache, err := GetFileCache(cachePath, size)
 		if err != nil {
 			return nil, err
 		}
 		out.procs = append(out.procs, fuzzerProc{proc, filecache})
 	}
 	out.record = make(map[string]string)
 	return &out, nil
 }

 func (c *cacheFuzzer) checkRead(t *testing.T, readTime float64, filecache *FileCache) {
 	// Acquire the lock for the minimum amount of time. We want the actual cache
 	// read to not be blocked by the lock.
 	var key string
 	var value string
 	foundSample := func() bool {
 		c.recordLock.RLock()
 		defer func() {
 			c.recordLock.RUnlock()
 			runtime.Gosched()
 		}()
 		for k, v := range c.record {
 			key, value = k, v
 			return true
 		}
 		return false
 	}()
 	// Make sure we actually sampled a real key/value pair
 	if !foundSample {
 		return
 	}
 	// Now test that the key and value make sense.
 	atomic.AddUint64(&c.totalTries, 1)
 	ref, err := filecache.Get(fuzzKey(key))
 	// Note that if we miss, it was because the file was culled. We don't attempt
 	// to test that keys that were never added hit this case.
 	if err != nil {
 		atomic.AddUint64(&c.totalMisses, 1)
 		return
 	}
 	// Make sure we wait on this to close
 	c.wg.Add(1)
 	// Now hold on to the file for a random amount of time.
 	go func() {
 		defer c.wg.Done()
 		defer ref.Close()
 		sleepRand(readTime)
 		data, err := ioutil.ReadFile(ref.String())
 		if err != nil {
 			t.Errorf("could not read file: %v", err)
 		}
 		if string(data) != value {
 			t.Errorf("could not read file: %v", err)
 		}
 	}()
 }

 // Generates a random hex string of 16-bytes with maximal entropy.
 // This should give enough enough entropy to ensure that the same
 // string is never used twice.
 func getRandomString() string {
 	out := make([]byte, 16)
 	rand.Read(out)
 	return hex.EncodeToString(out)
 }

 // This function shouldn't actually fail but adds new things to the cache
 // so that further gets can be tested later.
 func (c *cacheFuzzer) checkWrite(t *testing.T, filecache *FileCache) {
 	// We want to perform the write without a lock. The only part that should
 	// lock is updating the internal data structure we use to keep track of keys.
 	key := getRandomString()
 	value := getRandomString()
 	atomic.AddUint64(&c.totalWrites, 1)
 	file, err := filecache.Add(fuzzKey(key), bytes.NewBufferString(value))
 	if err != nil {
 		t.Errorf("%v", err)
 		atomic.AddUint64(&c.writeFails, 1)
 		return
 	}
 	file.Close()
 	c.recordLock.Lock()
 	defer c.recordLock.Unlock()
 	c.record[key] = value
 }

 // Sleep for a number of random number of seconds with mean 'beta'.
 // Entropy is maximized. To get an expected number of operations per
 // second of N you can use 1/N as beta to get maximally entropicly timed
 // events. The amount of time slept for is returned.
 func sleepRand(beta float64) float64 {
 	out := rand.ExpFloat64() * beta
 	time.Sleep(time.Duration(out * float64(time.Second)))
 	return out
 }

 func (c *cacheFuzzer) fuzzThread(t *testing.T, proc fuzzerProc, thread hammerThread) {
 	// lambda is the expected number of operations per second
 	lambda := thread.ReadsPerSec + thread.WritesPerSec
 	// readProb is the probability that one of our operations will be a read.
 	readProb := thread.ReadsPerSec / lambda
 	// we need to keep track of the total time we've slept for and die at the end.
 	totalTime := 0.0
 	for totalTime < thread.Duration {
 		totalTime += sleepRand(1.0 / lambda)
 		if rand.Float64() < readProb {
 			c.checkRead(t, thread.ReadTime, proc.cache)
 		} else {
 			c.checkWrite(t, proc.cache)
 		}
 	}
 	// Note that checkRead can call c.wg.Add. It is safe for it to call Add as
 	// long as it proceeds this Done.
 	c.wg.Done()
 }

 func (c *cacheFuzzer) fuzzProc(t *testing.T, proc fuzzerProc) {
 	for _, thread := range proc.Threads {
 		c.wg.Add(1)
 		go c.fuzzThread(t, proc, thread)
 	}
 }

 func (c *cacheFuzzer) fuzz(t *testing.T) {
 	for _, proc := range c.procs {
 		c.fuzzProc(t, proc)
 	}
 	c.wg.Wait()
 }

 const fuzzConfig = `
 [
   {"threads":[
     { "rps": 1000.0, "read_time": 0.000001, "wps": 100.0, "duration": 1.0 },
     { "rps": 2000.0, "read_time": 0.15, "wps": 100.0, "duration": 0.5 },
     { "rps": 10.0, "read_time": 0.001, "wps": 1000.0, "duration": 1.1 },
     { "rps": 5000.0, "read_time": 0.1, "wps": 10.0, "duration": 0.7 }
   ]},
   {"threads":[
     { "rps": 1000.0, "read_time": 0.01, "wps": 100.0, "duration": 1.1 },
     { "rps": 2000.0, "read_time": 0.0001, "wps": 100.0, "duration": 1.2 },
     { "rps": 10.0, "read_time": 0.05, "wps": 1000.0, "duration": 0.3 },
     { "rps": 5000.0, "read_time": 0.001, "wps": 10.0, "duration": 1.3 }
   ]},
   {"threads":[
     { "rps": 1000.0, "read_time": 0.01, "wps": 100.0, "duration": 0.5 },
     { "rps": 2000.0, "read_time": 0.001, "wps": 100.0, "duration": 1.0 },
     { "rps": 10.0, "read_time": 0.05, "wps": 1000.0, "duration": 1.5 },
     { "rps": 5000.0, "read_time": 0.005, "wps": 10.0, "duration": 1.0 }
   ]}
 ]
 `

 func TestFileCache(t *testing.T) {
 	cachePath := t.TempDir()
 	filecache, err := newCacheFuzzer(fuzzConfig, cachePath, 250)
 	if err != nil {
 		t.Fatalf("%v", err)
 	}
 	filecache.fuzz(t)
 	t.Logf("cache hit/miss ratio: %v:%v", filecache.totalTries-filecache.totalMisses, filecache.totalMisses)
 	t.Logf("write success/fail ratio: %v:%v", filecache.totalWrites-filecache.writeFails, filecache.writeFails)
 	if err := DeleteCache(cachePath); err != nil {
 		t.Error(err)
 	}
 }
	// Copyright 2019 The Fuchsia 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 cache

	import (
	"bytes"
	"encoding/hex"
	"encoding/json"
	"io/ioutil"
	"math/rand"
	"runtime"
	"sync"
	"sync/atomic"
	"testing"
	"time"
	)

	// hammerThread is a way for users to configure specific loads on the cache.
	// the times are not maintained precisely due to the fact that the time it
	// takes to perform an operation on the cache is assumed to be zero.
	type hammerThread struct {
	// ReadsPerSec sets the mean rate of read operations for this thread in
	// reads per second
	ReadsPerSec float64 `json:"rps"`
	// ReadTime sets the mean time to hold on to a file for before closing.
	ReadTime float64 `json:"read_time"`
	// WritesPerSec sets the mean rate of write operations for this thread in
	// reads per second.
	WritesPerSec float64 `json:"wps"`
	// Duration is the number of seconds this thread should run for.
	Duration float64 `json:"duration"`
	}

	type hammerProc struct {
	Threads []hammerThread `json:"threads"`
	}

	type fuzzerProc struct {
	hammerProc
	cache *FileCache
	}

	type fuzzKey string

	func (f fuzzKey) Hash() string {
	return string(f)
	}

	type cacheFuzzer struct {
	cachePath string
	size uint64
	procs []fuzzerProc
	// TODO: Figure out if write contention is making things slow and bucket
	// the keys so that a lock only has to be obtained for the particular part
	// of the map being used.
	recordLock sync.RWMutex
	record map[string]string
	// These need to be updated atomically.
	totalMisses uint64
	totalTries uint64
	totalWrites uint64
	writeFails uint64
	// Makes sure we wait on all threads.
	wg sync.WaitGroup
	}

	func newCacheFuzzer(config string, cachePath string, size uint64) (*cacheFuzzer, error) {
	file := bytes.NewBufferString(config)
	var out cacheFuzzer
	out.cachePath = cachePath
	out.size = size
	dec := json.NewDecoder(file)
	var procs []hammerProc
	dec.Decode(&procs)
	for _, proc := range procs {
	filecache, err := GetFileCache(cachePath, size)
	if err != nil {
	return nil, err
	}
	out.procs = append(out.procs, fuzzerProc{proc, filecache})
	}
	out.record = make(map[string]string)
	return &out, nil
	}

	func (c cacheFuzzer) checkRead(t testing.T, readTime float64, filecache *FileCache) {
	// Acquire the lock for the minimum amount of time. We want the actual cache
	// read to not be blocked by the lock.
	var key string
	var value string
	foundSample := func() bool {
	c.recordLock.RLock()
	defer func() {
	c.recordLock.RUnlock()
	runtime.Gosched()
	}()
	for k, v := range c.record {
	key, value = k, v
	return true
	}
	return false
	}()
	// Make sure we actually sampled a real key/value pair
	if !foundSample {
	return
	}
	// Now test that the key and value make sense.
	atomic.AddUint64(&c.totalTries, 1)
	ref, err := filecache.Get(fuzzKey(key))
	// Note that if we miss, it was because the file was culled. We don't attempt
	// to test that keys that were never added hit this case.
	if err != nil {
	atomic.AddUint64(&c.totalMisses, 1)
	return
	}
	// Make sure we wait on this to close
	c.wg.Add(1)
	// Now hold on to the file for a random amount of time.
	go func() {
	defer c.wg.Done()
	defer ref.Close()
	sleepRand(readTime)
	data, err := ioutil.ReadFile(ref.String())
	if err != nil {
	t.Errorf("could not read file: %v", err)
	}
	if string(data) != value {
	t.Errorf("could not read file: %v", err)
	}
	}()
	}

	// Generates a random hex string of 16-bytes with maximal entropy.
	// This should give enough enough entropy to ensure that the same
	// string is never used twice.
	func getRandomString() string {
	out := make([]byte, 16)
	rand.Read(out)
	return hex.EncodeToString(out)
	}

	// This function shouldn't actually fail but adds new things to the cache
	// so that further gets can be tested later.
	func (c cacheFuzzer) checkWrite(t testing.T, filecache *FileCache) {
	// We want to perform the write without a lock. The only part that should
	// lock is updating the internal data structure we use to keep track of keys.
	key := getRandomString()
	value := getRandomString()
	atomic.AddUint64(&c.totalWrites, 1)
	file, err := filecache.Add(fuzzKey(key), bytes.NewBufferString(value))
	if err != nil {
	t.Errorf("%v", err)
	atomic.AddUint64(&c.writeFails, 1)
	return
	}
	file.Close()
	c.recordLock.Lock()
	defer c.recordLock.Unlock()
	c.record[key] = value
	}

	// Sleep for a number of random number of seconds with mean 'beta'.
	// Entropy is maximized. To get an expected number of operations per
	// second of N you can use 1/N as beta to get maximally entropicly timed
	// events. The amount of time slept for is returned.
	func sleepRand(beta float64) float64 {
	out := rand.ExpFloat64() * beta
	time.Sleep(time.Duration(out * float64(time.Second)))
	return out
	}

	func (c cacheFuzzer) fuzzThread(t testing.T, proc fuzzerProc, thread hammerThread) {
	// lambda is the expected number of operations per second
	lambda := thread.ReadsPerSec + thread.WritesPerSec
	// readProb is the probability that one of our operations will be a read.
	readProb := thread.ReadsPerSec / lambda
	// we need to keep track of the total time we've slept for and die at the end.
	totalTime := 0.0
	for totalTime < thread.Duration {
	totalTime += sleepRand(1.0 / lambda)
	if rand.Float64() < readProb {
	c.checkRead(t, thread.ReadTime, proc.cache)
	} else {
	c.checkWrite(t, proc.cache)
	}
	}
	// Note that checkRead can call c.wg.Add. It is safe for it to call Add as
	// long as it proceeds this Done.
	c.wg.Done()
	}

	func (c cacheFuzzer) fuzzProc(t testing.T, proc fuzzerProc) {
	for _, thread := range proc.Threads {
	c.wg.Add(1)
	go c.fuzzThread(t, proc, thread)
	}
	}

	func (c cacheFuzzer) fuzz(t testing.T) {
	for _, proc := range c.procs {
	c.fuzzProc(t, proc)
	}
	c.wg.Wait()
	}

	const fuzzConfig = `
	[
	{"threads":[
	{ "rps": 1000.0, "read_time": 0.000001, "wps": 100.0, "duration": 1.0 },
	{ "rps": 2000.0, "read_time": 0.15, "wps": 100.0, "duration": 0.5 },
	{ "rps": 10.0, "read_time": 0.001, "wps": 1000.0, "duration": 1.1 },
	{ "rps": 5000.0, "read_time": 0.1, "wps": 10.0, "duration": 0.7 }
	]},
	{"threads":[
	{ "rps": 1000.0, "read_time": 0.01, "wps": 100.0, "duration": 1.1 },
	{ "rps": 2000.0, "read_time": 0.0001, "wps": 100.0, "duration": 1.2 },
	{ "rps": 10.0, "read_time": 0.05, "wps": 1000.0, "duration": 0.3 },
	{ "rps": 5000.0, "read_time": 0.001, "wps": 10.0, "duration": 1.3 }
	]},
	{"threads":[
	{ "rps": 1000.0, "read_time": 0.01, "wps": 100.0, "duration": 0.5 },
	{ "rps": 2000.0, "read_time": 0.001, "wps": 100.0, "duration": 1.0 },
	{ "rps": 10.0, "read_time": 0.05, "wps": 1000.0, "duration": 1.5 },
	{ "rps": 5000.0, "read_time": 0.005, "wps": 10.0, "duration": 1.0 }
	]}
	]
	`

	func TestFileCache(t *testing.T) {
	cachePath := t.TempDir()
	filecache, err := newCacheFuzzer(fuzzConfig, cachePath, 250)
	if err != nil {
	t.Fatalf("%v", err)
	}
	filecache.fuzz(t)
	t.Logf("cache hit/miss ratio: %v:%v", filecache.totalTries-filecache.totalMisses, filecache.totalMisses)
	t.Logf("write success/fail ratio: %v:%v", filecache.totalWrites-filecache.writeFails, filecache.writeFails)
	if err := DeleteCache(cachePath); err != nil {
	t.Error(err)
	}
	}